EP2959123B1 - Heat-insulated system for lubricating rotating and oscillating components of a motor vehicle - Google Patents
Heat-insulated system for lubricating rotating and oscillating components of a motor vehicle Download PDFInfo
- Publication number
- EP2959123B1 EP2959123B1 EP14707127.8A EP14707127A EP2959123B1 EP 2959123 B1 EP2959123 B1 EP 2959123B1 EP 14707127 A EP14707127 A EP 14707127A EP 2959123 B1 EP2959123 B1 EP 2959123B1
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- EP
- European Patent Office
- Prior art keywords
- oil
- coolant
- heat
- temperature
- engine
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- MFUVDXOKPBAHMC-UHFFFAOYSA-N magnesium;dinitrate;hexahydrate Chemical compound O.O.O.O.O.O.[Mg+2].[O-][N+]([O-])=O.[O-][N+]([O-])=O MFUVDXOKPBAHMC-UHFFFAOYSA-N 0.000 description 4
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Images
Classifications
-
- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F01—MACHINES OR ENGINES IN GENERAL; ENGINE PLANTS IN GENERAL; STEAM ENGINES
- F01M—LUBRICATING OF MACHINES OR ENGINES IN GENERAL; LUBRICATING INTERNAL COMBUSTION ENGINES; CRANKCASE VENTILATING
- F01M5/00—Heating, cooling, or controlling temperature of lubricant; Lubrication means facilitating engine starting
- F01M5/02—Conditioning lubricant for aiding engine starting, e.g. heating
- F01M5/021—Conditioning lubricant for aiding engine starting, e.g. heating by heating
-
- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F01—MACHINES OR ENGINES IN GENERAL; ENGINE PLANTS IN GENERAL; STEAM ENGINES
- F01M—LUBRICATING OF MACHINES OR ENGINES IN GENERAL; LUBRICATING INTERNAL COMBUSTION ENGINES; CRANKCASE VENTILATING
- F01M5/00—Heating, cooling, or controlling temperature of lubricant; Lubrication means facilitating engine starting
- F01M5/001—Heating
Definitions
- the invention relates to a heat-insulated lubricating system for lubricating rotating or oscillating components, in particular a lubrication system for a motor vehicle, which can be used for the lubrication of moving parts of an internal combustion engine such as gasoline or diesel engine and / or lubrication of a transmission.
- the lubrication system can be used for example in a conventionally driven vehicle or in a hybrid or electric vehicle, but also in stationary systems such as power generators, work machines, etc.
- Lubricating systems for moving parts of a drive in particular an engine or mechanical transmission are well known. They serve to reduce friction between moving parts and to improve smooth running of the moving parts against each other. This reduces abrasion, reduces thermal heating of the parts and thus increases the service life.
- a stiffness of moving parts also requires an increased drive energy that must be used in unproductive manner to overcome the stiffness and brings an increased fuel or electricity consumption, so that on the one hand increases exhaust emissions, increased operating costs and, for example, reduced a range of a motor vehicle becomes.
- a reduction in the exhaust gas load and a low energy consumption are not only technically desirable properties of an engine, but internationally indispensable prerequisites, to comply with various government standards and limits.
- an inefficient lubrication management of a drive can lead to increased tax and duty load of the operator.
- One way to reduce friction losses is to use high quality lubricating oils with reduced viscosity at low temperatures, another option is to provide targeted rapid heating of the lubricant in the cold start phase.
- an oil lubrication system can be removed, in which from an oil suction pipe, which is arranged in an oil sump, oil can be introduced by means of an oil pump in a lubrication system, said oil is heated by means of an oil bypass line and a heat exchanger through an exhaust system.
- the heated oil can be stored in a thermally insulated intermediate tank and fed back into the lubrication system by means of a supply line directly under the suction bell of the oil sump.
- a lubrication system for an internal combustion engine includes an oil circuit, a radiator, and a heat accumulator located upstream of the engine for heating the oil.
- the heat accumulator is connected in parallel with the radiator, whereby a valve can switch the oil circuit between radiator and heat accumulator.
- an external insulation of oil lines to the heat storage if the heat storage is located further away from the engine. External insulation is subsequently easy to install and greatly alters mechanical dimensions and appearance of the insulated areas as well as their durability and mechanical resistance.
- an external insulation usually has a low fire resistance and thus represents a fire safety risk, and may be damaged, for example, by marten bite.
- Another disadvantage of external insulation is the resulting increase in surface area resulting in increased heat loss. Furthermore, the total weight is increased by external insulation. In the case of an inner insulation of a metal housing, on the other hand, the weight is reduced since a part of the heavy metal housing is replaced by a lighter insulating layer, in particular plastic. At no point in this document is pointed to an inner insulation of the oil line, especially not in a metal housing. With a housing made of an insulating material such as plastic, no comparable structural strength, rigidity or toughness can be achieved as in a metal housing, or other disadvantages such as high costs, for example when using ceramic are the result.
- the DE 30 32 090 A1 also relates to a method for accelerated heating of lubricating oil in a warm-up phase of an internal combustion engine, wherein by a heat pipe or a heat exchanger lubricating oil to be heated faster. It is proposed that the oil pan have controlled thermal insulation, where the louvers or shutters can be opened or closed as needed to cool or isolate the oil pan from the ambient air.
- Object of the following invention is to propose a lubrication system that overcomes the above-mentioned disadvantages of the prior art, provides a simple technical implementation and offers a significantly reduced friction, especially in the cold start phase.
- the system for lubricating rotating or oscillating components comprises at least one oil suction pipe, which is arranged in an oil reservoir, an oil pump, a heat source and further connecting lines, which are integrated in a metal housing, in particular an oil gallery for distributing lubricating oil to the components to be lubricated such as crankshaft, camshaft, gear parts, etc.
- the oil reservoir can be an open and usually not isolated storage and can in its structural design of a Correspond to oil pan.
- connection line within the oil gallery downstream of the heat source is insulated inwardly by an internal insulation, the thermal conductivity of the inner insulation being 5% or less than the thermal conductivity of the connection lines or the remaining oil gallery and preferably at least less than 1 W / (m K) and the heat source is switched off or at least reduced in its heat output when a first upper limit oil temperature is reached.
- the outer circumference of the connecting line can be at least twice as large as the inner circumference of the connecting lines, at least at one point.
- a connecting line behind an oil pump i. in a pressurized connection line region of a lubricating system and preferably behind a heat source, such as a heat exchanger having insulation, in particular an inner insulation, which makes a thermal heat transfer from the lubricating oil to the metallic environment more difficult.
- a heat source such as a heat exchanger having insulation, in particular an inner insulation
- the total thermal contact resistance is 3.3 times greater than without the proposed inner insulation. For this reason, improved heating can be achieved because the energy loss of the oil in the cold start phase is lowered and improved lubrication in the cold start phase is given.
- An internal insulation of a metal housing and a metal conduit also makes it possible to produce oil conduits and housings made of metal or permanent, but thermally conductive materials, and to maintain given external mechanical dimensions, since only an internal insulation is to be used, and external dimensions and structural details can be maintained and thus Rebuilding an existing aggregate design can be avoided.
- Internal insulation of oil pipes and housing parts makes existing engines and units more efficient without having to make design changes.
- the housing of the lubrication system in particular a crankcase or transmission housing, by a Be isolated inside insulation, wherein the thermal conductivity of the inner liner 5% or less than the thermal conductivity of a structural environment, in particular as the thermal conductivity of lubrication points, a housing, the components to be lubricated, a metal environment, and preferably at least less than 1 W / (m K) is.
- the structural environment describes a functional structural environment of the lubrication system, ie lubrication points where surfaces move against each other, as well as structural structural environments, ie the surrounding material such as metal housings, components, engine block etc.
- the oil reservoir can be isolated by an inner insulation, wherein the thermal conductivity of the inner insulation is 5% or less than the thermal conductivity of the oil reservoir, and preferably at least less than 1 W / (m K).
- the oil reservoir may be made entirely or at least partially of an insulating material which has a thermal conductivity of preferably at most less than 1 W / (m K).
- At least one of the components to be lubricated, rotating or oscillating can be insulated by at least one inner insulation and / or outer insulation, wherein the thermal conductivity of the outer insulation is 5% or less than the thermal conductivity of the rotating or oscillating components to be lubricated , and is preferably at least less than 1 W / (m K).
- the oil can only slightly lose heat to the metallic environment and is not so much cooled down, the oil in the cold start phase is heated by higher heat inputs, for example by a heat source, for example by an exhaust gas heat exchanger. Due to the isolation of the crankshaft, the thermal mass, which is available for the cooling of the oil, is reduced and due to the insulation of the inner Crankshaft housing, which can be considered very significant for the heat retention of the oil, an improved heating at low viscosity of the oil can be achieved.
- a highly insulated heat accumulator may in particular be provided with at least 5 mm thick heat storage insulation with a thermal conductivity of less than 0.01 W / (m K), in particular between an oil suction pipe and an oil pump or between an oil pump and a heat source, or between a heat source and a lubricating point, wherein preferably a temperature loss of oil at a temperature of 100 ° C to 80 ° C at 25 ° C ambient temperature in more than 6 hours.
- the heat storage insulation can be designed as a vacuum insulation.
- the oil connection lines and / or an outer jacket of the heat accumulator consists of a heat-insulating material having a thermal conductivity of less than 20 W / (m K).
- a plastic insulation can be used.
- the outer jacket of the heat accumulator can be double-walled and in the intermediate space between the inner wall and outer wall of the outer jacket, an insulating layer of airgel can be arranged, which has a thermal conductivity of less than 0.04 W / (m K).
- the filled with airgel volume may have a negative pressure to the environment. As a result, the insulation is significantly improved and prevents heat loss or unwanted heat input.
- the lubrication system may comprise a bypass valve, so that the heat accumulator is filled with oil at least 90.degree. C. when reaching a second upper oil limit temperature outside the heat accumulator and at a cold start the oil to be lubricated components under a predetermined first lower oil limit temperature of at most 50 ° C outside the heat storage, the stored oil in the heat storage can be delivered to the lubrication system.
- the proposed heat accumulator can advantageously overcome this with the preceding embodiments, wherein excess heat in the heat accumulator can be discharged from a cooling system or through a radiator or through an oil cooler, and through the improved thermal insulation the heat directly lowers the oil viscosity and contributes to friction reduction and thus leads to a reduction in fuel consumption.
- Attaching to the lubricating system with the heat storage can have in an advantageous development of the heat storage at least a separate chamber with a phase change material, in particular with a sugar alcohol, such as erythritol, threit or a paraffin or the like or a salt, preferably a hydrate, nitrate, hydroxide or chloride such as magnesium chloride hexahydrate or magnesium nitrate hexahydrate.
- a sugar alcohol such as erythritol, threit or a paraffin or the like or a salt, preferably a hydrate, nitrate, hydroxide or chloride such as magnesium chloride hexahydrate or magnesium nitrate hexahydrate.
- the melting temperature of the phase change material should be lower than the first upper oil limit temperature, and preferably - if the melting temperature of the phase change material is greater than 100 ° C - the phase change material erythritol be with a melting temperature of about 120 ° C, so that in cold start a highest possible Temperature is present in the heat storage.
- a sugar alcohol is used as the phase change material, and the melting temperature of the phase change material is provided above 100 ° C.
- latent heat storage are already known from the prior art. They use in various embodiments salt that has a melting temperature of 60 ° C to 80 ° C, such as. Barium hydroxide or Sodium silicates, such salts are material aggressive and cause corrosion damage that can lead to leaks in the cooling system or in the lubrication system. For this reason, a series production of such latent heat storage has been set.
- Another disadvantage of the known latent heat storage with phase change material was that the melting temperature is typically between 60 ° C and 80 ° C, which is clearly too low for an optimum temperature for oil lubrication, which is preferably 120 ° C.
- the use of such latent storage with salt-based phase change material could not sustainably improved lubrication in the cold start area.
- Use of phase change material with phase change temperatures above 80 ° C, especially erythritol as latent heat storage medium overcomes these problems because it has a melting temperature that is optimal for lubrication with engine oils.
- Attaching to the lubrication system with the heat storage can be carried out cylindrically in an advantageous embodiment of the invention, the heat storage and comprise a free piston of heat-insulating material, which divides the heat storage in two chambers. This is when filling the Heat storage with oil above a first upper limit oil temperature of at least 90 ° C in the first chamber, an oil volume from the second chamber pushed back into the lubrication system and when emptying the oil from the first chamber in a cold start phase below a first lower limit oil temperature of at most 50 ° C in the lubrication system will fill the second chamber with oil.
- the oil level in the oil reservoir is only insignificantly influenced and the heat storage is required, as a heat source, in particular as a heater and as a heat sink, in particular cooling device usable.
- the oil limit temperature may be an oil temperature of lubricating oil somewhere in the lubricating oil circuit, advantageously directly at a junction of the heat accumulator or ⁇ lauslassstelle where typically the highest expected oil temperatures occur, such as. Exit point from the engine block, etc.
- the heat storage In the case of filling the heat accumulator is hot Oil of the oil circuit absorbed by the heat storage and emit cooler oil, the heat storage thus serves as a heat sink. In a cold start phase and when emptying the heat accumulator cooler oil is absorbed and released warmer, the heat storage serves as a heat source.
- the heat accumulator can be arranged to effect an emptying of oil from the first chamber for oil cooling, as soon as oil in the oil circuit exceeds a second upper oil limit temperature of at least 110 ° C.
- a second upper oil limit temperature of at least 110 ° C typically, an oil temperature of oil in the first chamber is lower than the second upper oil limit temperature, so that the oil flowing out of the heat accumulator is colder than the inflowing oil.
- heat accumulators Another problem of heat accumulators is that during the cold start phase returning cooled oil mixes with the stored heated oil to establish a mixing temperature lower than the previous temperature in the heat storage before interchanging with the environment. Lowering the temperature reduces the lubricating property and thus the friction in the lubrication system.
- This problem can be solved in that a free piston is provided in the heat accumulator, wherein the heat accumulator preferably has a cylindrical shape, which divides the memory into two sub-chambers, which are interconnected by switching valves, so that the preheated oil does not settle with the can mix cold oil.
- the free piston the oil volume is kept constant, so that this does not adversely affect the pressure conditions and the oil volume in the lubrication circuit.
- the lubricating system, oil reservoir, structural environment and heat source can be comprised by an internal combustion engine, in particular by an internal combustion engine of a motor vehicle.
- the lubrication system, oil reservoir and structural environment may be comprised of a transmission, in particular a motor vehicle transmission, and the heat source may be provided by an internal combustion engine and / or an electric battery and / or an inverter.
- An inverter can convert DC to AC and vice versa and is used to drive AC and AC drives through batteries and accumulators.
- a lubricating medium in a transmission or a power transmission mechanism may be heated by waste heat from an internal combustion engine, or, for example, when used in an electric or hybrid vehicle by a heating characteristic of a battery or an electrical consumer, which become warm when the energy is released or absorbed.
- a fuel cell for example in the case of a hydrogen drive, a heat source for heating the lubrication system for the drive mechanism / transmission provides.
- Electric vehicles and hybrid vehicles which are powered by a combination of electric and internal combustion engine, are confronted with the problem that they on the one hand have no intrinsic heat source such as an internal combustion engine, and yet the lubricating property, especially at temperatures below 30 ° C significantly lower and thus Increased friction and increased energy consumption.
- waste heat can be used, which is generated for example by an inverter, a fuel cell or an electric battery, or waste heat of an electrical unit can be used to achieve an optimum lubrication temperature, especially for a transmission.
- a refrigeration cycle may be provided which interconnects the transmission, inverter, and battery to more quickly heat the transmission or heat transmission oil through a coolant-oil heat exchanger and cool the inverter or fuel cell, thereby providing improved performance Efficiency, increased range and low consumption can be achieved.
- a heat storage engine oil and transmission oil in a structural unit and in particular comprise at least one chamber for engine oil and a chamber for transmission oil.
- a uniform tank volume can be provided, the memory has a single high-quality insulation and requires little space.
- a high-quality insulated tank which has a vacuum insulation or which is filled with a phase change material, are provided, in particular two chambers for the two separate lubrication systems having.
- the heat source can comprise an exhaust gas heat exchanger, or the heat source, in particular in the case of application in a transmission, can comprise a coolant heat exchanger and / or an exhaust gas heat exchanger of an internal combustion engine.
- the exhaust gas heat exchanger may be arranged downstream of the coolant heat exchanger.
- a coolant valve may be arranged, which is closed when falling below a coolant limit temperature, in particular below an opening temperature of the cooling circuit thermostat for activating a main water cooler, in particular at most 10 ° C below thede Vietnamese Vietnameseturiturithermostattemperatur and is opened when the coolant temperature limit is exceeded.
- the coolant valve can be opened, preferably below 5 ° C below the opening temperature of thedeniklaufthermostattemperatur.
- the transmission may be a manual transmission or an automatic transmission, which has no oil pump, wherein a coolant heat exchanger is arranged in the oil reservoir, so that the transmission oil is warmed up by the engine coolant.
- the coolant heat exchanger is provided on the coolant side with a coolant valve, which falls below a coolant temperature limit, in particular below the opening temperature of a cooling circuit thermostat for activating the main water cooler, in particular 10 ° C. or more below thede Vietnamese Vietnamese silklaufthermostattemperatur, is closed and is opened when the coolant limit temperature is exceeded, in particular below the opening temperature of thedeniklaufthermostats is opened, in particular below 5 ° C below the opening temperature of thechenlaufthermostattemperatur is opened.
- a manual transmission, or an automatic transmission of a vehicle can significantly reduce fuel consumption through improved lubrication.
- the oil for lubrication of the gearbox can be heated by a cooling circuit, in particular at high loads, the oil temperature can be heated quickly, or an elevated temperature can be cooled by a high load in the transmission through the cooling circuit.
- the transmission oil and the coolant can be heated by an exhaust gas heat exchanger, as described for example in SAE 2011-01-1171.
- the heat exchange between coolant and transmission oil is interrupted when the coolant temperature is lower than the switching temperature of a cooling circuit thermostat, whereby an external water cooler is switched on, and if the coolant flow through the coolant transmission oil heat exchanger is opened only when thedeniklaufthermostattemperatur is exceeded and thus the coolant is significantly heated, in particular only if a heat exchange From the coolant to the oil can take place, that is, when the temperature of the cooling circuit is only slightly below the temperature of the cooling circuit thermostat.
- This ensures that a heat transfer or heating of the lubricating oil by the cooling circuit takes place only when the cooling circuit has become correspondingly warm, or a cooling of the oil circuit takes place only when the vehicle has arrived in a warm-up phase.
- the transmission in the case of a transmission lubrication system, can be a manual transmission and the oil pump function can be provided by the displacement effect of a gear pair, in particular a Gereteendantriebs.
- an oil pressure line can be arranged on the side on which the two tooth flanks move toward one another and an oil return line can be arranged on the side on which the two tooth flanks move away from one another.
- manual transmissions are also significantly more efficient and lower consumption, if the oil temperature of the transmission is increased.
- typical gearboxes do not have a separate oil pump, such as those found in automatic transmissions, for example, so that the oil in a manual transmission can not be pumped through a heat exchanger and an effective lubrication circuit in manual transmissions is not present.
- additional electric oil pumps may be provided to provide oil circulation and, in particular, heat input through a heat source for transmission lubrication, but this requires extra space, additional cost, and consumes more electrical energy, part of the fuel reduction through the improved lubrication eating again.
- a lubricating circuit for a manual transmission in which a heat exchanger is connected to a cooling system, which is the Heated oil in the oil sump of the manual gearbox faster.
- an oil suction pipe carrying oil to the external oil exchanger may be disposed in the vicinity of a transmission end gear, which gears may move toward each other and thereby generate a pressure that can be used for the oil pumping action.
- the return from the oil heat exchanger may be provided at an opposite end of the gearbox drive, where gears move away from each other, creating a vacuum and providing an oil suction action.
- Blow-by gases are gases that can pass from the cylinder combustion chamber past the piston into the crankcase and that can not be released directly into the environment in order to comply with corresponding emission standards. These gases are usually returned to the engine supply, and not released into the environment, without first being cleaned by a catalyst.
- the most common use here corresponds to the so-called PCV, the positive crankcase ventilation.
- a crankshaft exhaust port is coupled to the air supply of the engine and a blow-by gas valve is provided, which connects the crankshaft housing with a fresh air supply, typically with an air filter.
- a disadvantage of this design is that fresh air penetrates into the crankcase and the fresh air in most cases is colder than the crankshaft temperature and consequently the crankshaft cools accordingly, so that the viscosity of the lubricating oil increases and especially in the cold start phase, a higher friction and thus an increased fuel consumption occurs.
- fresh air is prevented from entering the crankcase, which could lower an oil lubricating temperature.
- an oil cooling jet injects oil from the crankcase or through an opening of the oil line in the connecting rod to the underside of the cylinder piston at high pressure when high speeds or high load phases occur to coking the engine oil , which is located behind the piston ring to prevent.
- the piston spray cooling is controlled in response to engine oil pressure, such that, for example, at low oil pressures, such as less than 2 bar, no oil leaks through the spray nozzles and the mechanical power consumed by the oil pump is thereby reduced.
- This has the disadvantage that, during a warm-up phase, the oil pressure at the piston spray nozzles is relatively low and, due to the low engine speeds, no piston spray cooling takes place.
- the heat source may comprise a piston-spray cooling of an internal combustion engine, wherein an oil volume flow which is injected by piston spray nozzles to the underside of the pistons of the internal combustion engine, the largest oil volume flow in Represents engine lubrication system, but at least represents 30% of the funded by the oil pump oil flow.
- the Kolbenspritzdüsenölvolumenstrom be reduced as soon as the catalyst temperature is below a light-off temperature limit, ie Anspringgrenzwerttemperatur of the catalyst and Kolbenspritzdüsenölvolumenstrom can be reduced, in particular set to zero as soon as a predefinable limit oil pressure is reached.
- Increasing the orifice nozzle cross-sections that are larger than normal with oil flow through the piston orifice being greater than 30% of the total oil flow of the engine oil pump can effectively inject heat into the engine oil, regardless of engine speed, by controlling the oil flow rate through the piston injectors to get promoted. If the oil spray nozzles are open during the cold start phase, the oil may heat up more quickly when sprayed on the underside of the pistons, which are the warmest region of the engine, thus providing significantly improved lubrication in the cold start phase.
- the heat source may comprise at least part of an oil line, in particular a non-insulated oil line, between a combustion chamber of an internal combustion engine and a coolant channel.
- the oil line between a cylinder bore of the internal combustion engine and a coolant channel can be arranged in the upper region of the cylinder bore, wherein the distance between the lower end of the oil line and the upper end of the cylinder bore, which is sealed with the seal of the cylinder head, a maximum of 50% of the piston stroke is.
- the oil line is arranged between the combustion chamber and the coolant channel, be isolated on one side from the inside to the side of the coolant channel.
- the thermal conductivity of the one-sided insulation can be significantly lower than the thermal conductivity of the structural environment and preferably at least less than 1 W / (m K).
- the oil line can in particular run parallel to the cylinder center axis.
- a piston spray cooling and insulation of the oil galleries and the crankshaft and in particular by arranging a heat storage can be dispensed with, for example, a complex exhaust gas heat exchanger.
- the oil channels are arranged parallel to the central axis of the cylinder, they can be relatively easily manufactured, for example, drilled later and no complex casts for the cylinder jackets for circumferential, horizontal channels to the central axis are provided, which carry the risk that by residues of molding sand sensitive parts of the valve train as the bearings or solenoid valves of camshaft adjuster can be damaged. Furthermore, effective heating can be achieved by a parallel course of the oil passages, since the oil flows from the colder, lower end to the hot, upper end region and thus a temperature gradient go through and can be heated accordingly hot. By a half-side isolation of the oil guide channels compared to the water jacket cooling, the efficiency of the proposed measures can be significantly increased.
- a heat accumulator may be included for the transmission oil, which preferably has a chamber with a phase change material, and structurally integrates a coolant heat exchanger for heating the transmission oil with coolant in a unit.
- the heat exchanger requires a large amount of space, and in a cold start phase, hot fluid stored in the tank is mixed with return fluid so that the total temperature within the heat accumulator is reduced because the hot oil is replaced with cold lubricating oil. For this reason, complex oil guide channels are provided in numerous heat accumulators to control the movement of the engine oil, such as in the DE 87108302 A is described.
- a heat exchanger for at least two fluids in the heat accumulator with an already existing large volume and a correspondingly good insulation.
- exhaust gas and / or coolant could be considered as heat-emitting fluid, as heat-absorbing fluid engine oil and / or gear oil come into question.
- an exhaust gas / engine oil heat exchanger and a coolant / gear oil exchanger is conceivable, but also a combination thereof, for example a coolant / gear oil / engine oil heat exchanger or an exhaust / engine oil / gear oil heat exchanger.
- the at least two fluids may advantageously be coupled together by a chamber having a phase change material.
- a phase change material helps to set a preferred coupling temperature and to store heat or cold.
- the absorption of heat from the heat-emitting fluid melts the phase change material and the heat-emitting fluid is cooled. As the temperature decreases, the phase change material again freezes by dissipating heat to the heat receiving fluid, so that this is heated. The result is a storage of heat energy, a delayed heat transfer and a preferred heat transfer temperature.
- Placed on the gear lubrication system with the heat storage can be designed as a plate heat exchanger in a further advantageous embodiment of the invention with the heat storage integrated coolant heat exchanger, in each case the two outer first plates lead coolant and between the next, second plate is guided inward transmission oil and between the next, third plate inwardly a phase change material is arranged, and between the next, fourth plate inwardly engine oil is guided, further preferably between a respective next, fifth plate inside a phase change material is arranged, and further between each In the next, sixth plate in gearbox oil is guided, and further between a respective next, seventh plate is guided inwardly coolant, the sequence of further layers as mentioned above beechi g can continue.
- the coolant heat exchanger as a tube heat exchanger, wherein for example in an inner tube coolant, in a concentrically guided outer hollow cylinder wall gear oil in another concentric Hohlzylinderwandung a phase change material and in another concentric Hohlzylinderwandung engine oil. If necessary, the concentric structure of the tube heat exchanger can be repeated or the tube heat storage can be performed meandering.
- One or more valves in particular a coolant valve and / or a transmission oil valve for controlling the fluid flow through the various channels of the heat accumulator may be provided on the transmission lubrication system with the heat accumulator so that a coolant supply is interrupted when the coolant temperature is lower as a first coolant limit temperature, in particular 90 ° C and when the transmission oil temperature is higher than the coolant temperature, and that the transmission oil supply is interrupted when an engine oil temperature is below a first engine oil limit temperature, in particular less than 120 ° C.
- the transmission oil supply to the heat accumulator can be opened to the transmission lubrication system with the heat accumulator as soon as the engine oil temperature reaches a second heat exchanger engine oil limit temperature, in particular greater than 120 ° C. Furthermore, the transmission oil supply to the heat accumulator can be closed as soon as the engine oil temperature has reached a lower third heat exchanger engine oil limit temperature, in particular less than 90 ° C. In addition, preferably a cooling water supply to the integrated heat accumulator can be opened as soon as the transmission oil temperature is lower than the coolant temperature and the cooling water supply to the integrated heat accumulator can be closed as soon as the transmission oil temperature is greater than the coolant temperature.
- Exhaust gas heat exchangers are relatively expensive and complex because they have high temperatures and high pressures and the risk of leaks or fire have to counteract. It must take costly measures to prevent corrosion and pollution by the exhaust gases and an accumulation of water that can freeze must be prevented.
- an exhaust gas bypass line is arranged with exhaust bypass valve, so that a passage of exhaust gases through the exhaust oil heat exchanger is switchable, provided that the engine oil temperature or the transmission oil temperature reaches a maximum, optimal control of Heating can be achieved especially at high loads and the cold start phase. This in turn can be achieved an improved lubrication.
- an exhaust / oil heat exchanger for engine oil and transmission oil can be made in one piece. It may also be advantageous if the heat exchanger is flowed through in the countercurrent principle, in particular engine oil and gear oil flow through the heat exchanger in countercurrent, and preferably the region of the transmission oil-exhaust heat exchanger downstream of the range of engine oil exhaust gas heat exchanger is arranged.
- the exhaust gas / oil heat exchanger may be provided on the exhaust side with an exhaust gas bypass line and at least one exhaust gas bypass valve, so that an exhaust gas flow through the region of the engine oil exhaust gas heat exchanger at a predefinable first heat exchanger engine oil limit temperature, in particular of 120 ° C, is interrupted.
- the exhaust gas flow can be interrupted by the region of the transmission oil-exhaust heat exchanger when a predefinable first heat exchanger transmission oil limit temperature, in particular 90 ° C., is exceeded.
- the coolant of the coolant circuit may comprise a phase change material having a melting temperature above 0 ° C and a boiling temperature of at least 120 ° C, in which the density increases with increasing temperature, in particular during the phase transition from solid to liquid ,
- the coolant circuit filled with this phase change material can be integrated in the internal combustion engine to be cooled in such a way that no connecting lines leading to other components are present.
- a first coolant circuit with the phase change material can be surrounded by a second coolant circuit and cooled by it, wherein the second coolant circuit is filled with coolant having a melting temperature of at least below -30 ° C, and the second coolant circuit can be arranged outside the internal combustion engine components, in particular a cooler.
- phase change material may provide a higher boiling temperature than water so that the use of such material in the coolant system allows a higher peak temperature in the combustion chamber.
- phase change material has a low specific heat capacity and a lower thermal conductivity or both, so that large radiators, pumps and connecting lines are required in the cooling circuit.
- no phase change material can be used, which assumes a fixed state of aggregation at ambient temperatures between -40 ° C and 0 ° C, since in the solid state at high loads no waste heat can be transported to the radiator.
- a phase change material having a melting temperature between 40 ° C and 120 ° C is used, which is used only within an inner cooling circuit, so that the phase change material in a cold start phase very quickly reaches its melting point and becomes liquid and During the cold start phase can already dissipate heat.
- the inner cooling circuit is connected to an outer cooling circuit through a heat exchanger, wherein in the outer cooling circuit, for example, conventional coolant having a melting temperature of below -30 ° C can be used.
- a cooling system with separate cooling circuits for improved heating wherein the coolant through a cylinder head and through a cylinder block run separately, for example, from JSAE Review 23 (2002) p. 507-511 known.
- the coolant circuit may be interrupted by the cylinder block or engine block, wherein at higher temperatures, the coolant flows through the cylinder head in parallel through the cylinder block and from there to the radiator.
- this involves the disadvantage that the coolant does not move during a cold start phase in the cylinder block and thus local overheating may occur, especially under high engine load during the cold start.
- the refrigerant is disadvantageously moved to flow from top to bottom in a combined flow of cylinder head to the cylinder block and thus in the opposite direction to the convection, ie the heat flow, which acts from bottom to top, which the flow resistance on the Motor pump increases and an additional mechanical load and additional electrical consumption of the water pump conditionally.
- a cylinder-head coolant channel and a cylinder block coolant channel of the cooling circuit of an internal combustion engine may be structurally separated in order to achieve an acceleration of the coolant heating.
- a coolant first flows through the cylinder head for heating and from there through a cylinder / engine block, where the warm coolant heats a cylinder wall to reduce wall heat losses, and there it fed to a coolant pump.
- a first coolant flow direction thermostat can be opened in the cylinder head, and at least one partial volume flow of the coolant can be routed to a radiator.
- a seconddeffenschstromiquessthermostat in particular a 3-way thermostat at the previous output of the cylinder / engine block connect to the input of the coolant pump and connect to the output of the coolant pump, so that the coolant in the cylinder / engine block in the opposite direction as the coolant flows in the cylinder head, and a combined coolant flow from the cylinder head and cylinder / engine block is passed through the radiator.
- the coolant is first passed through the cylinder head, wherein at the end of the cylinder head, the coolant is fed back into the engine block, so that the cylinder block is also heated by the already heated in the cylinder head coolant and thus takes place an improvement of the combustion process, since the cylinder head typically heats up much faster and is warmer than the cylinder block - also due to the fact that the water jacket cooling in the cylinder head occupies much less space and hot exhaust gases are also passed through the cylinder head - so that the largest heat there arises.
- the coolant can heat up faster.
- a coolant thermostat may change the coolant flow direction such that coolant flows through a water cooler, and when the engine block becomes warm enough, the coolant may flow in parallel through the engine block and cylinder head for maximum cooling by the water coolers can.
- a sufficient cooling and a rapid heating or a uniform heating of the engine block is achieved, so that the lubricating oil is heated faster.
- the piston of an internal combustion engine is insulated on the inside of at least one piston skirt by insulation, the thermal conductivity of the insulation being 5% or less than the thermal conductivity of the piston skirt, and preferably at least less than 1 W / (FIG. m K), wherein preferably the inside of the piston crown is not isolated.
- the thermal conductivity of the insulation being 5% or less than the thermal conductivity of the piston skirt, and preferably at least less than 1 W / (FIG. m K), wherein preferably the inside of the piston crown is not isolated.
- a heat storage is provided to store oil in a desired temperature range between, may advantageously be provided for heating or cooling an exhaust gas heat exchanger, which is at least three-volume or three-channel or with three chambers, and the structurally integrated in the heat storage (14) can be.
- the exhaust gas heat exchanger may comprise a first volume that can be flowed through by at least a first partial exhaust gas flow, wherein the first volume through a first partition wall is limited or surrounded by a first partition, wherein on at least one of the sides of the first partition, which is not in communication with the exhaust partial flow, a phase change material may be arranged in a second volume bounded by a second partition or surrounded by a second partition is, wherein on at least one of the sides of the second partition, which is not in communication with the phase change material, lubricating oil is flowable through a third volume.
- the phase change material may comprise at least one sugar alcohol such as erythritol, threit or a paraffin, or a salt such as a hydrate, nitrate, hydroxide or a chloride such as magnesium chloride hexahydrate or magnesium nitrate hexahydrate, whose latent heat of fusion is greater than the heat which the heat storage due to the temperature difference of a first lower oil limit temperature of 50 ° C and a first upper oil limit temperature of 90 ° C can save.
- sugar alcohol such as erythritol, threit or a paraffin
- a salt such as a hydrate, nitrate, hydroxide or a chloride such as magnesium chloride hexahydrate or magnesium nitrate hexahydrate
- the melting temperature of the phase change material may be lower than the first upper oil limit temperature, and preferably, if the melting temperature of the phase change material is greater than 100 ° C, the phase change material erythritol with a melting temperature of about 120 ° C, so that in cold start a highest possible temperature in Heat storage can be reached in a short time.
- integrated in the heat accumulator three-chamber heat exchanger with an indirect coupling of oil and exhaust gas via a phase change material direct heat transfer from very hot exhaust gas to the oil is bypassed because the phase change material serves as a heat buffer.
- a local overheating of the oil by the phase change material (PCM - phase change material) is prevented as a damping layer.
- the PCM material for example magnesium chloride hexahydrate (MgCl2 x 6 H2O) is incombustible and thus reduces the risk of ignition.
- the exhaust gas heat exchanger can be constructively designed as a simple plate heat exchanger and integrated in the heat storage.
- the insulation of the heat accumulator insulates the heat exchanger so that it can ensure effective heat transfer very quickly during a cold start without the exhaust gas having to heat up the wall of the heat exchanger itself.
- the aforementioned heat exchanger can preferably be designed as a tube heat exchanger, be configured with at least three telescoped tubes.
- the tubes may be double-walled and be arranged a phase change material in the space between the inner tube and the outer tube. As a result, a separation, compact design and ease of manufacture can be easily achieved. If leakage did occur, it would be ensured that no liquid could escape into the heat accumulator since leakage could at most reach up to a PCM chamber.
- At least one of the exhaust gas connection lines of the exhaust gas heat exchanger integrated in the heat accumulator can be insulated from the heat accumulator by a ceramic line. As a result, the insulation effect is further improved, thereby reducing heat losses.
- an oil feed line of a cylinder head and / or a turbocharger downstream of the heat source may be connected to a cylinder block oil gallery.
- a coolant heat exchanger can be arranged in the oil supply line of the cylinder head and / or the turbocharger, which can be flowed through by coolant of a coolant circuit.
- a flow rate of the oil pump can be regulated, wherein a flow rate of the oil pump is increased in order to achieve an increased pumping volume flow within a heat accumulator as soon as an oil outlet temperature of the heat accumulator is below a predefinable oil leakage temperature of maximum 90 ° C and an oil inlet temperature of the Heat accumulator is above a predefinable oil inlet temperature limit of at least 90 ° C. It has been found that in the case of an aforementioned relatively high oil temperature in the oil circuit hardly comes to a displacement of the cold oil by the incoming hot oil, since the hot oil flows through short circuit through the cold oil.
- Fig. 1 shows a first embodiment 100 of a functional structure environment lubrication system 11 according to the invention, in particular for lubrication points such as oil gallery, crankshaft, bearings or a metallic structure environment 63 such as gear parts with metal environment and housing.
- a lubrication system can be used for example in a vehicle with an internal combustion engine, an electric vehicle or a hybrid vehicle.
- a crankshaft housing can be considered in which the crankshaft, bearing shell, connecting rod and housing form a metallic environment whose high specific thermal conductivity removes heat from oil at low ambient temperatures. Internal insulation of these areas, especially areas in contact with outside air, can accelerate heating of the oil.
- Lubricating oil is stored in an oil reservoir 1, which is sucked in via an oil strainer 2 and an electrically controlled pump 4.
- a pressure relief valve 5 is arranged downstream of the pump outlet, which in a case of overpressure in the oil lubrication circuit allows the oil to flow back into the oil reservoir 1 via the pump 4.
- the oil is passed through another oil filter 6 and via a heat source 7, in this case an exhaust gas oil heat exchanger, which has a thermal energy supply line 8 and a residual energy stream discharge line 9.
- This may be, for example, a supply pipe and an exhaust pipe between a catalyst of an internal combustion engine and the exhaust.
- the heat source 7 may also be a heat exchanger between the oil lubrication system and the coolant circuit, whereby the lubricating oil can be warmed up more in a cold start phase.
- at least one connecting line connects with lubrication points 11 or oil gallery line 10, which supplies the points to be lubricated with lubricating oil and having an inner thermal insulation 13, wherein an oil-carrying inner part 12 of the oil gallery 10 out is.
- the outer diameter D is substantially less than the inner diameter d, since the insulation is directed inward and reduces the cross-section, so that the surface-to-volume ratio is improved and the release of heat energy to the metal environment or structural environment 11, 63 is reduced.
- housing inner walls, oscillating components or other metal areas with which lubricating oil may come into contact may be provided with an insulating layer.
- the oil After performing the heated by the heat source 7 oil through an isolated environment to be lubricated points, the oil is returned to the oil reservoir 1, where it is available for the recycle.
- thermal insulation of oil gallery 10, lubrication points 11 and structural environment 63 after the heat source 7, the release of thermal energy to the metal environment, such as cylinder head or cylinder block is significantly reduced, so that when heated in a cold start phase, a low viscosity and thus a reduced Friction can be achieved, resulting in a reduced fuel consumption and reduced exhaust emissions of the internal combustion engine.
- the oil reservoir 1 may be thermally insulated and further parts, such as to be lubricated rotating or oscillating components and the surrounding housing to be isolated.
- the areas arranged after the oil pump 4 are largely thermally insulated, in particular the pressurized oil circulation area and the areas in which the heat is supplied by the heat source.
- Fig. 2 a further development of a lubrication system according to the invention, based on the structure of the lubrication system 100 of Fig. 1 builds up, and can be used comparably.
- a thermally insulated Heat accumulator 14 is arranged, which is connected in parallel to the oil suction pipe 3, and which can be switched via a three-two-way valve 15 in the ⁇ lsaugrohrtechnisch 3.
- thermally insulated heat accumulator 14 oil may be temporarily stored in a heated state to maintain the heat and associated reduced viscosity, allowing for improved heating in the thermally insulated structural environment such as lubrication points 11 and metallic environment 63 such as housings, components, etc. becomes.
- oil can be removed from a heat accumulator 14, which has a residual heat and thus a lower viscosity than the oil in the oil accumulator 1, which absorbs the ambient temperature.
- a heat accumulator 14 can be carried out highly insulated, for example, vacuum insulated, and mixes with the flow of oil with freshly inflowing cold oil, the mixing temperature of the oil in the heat accumulator 14 decreases.
- a thermally highly insulated heat accumulator 14 may be used, which comprises a freewheel piston 19 and the cylindrically executed heat accumulator 14 divides into two slidably large chambers 16 a and 16 b.
- the chamber 16b for example, cold oil can flow and be stored in the chamber 16a warm oil.
- the thermally insulated freewheel piston moves to the left and cold oil can flow into the chamber 16b, so that the pressure conditions in the heat accumulator 14 remain constant.
- a four-way valve 20 various modes for the heat-insulated oil reservoir 14 can be adjusted.
- a removal position in the left position, in the middle position, a connection of the two chambers and a right Aufladeposition in the chamber 16 a filled with oil from a heat source 7 and oil from chamber 16 b can be discharged back into the oil reservoir 1, adjustable.
- the two chambers are connected to prevent over-pressure with biased check valves 22, 23, so that an overpressure in one Chamber in the other chamber can be dismantled.
- the insulation 17 can be carried out very expensive, eg as a vacuum insulation, so that a temperature loss, for example, from 100 to 80 ° C at 25 ° C ambient temperature within more than 6 hours. This ensures that at least for a short-term parking of a vehicle of less than 24 hours, a sufficiently warm amount of lubricating oil is available to ensure optimal lubrication even in the cold-start phase.
- a further embodiment 100 of a lubrication system for an internal combustion engine is shown, which basically the structure of in Fig. 1 shown lubrication system 100 corresponds.
- the heat source 7 which is designed as exhaust gas heat exchanger 60
- another heat exchanger 24 is provided as a coolant heat exchanger, which is connected to a cooling circuit 61 via a two-two-way valve 25 switchable.
- a heat input can take place via the cooling circuit 61 as well as via the exhaust gas heat circuit into the heat source 7.
- Via a suction line 26 a fuel-air mixture enters a cylinder head 27 of an engine block 36, whereupon the exhaust gas is passed through a catalyst 28 into an exhaust pipe 55.
- a three-two exhaust bypass valve 29 is arranged, in which the exhaust stream can be passed through the Abgasmotorölkorsammlungleyer 7, 60 or on the other via an exhaust gas bypass line 30 can be fed directly to the exhaust 31, in particular if a minimum temperature of Oil is reached.
- the coolant valve 25, which is arranged downstream of the oil reservoir 1 in the oil circuit and via the exhaust oil heat exchanger 7, 60 which upstream to the oil gallery 10 and lubricating components 63 and lubrication points 11 is arranged, a heat input into the engine oil take place so that heated by the highly isolated oil gallery in the structural environment 11, 63 and thereby highly viscous oil can be distributed to the points to be lubricated before the oil is returned to the oil reservoir 1.
- FIG. 5a schematically an internal combustion engine 41 with engine block 36 and components such as cylinders with crankshaft 67, connecting rod 64 and piston 66 and cylinder block and cylinder head 27 shown with intake and exhaust valves.
- the engine block 36 has a cylinder center axis 58, wherein the cylinder head 27 has a cylinder head flange 35, a combustion chamber 34 and the engine block has a cylinder bore 38 in which the connecting rod 64 connects the crankshaft 67 with the piston 66.
- the cylinder jacket has a water jacket cooling 65 with channels 37 for cooling liquid, which, for example, in the Fig. 5b are shown as the coolant channel 37.
- Figs. 5b and 5c only two embodiments of oil guide pipe of a lubrication system 32 are shown, which extend in the upper region of the combustion chamber 34 in the height of the half cylinder 33 between Zylinderau H- and cylinder inner wall 62 and the coolant channel 37 of the water jacket cooling 65.
- the combustion chamber 34 which is the fastest heating component in the internal combustion engine 41, so that lubricating oil can be heated there particularly effectively, and this can serve as a heat source 7 for improved lubrication, especially during a cold running phase.
- Fig. 5b non-insulated oil lines 32 which can absorb heat of the cylinder wall and the combustion chamber 34 thermally isolated from the coolant passage 37.
- a further embodiment is shown, which is a unilaterally insulated oil passage 32, 56, wherein the oil guide line is half insulated from the coolant channel 37 and thus can be heated faster and provides better insulation of cylinder wall 62 against the coolant channel 37, while heat the cylinder inner wall 62nd can be registered in the oil.
- Fig. 6 shows based on the embodiment of the Fig. 1 another lubrication system 100, in addition to the in Fig. 1 Components shown a highly insulated pressure heat accumulator 14 in the pressurized area of the Oil lubrication line after the heat source 7, which is arranged in front of the heat-insulated structure environment 11, 63 with oil gallery 12. Heated oil can be added to the heat storage 14 switchable by the three-two-way valve 15, and be released if necessary, for example, in the cold start phase again.
- the heat accumulator 14 is disposed in the pressure range of the oil lubrication system 100, so that in particular when approaching a short-term shutdown of max.
- heat accumulator 14 is the in Fig. 6 illustrated heat accumulator 14 designed for high pressures and may have a different construction.
- the Fig. 7 shows a coolant circuit 61 in the coolant through an internal combustion engine 41 along two coolant channels 37 through a cylinder head 27 and through an engine block / cylinder block 36 can be performed.
- the heat of the cooling circuit can be discharged via a radiator 45 to a second coolant circuit 57 or to an air flow.
- a coolant pump 39 forces the coolant to circulate in the coolant circuit 57, and two switching valves, namely, the two-two coolant flow direction thermostat 44 and the three-two coolant flow direction thermostat 40, determine the direction and type of the coolant flow through the cylinder head 27 and engine block 36.
- Fig. 7a In the Fig. 7a is shown that, for example, in a cold start phase, the coolant via the coolant pump 39 first flows back through the cylinder head 27 and lockeddeffenstrom exercisessthermostat 44 through the engine block 36 so that a closed circuit is formed, in which no external cooling takes place and the coolant flow in anti-parallel through the Coolant channels 37 of the cylinder head 27 and engine block 36 flows.
- Fig. 7b shows a second switching option for a partial load range, in the a coolant flows through the cylinder head 27 and thereafter branched antiparallel through the engine block 36 back to the coolant pump 39 and partially via a -Wassererkühler 45 flows, whereby the cylinder head 27 well cooled and engine block 36 can be cooled less.
- a third shift variant for a full load operation is shown with the first coolant direction thermostat 44 open and the second coolant direction thermostat 40 also open so that the coolant flow can flow in parallel through the cylinder head 27 and engine block 36 so that maximum cooling performance can be provided.
- the in the three switching variants in Fig. 7a, 7b and 7c shown configurations can be switched at different load or cold and warm start phases of an internal combustion engine, wherein Fig. 7a in a cold warm-up phase can serve for rapid warming.
- Fig. 7b in a medium operating phase a low cooling effect and
- Fig. 7c represents a cooling circuit with a maximum cooling effect, so that the oil of a lubrication system can be heated quickly in all load cases and can achieve a low viscosity and optimum lubrication effect.
- a piston 66 of an internal combustion engine 41 which has an insulation 13 on the inside of the piston skirt 102 in an annular manner, which thermally insulates the piston skirt 102 from the cylinder inner wall 62.
- the thermal conductivity of the insulation 13 is 5% or less than the thermal conductivity of the piston skirt 102.
- the inside of the piston crown 103 is not insulated.
- the piston head 103 can heat up quickly in a cold start phase, wherein, for example, when using a piston spray cooling oil which is injected onto the underside of the piston, can be heated very quickly.
- FIG. 12 illustrates a wide embodiment of a lubrication system 100 that is substantially the embodiment of the present invention Fig. 1 equivalent.
- the shingles a structural environment 11 of an internal combustion engine include an oil gallery 10 with an oil-carrying inner part 12, which is supplied by the oil gallery 10 with lubricating oil.
- An oil supply line 104 branches off from the oil gallery 10 and lubricates a cylinder head 27.
- the oil supply line 104 of the cylinder head 27, which could also lubricate a turbocharger, is connected to the cylinder block oil gallery 10 downstream of an exhaust heat exchanger 60 as a heat source 7.
- a coolant heat exchanger 24 is arranged in the oil supply line 104 of the cylinder head 27, a coolant heat exchanger 24 is arranged.
- the coolant heat exchanger 24 is connected to an inlet and outlet 61 a, 61 b of a coolant circuit 61, which can cool or heat the lubricating oil as needed.
- a coolant control valve 25 is provided to control the heat exchange of the coolant heat exchanger 24.
- the isolated oil ducts are located in an oil supply area behind the oil pump, i. are arranged in the pressurized line area.
- This line has a larger circumference than the inner diameter of the line, at least in some areas, so that an improved surface volume ratio can be achieved.
- the insulation may preferably be made of plastic or ceramic and may be arranged internally or externally.
- the thermal conductivity of the isolated regions of the connecting line is 5% or less than that of the surrounding metal structure or oil gallery, in particular steel or cast iron having a thermal conductivity of about 50 W / mK and thus the insulation has a thermal conductivity of 2.5 W / mK, preferably 1 W / mK or less should have.
- the other areas to be isolated in addition to supply lines and the lubrication points are in particular gearbox or in an internal combustion engine, the crankcase, the oil pan and the oil gallery.
- For the thermal isolation of rotating or oscillating components are in particular crankshaft, crankshaft bearings and crankcase, camshafts and bearings and gear shaft and gears - preferably isolating the areas that are regularly wetted with oil in functional use. It is advantageous if no fresh air enters the crankcase, so that it is closed to the cold outside air, and possibly blow-by gases leak, but no cold fresh air can penetrate into the crankcase to allow increased or accelerated heating.
- phase change material used in the cooling circuit, then it is advisable to provide a second enveloping cooling circuit, wherein the first cooling circuit can be operated at elevated temperatures, and the second cooling circuit serves to cool the inner cooling circuit, wherein a freezing or a solid state the phase change material can be prevented, so that an operability can be achieved even at very low outdoor temperatures.
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- Engineering & Computer Science (AREA)
- Mechanical Engineering (AREA)
- General Engineering & Computer Science (AREA)
- Lubrication Of Internal Combustion Engines (AREA)
- Lubrication Details And Ventilation Of Internal Combustion Engines (AREA)
- General Details Of Gearings (AREA)
Description
Die Erfindung betrifft ein wärmeisoliertes Schmiersystem zur Schmierung von rotierenden oder oszillierenden Bauteilen, insbesondere ein Schmiersystem für ein Kraftfahrzeug, das zur Schmierung von beweglichen Teilen einer Verbrennungskraftmaschine wie Benzin- oder Dieselmotor und/oder zur Schmierung eines Getriebes eingesetzt werden kann. Das Schmiersystem kann beispielsweise in einem konventionell angetriebenen Fahrzeug oder in einem Hybrid- oder Elektrofahrzeug eingesetzt werden, aber auch in stationären Anlagen wie Stromgeneratoren, Arbeitsmaschinen etc.The invention relates to a heat-insulated lubricating system for lubricating rotating or oscillating components, in particular a lubrication system for a motor vehicle, which can be used for the lubrication of moving parts of an internal combustion engine such as gasoline or diesel engine and / or lubrication of a transmission. The lubrication system can be used for example in a conventionally driven vehicle or in a hybrid or electric vehicle, but also in stationary systems such as power generators, work machines, etc.
Schmiersysteme für bewegliche Teile eines Antriebes, insbesondere eines Motors oder mechanischen Getriebes sind hinlänglich bekannt. Sie dienen dazu, Reibung zwischen beweglichen Teilen zu verringern und einen Leichtlauf der beweglichen Teile gegeneinander zu verbessern. Hierdurch wird Abrieb vermindert, eine thermische Erwärmung der Teile verringert und somit die Lebensdauer erhöht. Eine Schwergängigkeit beweglicher Teile bedingt darüber hinaus eine erhöhte Antriebsenergie, die in unproduktiver Weise zur Überwindung der Schwergängigkeit eingesetzt werden muss und die einen erhöhten Kraftstoff- oder Stromverbrauch mit sich bringt, so dass zum einen Abgasemissionen erhöht, Betriebskosten gesteigert und z.B. eine Reichweite eines Kraftfahrzeugs verringert wird. Insbesondere eine Verringerung der Abgasbelastung und ein niedriger Energieverbrauch sind nicht nur technisch wünschenswerte Eigenschaften eines Motors, sondern international unabdingbare Voraussetzungen, um diverse staatliche Normen und Grenzwerte einzuhalten. Nicht zuletzt kann ein ineffizientes Schmiermanagement eines Antriebs zu erhöhter Steuer- und Abgabenlast des Betreibers führen.Lubricating systems for moving parts of a drive, in particular an engine or mechanical transmission are well known. They serve to reduce friction between moving parts and to improve smooth running of the moving parts against each other. This reduces abrasion, reduces thermal heating of the parts and thus increases the service life. A stiffness of moving parts also requires an increased drive energy that must be used in unproductive manner to overcome the stiffness and brings an increased fuel or electricity consumption, so that on the one hand increases exhaust emissions, increased operating costs and, for example, reduced a range of a motor vehicle becomes. In particular, a reduction in the exhaust gas load and a low energy consumption are not only technically desirable properties of an engine, but internationally indispensable prerequisites, to comply with various government standards and limits. Not least, an inefficient lubrication management of a drive can lead to increased tax and duty load of the operator.
In einer Kaltstartphase, insbesondere bei niedrigen Temperaturen wie 0°C oder Extremtemperaturen wie -15°C oder weniger ergibt sich das Problem, dass ein eingesetztes Schmiermedium, insbesondere Schmieröl, eine hohe Viskosität und somit verminderte Schmiereigenschaft aufweist. So ist in einem Verbrennungsmotor der Kraftstoffverbrauch während eines NEDC-Tests im kalten Zustand (Starttemperatur ca. 24 C) ca. 10 bis 15 % höher als bei demselben Test mit einer Motoröltemperatur in einem heißen Zustand von ca. 90 °C, dem sogenannten NEDC-Heißtest. Dies liegt unter anderem daran, dass das Schmieröl bei niedrigeren Temperaturen eine höhere Zähigkeit aufweist. Gleichzeitig wird ein Großteil der zugeführten Energie ungenutzt als Abgasenthalpie abgeführt. Dies sind insgesamt ca. 30 bis 40 % der Energie des zugeführten Kraftstoffes.In a cold start phase, in particular at low temperatures such as 0 ° C or extreme temperatures such as -15 ° C or less, there is the problem that an inserted lubricating medium, in particular lubricating oil, has a high viscosity and thus reduced lubricating property. Thus, in a combustion engine, the fuel consumption during a cold NEDC test (starting temperature about 24 C) about 10 to 15% higher than the same test with an engine oil temperature in a hot state of about 90 ° C, the so-called NEDC -Heißtest. This is partly because the lubricating oil has a higher toughness at lower temperatures. At the same time, a large part of the energy supplied is discharged unused as exhaust gas enthalpy. This is a total of about 30 to 40% of the energy of the fuel supplied.
Eine Möglichkeit zur Verringerung der Reibungsverluste besteht darin, hochwertige Schmieröle mit reduzierter Viskosität bei niedrigen Temperaturen einzusetzen, eine andere Möglichkeit zielt auf eine gezielte schnelle Erwärmung des Schmiermediums in der Kaltstartphase.One way to reduce friction losses is to use high quality lubricating oils with reduced viscosity at low temperatures, another option is to provide targeted rapid heating of the lubricant in the cold start phase.
Auf eine beschleunigte Erwärmung während einer Kaltstartphase zielen Vorschläge zum Einsatz von Wärmetauschern, die einen erhöhten Wärmeeintrag in das Schmiersystem insbesondere während einer Kaltstartphase liefern. Aus verschiedenen Veröffentlichungen ist hierzu bekannt, dass eine Aufheizung des Motoröls mit Hilfe eines Abgas-/Ölwärmetauschers den Kraftstoffverbrauch und die Abgasemissionen deutlich reduzieren können. Hierbei wird die Aufwärmphase des Motors dadurch beschleunigt, dass Abgaswärmetauscher eingesetzt werden, die in komplizierter Weise das Motoröl aufheizen und den Öldruck reduzieren. Dabei ergibt sich allerdings das Problem, den Motor, insbesondere das Motoröl, bei dieser Aufheizung vor Überhitzung zu schützen. Daher werden zusätzliche Hochleistungsölkühler verwendet. Die bekannten Lösungen sind allerdings technisch und konstruktiv aufwändig sowie fehleranfällig und führen nur zu einer relativ geringen Reduzierung des Kraftstoffverbrauches, so dass aus wirtschaftlichen Gründen die praktische Umsetzung meist nicht realisiert wird.To accelerate heating during a cold start phase, proposals are for the use of heat exchangers, which provide increased heat input into the lubrication system, especially during a cold start phase. It is known from various publications that a heating of the engine oil with the aid of an exhaust gas / oil heat exchanger can significantly reduce fuel consumption and exhaust emissions. In this case, the warm-up phase of the engine is accelerated by the use of exhaust gas heat exchangers, which heat the engine oil in a complicated manner and reduce the oil pressure. However, there is the problem of protecting the engine, in particular the engine oil, from overheating during this heating. Therefore, additional high performance oil coolers are used. The known solutions are However, technically and structurally complex and error-prone and lead only to a relatively small reduction in fuel consumption, so that for economic reasons, the practical implementation is usually not realized.
Beispielhaft wird hier auf die
Aus der
Weitere Lösungsvorschläge sind in den Konferenzbeiträgen:
In der
Aus der
Die
Nachteilig an den oberen Vorschlägen zur Reduzierung der Reibleistung sind zum einen der hohe konstruktive Aufwand sowie die erhöhte Fehleranfälligkeit sowie insbesondere die im Vergleich zum Aufwand nur geringe Reduzierung der Reibleistung, da das erwärmte Öl sich schnell wieder abkühlt, wenn es mit kühleren Bauteilen in Kontakt kommt, wie z.B. den Ölgalerien in Zylinderblock und Zylinderkopf sowie dem Gehäuse (z.B. Ölwanne und Kurbelgehäuse)..Disadvantages of the upper proposals for reducing friction losses are, on the one hand, the high design complexity and the increased susceptibility to errors, and in particular the small reduction in friction losses compared with the effort, since the heated oil quickly cools again when it comes into contact with cooler components , such as the oil galleries in cylinder block and cylinder head as well as the housing (for example oil sump and crankcase) ..
Aufgabe der folgenden Erfindung ist es, ein Schmiersystem vorzuschlagen, die die obengenannten Nachteile des Stands der Technik überwindet, eine einfache technische Umsetzung bietet und eine deutlich reduzierte Reibung insbesondere in der Kaltstartphase bietet.Object of the following invention is to propose a lubrication system that overcomes the above-mentioned disadvantages of the prior art, provides a simple technical implementation and offers a significantly reduced friction, especially in the cold start phase.
Gelöst wird die oben genannte Aufgabe durch ein Schmiersystem nach dem unabhängigen Anspruch 1. Vorteilhafte Ausführungsformen der Erfindung sind Gegenstand der abhängigen Ansprüche.The above object is achieved by a lubricating system according to the
Erfindungsgemäß umfasst das System zur Schmierung von rotierenden oder oszillierenden Bauteilen zumindest ein Ölsaugrohr, das in einem Ölspeicher angeordnet ist, eine Ölpumpe, eine Wärmequelle und weiteren Verbindungsleitungen, die in einem Metallgehäuse integriert sind, insbesondere eine Ölgalerie zur Verteilung von Schmieröl an die zu schmierenden Bauteile wie Kurbelwelle, Nockenwelle, Getriebeteile etc.. Der Ölspeicher kann ein offener und in der Regel nicht isolierter Speicher sein und kann in seiner konstruktiven Bauart einer Ölwanne entsprechen. Es wird vorgeschlagen, dass zumindest eine Verbindungsleitung innerhalb der Ölgalerie stromabwärts der Wärmequelle inwandig durch eine Innenisolierung isoliert ist, wobei die Wärmeleitfähigkeit der Innenisolierung 5% oder weniger als die Wärmeleitfähigkeit der Verbindungsleitungen bzw. der übrigen Ölgalerie und bevorzugt mindestens kleiner als 1 W/(m K) beträgt und die Wärmequelle abgeschaltet oder zumindest in ihrer Wärmeabgabe reduziert wird, wenn eine erste obere Ölgrenztemperatur erreicht wird. Der äußere Umfang der Verbindungsleitung kann zumindest an einer Stelle mindestens zweimal so groß sein, wie der innere Umfang der Verbindungsleitungen.According to the invention, the system for lubricating rotating or oscillating components comprises at least one oil suction pipe, which is arranged in an oil reservoir, an oil pump, a heat source and further connecting lines, which are integrated in a metal housing, in particular an oil gallery for distributing lubricating oil to the components to be lubricated such as crankshaft, camshaft, gear parts, etc. The oil reservoir can be an open and usually not isolated storage and can in its structural design of a Correspond to oil pan. It is proposed that at least one connection line within the oil gallery downstream of the heat source is insulated inwardly by an internal insulation, the thermal conductivity of the inner insulation being 5% or less than the thermal conductivity of the connection lines or the remaining oil gallery and preferably at least less than 1 W / (m K) and the heat source is switched off or at least reduced in its heat output when a first upper limit oil temperature is reached. The outer circumference of the connecting line can be at least twice as large as the inner circumference of the connecting lines, at least at one point.
Mit anderen Worten wird erfindungsgemäß vorgeschlagen, dass zumindest ein Teil einer Verbindungsleitung hinter einer Ölpumpe, d.h. in einem Druck stehenden Verbindungsleitungsbereich eines Schmiersystems und bevorzugt hinter einer Wärmequelle, wie beispielsweise einem Wärmetauscher eine Isolierung aufweist, insbesondere eine Innenisolierung, die einen thermischen Wärmeübergang vom Schmieröl zur metallischen Umgebung erschwert. Dadurch wird erreicht, dass nach einer Erwärmung eines unter Druck stehenden Ölvolumens dieses bei der Zuführung der zu schmierenden Stellen, insbesondere der Ölgalerie nur wenig seine aufgenommene Wärme an die metallische Umgebung, die einen hohen thermischen Leitwert besitzt, abgibt. Damit kann eine schnelle Aufheizung des Öls, das über Schmierstellen direkt an die zu schmierenden Stellen abgegeben wird, erreicht werden und somit eine reduzierte Reibung insbesondere beim Kaltstart bewirkt werden.In other words, it is proposed according to the invention that at least part of a connecting line behind an oil pump, i. in a pressurized connection line region of a lubricating system and preferably behind a heat source, such as a heat exchanger having insulation, in particular an inner insulation, which makes a thermal heat transfer from the lubricating oil to the metallic environment more difficult. This ensures that, after heating a pressurized volume of oil that in the supply of the points to be lubricated, especially the oil gallery only slightly absorbed his heat to the metallic environment, which has a high thermal conductivity value. Thus, a rapid heating of the oil, which is delivered via lubrication points directly to the points to be lubricated, can be achieved and thus a reduced friction, in particular during cold start can be effected.
So ist zwar aus der
Durch die Einführung einer Wärmeisolierung innerhalb einer Ölgalerie, insbesondere an Schmierstellen der funktionalen Strukturumgebung zum Schmieren der Bauteile, aber auch der strukturellen Strukturumgebung, die durch die Metallumgebung, Kurbelwelle, Pleuelstange, Nockenwelle, Lager, Zahnräder, Gehäusebereiche, Motorblock an der Innenwand eines Kurbel- oder Getriebegehäuses oder der gegeneinander bewegten Bauteile können mehrere Vorteile beim Übertragen der Wärme in den kalten Motorblock erreicht werden:
- Die Wärmeisolierung erhöht den thermischen Widerstand.
- Das Oberflächen- zu Volumenverhältnis wird verringert.
- Das Ölvolumen und damit auch die zu erwärmende Ölmenge in der Ölgalerie wird verringert.
- Der thermische Widerstand erhöht sich aufgrund des Kontaktwiderstands zwischen der Isolation und dem Motorblock oder den Zylinderköpfen.
- The thermal insulation increases the thermal resistance.
- The surface to volume ratio is reduced.
- The oil volume and thus also the amount of oil to be heated in the oil gallery is reduced.
- The thermal resistance increases due to the contact resistance between the insulation and the engine block or cylinder heads.
Durch eine Verringerung des Oberflächen-Volumenverhältnisses wird weniger Wärme an die metallische Umgebung abgegeben. Beispielhaft kann dies durch Betrachtung einer Isolationsleitung mit einer Wärmleitfähigkeit von 1 W/m K in eine Ölgalerie mit einem Durchmesser von 20 mm und einem inneren Durchmesser von 10 mm betrachtet werden. Der thermische Übergangswiderstand wird bei Betrachtung eines Wärmeübertragungskoeffizienten zwischen dem Öl- und dem Zylinderblock mit h = 40 betrachtet, wobei angenommen wird, dass das Öl 20°C wärmer als der Motorblock ist. Daraufhin ergibt sich ein thermischer Widerstand R = 1/(h A) = 1/ (h l π D) = 0.4 K/W. Der thermische Widerstand wird beschrieben durch
Somit kann im Ergebnis festgehalten werden, dass bei den oben genannten Werten:
- Die Isolation den
thermischen Übergangswiderstand um 25 % erhöht, - Das Oberflächen- zu Volumenverhältnis um 50 % reduziert wird, was den thermischen Widerstand um weitere 100 % erhöht,
- Das Ölvolumen in der Ölgalerie um 75 % abgesenkt wurde,
- Der thermische Widerstand aufgrund des Kontaktwiderstandes sich nochmals um zusätzliche 100 % erhöht.
- The insulation increases the thermal contact resistance by 25%,
- The surface to volume ratio is reduced by 50%, which increases the thermal resistance by a further 100%,
- The oil volume in the oil gallery was lowered by 75%,
- The thermal resistance due to the contact resistance increases again by an additional 100%.
Aus diesem Grund ist der gesamte thermische Übergangswiderstand 3.3 Mal größer als ohne die vorgeschlagene Innenisolation. Aus diesem Grund kann eine verbesserte Aufheizung erreicht werden, da der Energieverlust des Öls in der Kaltstartphase abgesenkt und eine verbesserte Schmierung in der Kaltstartphase gegeben ist.For this reason, the total thermal contact resistance is 3.3 times greater than without the proposed inner insulation. For this reason, improved heating can be achieved because the energy loss of the oil in the cold start phase is lowered and improved lubrication in the cold start phase is given.
In der Veröffentlichung der Japanese Society of Automotive Engineers (JSAE 235-20125071 wird zur verbesserten Erwärmung von Öl in einer Kaltstartphase vorgeschlagen, das Öl im Ölspeicher in zwei Teilvolumen aufzuteilen, wobei in einer Warmlaufphase nur ein Teil des Öls im Ölspeicher zur Schmierung verwendet wird. Wenn die gleiche Wärmemenge in das reduzierte Ölvolumen eingebracht wird, kann sich das Öl doppelt so schnell erwärmen, wie wenn die Wärmemenge in die gesamte Ölmenge eingebracht werden würde. Allerdings hat sich herausgestellt, dass dies nicht zutreffend ist, wie in der Veröffentlichung JSAE 235-20125071 dargestellt ist. Dabei hat sich gezeigt, dass durch eine Aufteilung des Ölspeichers in zwei Teilvolumen es für das außen liegende kältere Ölvolumen deutlich wurde, dass im Rahmen eines Tests die maximale Temperatur von 85°C auf 45°C, d.h. um 40°C abgesenkt wurde, während allerdings in dem inneren Ölvolumen die Temperatur nicht gleichermaßen um 40°C von 85°C auf 125°C erhöht werden konnte. Da das Ölvolumen der inneren Kammer geringer war als das der äußeren Kammer, wurde erwartet, dass die Temperaturzunahme umso größer ausfallen sollte. Auch dies hat sich als Trugschluss herausgestellt, da die Temperatur im Inneren nur um maximal 5°C erhöht werden konnte, was zu einer sehr geringen Einsparung des Kraftstoffs um lediglich 0,8 % geführt hat. Als Ursache wurde erkannt, dass die Wärme des inneren Ölvolumens hauptsächlich durch die Wärmeübertragung zwischen dem Motorblock und der Kurbelwelle abgeführt wurde, wobei das Öl an die Außenwandung des Kurbelwellengehäuses geschleudert wird, sobald es die Kurbelwellenlager erreicht. Die Gehäusetemperatur und die Temperatur des Motorblocks bestimmen somit durch ihre großen Oberflächen überwiegend die Öltemperatur. Aus diesem Grunde kann die Öltemperatur die Kühlmitteltemperatur und die Temperatur des Motors nicht deutlich überschreiten, zumindest nicht bei durchschnittlichen Kaltstartphasen und somit nur eine geringe Kraftstoffeinsparung erreicht werden. Eine verbesserte Isolation allerdings überwindet diese Nachteile, führt zu einer deutlich reduzierten Reibung, einem deutlich niedrigen Verbrauch und niedrigeren Abgasemissionen.In the publication of the Japanese Society of Automotive Engineers (JSAE 235-20125071) it is proposed to divide the oil in the oil reservoir into two sub-volumes for improved heating of oil in a cold start phase, during which only a portion of the oil in the oil reservoir is used for lubrication during a warm-up phase. If the same amount of heat is introduced into the reduced volume of oil, the oil can heat up twice as fast as if the amount of heat were added to the total amount of oil, although this has been found to be inaccurate, as described in the publication JSAE 235- It has been shown that dividing the oil reservoir into two partial volumes made it clearer for the outer colder oil volume that during a test the maximum temperature increased from 85 ° C to 45 ° C, ie around 40 ° C was lowered while, however in the internal volume of oil, the temperature could not be increased equally by 40 ° C from 85 ° C to 125 ° C. Since the oil volume of the inner chamber was lower than that of the outer chamber, it was expected that the temperature increase should be larger. This, too, has proved to be a fallacy, since the temperature inside could only be increased by a maximum of 5 ° C, resulting in a very small fuel saving of only 0.8%. As a cause, it was recognized that the heat of the inner oil volume was mainly dissipated by the heat transfer between the engine block and the crankshaft, the oil being thrown to the outer wall of the crankcase as soon as it reaches the crankshaft bearings. The housing temperature and the temperature of the engine block thus predominantly determine the oil temperature due to their large surfaces. For this reason, the oil temperature can not significantly exceed the coolant temperature and the temperature of the engine, at least not achieved at average cold start phases and thus only a small fuel economy. Improved insulation, however, overcomes these disadvantages, resulting in significantly reduced friction, significantly lower fuel consumption and lower exhaust emissions.
Eine Innenisolierung eines Metallgehäuses und einer Metallleitung ermöglicht weiterhin, Ölleitungen und Gehäuse aus Metall oder dauerhaften, allerdings wärmeleitfähigen Materialien herzustellen, und gegebene äußere mechanische Abmessungen beizubehalten, da lediglich eine innere Isolierung einzusetzen ist, und äußere Abmessungen und konstruktive Details beibehalten werde können und somit eine Umkonstruktion ein vorhandenen Aggregatdesigns vermieden werden kann. Durch eine Innenisolierung von Ölleitungen und Gehäuseteile können bestehende Motoren und Aggregate effizienter werden, ohne konstruktive Änderungen vornehmen zu müssen.An internal insulation of a metal housing and a metal conduit also makes it possible to produce oil conduits and housings made of metal or permanent, but thermally conductive materials, and to maintain given external mechanical dimensions, since only an internal insulation is to be used, and external dimensions and structural details can be maintained and thus Rebuilding an existing aggregate design can be avoided. Internal insulation of oil pipes and housing parts makes existing engines and units more efficient without having to make design changes.
Gemäß einer vorteilhaften Weiterbildung der Erfindung kann das Gehäuse des Schmiersystems, insbesondere ein Kurbel- oder Getriebegehäuse, durch eine Innenisolierung isoliert sein, wobei die Wärmeleitfähigkeit der Innenisolierung 5 % oder weniger als die Wärmeleitfähigkeit einer Strukturumgebung, insbesondere als die Wärmeleitfähigkeit von Schmierstellen, einem Gehäuse, den zu schmierenden Bauteilen, einer Metallumgebung, beträgt und bevorzugt mindestens kleiner als 1 W/(m K) ist. Die Strukturumgebung beschreibt eine funktionelle Strukturumgebung des Schmiersystems, d.h. Schmierstellen, an denen sich Oberflächen gegeneinander bewegen, als auch strukturelle Strukturumgebungen, d.h. das umliegende Material wie Metallgehäuse, Bauteile, Motorblock etc..According to an advantageous embodiment of the invention, the housing of the lubrication system, in particular a crankcase or transmission housing, by a Be isolated inside insulation, wherein the thermal conductivity of the
Gemäß einer weiteren vorteilhaften Weiterbildung kann der Ölspeicher durch eine Innenisolierung isoliert sein, wobei die Wärmeleitfähigkeit der Innenisolierung 5 % oder weniger als die Wärmeleitfähigkeit des Ölspeichers beträgt und bevorzugt mindestens kleiner als 1 W/(m K) ist. Alternativ oder zusätzlich kann der Ölspeicher komplett oder zumindest teilweise aus einem isolierenden Material gefertigt sein, welches eine Wärmeleitfähigkeit von bevorzugt höchstens kleiner als 1 W/(m K) aufweist.According to a further advantageous development of the oil reservoir can be isolated by an inner insulation, wherein the thermal conductivity of the inner insulation is 5% or less than the thermal conductivity of the oil reservoir, and preferably at least less than 1 W / (m K). Alternatively or additionally, the oil reservoir may be made entirely or at least partially of an insulating material which has a thermal conductivity of preferably at most less than 1 W / (m K).
Gemäß einer vorteilhaften Ausbildung der Erfindung kann zumindest eine der zu schmierenden, rotierenden oder oszillierenden Bauteile durch zumindest eine Innenisolierung und/oder Außenisolierung isoliert sein, wobei die Wärmeleitfähigkeit der Außenisolierung 5 % oder weniger als die Wärmeleitfähigkeit der zu schmierenden, rotierenden oder oszillierenden Bauteile, beträgt, und bevorzugt mindestens kleiner als 1 W/(m K) ist.According to an advantageous embodiment of the invention, at least one of the components to be lubricated, rotating or oscillating can be insulated by at least one inner insulation and / or outer insulation, wherein the thermal conductivity of the outer insulation is 5% or less than the thermal conductivity of the rotating or oscillating components to be lubricated , and is preferably at least less than 1 W / (m K).
Durch Isolierung sowohl des Kurbelwellengehäuses als auch des Ölsumpfs von innen und auch zumindest Teilbereiche der rotierenden oder oszillierenden Bauteile, die zu schmieren sind, kann das Öl nur geringfügig Wärme an die metallische Umgebung verlieren und wird nicht so stark heruntergekühlt, wobei das Öl in der Kaltstartphase durch höhere Wärmeeinträge beispielsweise durch eine Wärmequelle erwärmt wird, beispielsweise durch einen Abgasölwärmetauscher. Durch die Isolation der Kurbelwelle wird die thermische Masse, die zur Abkühlung des Öls zur Verfügung steht, reduziert und durch die Isolation des inneren Kurbelwellengehäuses, die sehr bedeutend für den Wärmeerhalt des Öls angesehen werden kann, kann eine verbesserte Aufwärmung bei niedriger Viskosität des Öls erreicht werden.By insulating both the crankshaft housing and the oil sump from the inside and also at least portions of the rotating or oscillating components to be lubricated, the oil can only slightly lose heat to the metallic environment and is not so much cooled down, the oil in the cold start phase is heated by higher heat inputs, for example by a heat source, for example by an exhaust gas heat exchanger. Due to the isolation of the crankshaft, the thermal mass, which is available for the cooling of the oil, is reduced and due to the insulation of the inner Crankshaft housing, which can be considered very significant for the heat retention of the oil, an improved heating at low viscosity of the oil can be achieved.
Gemäß einer vorteilhaften Weiterbildung kann ein hochisolierter Wärmespeicher insbesondere mit einer mindestens 5mm dicken Wärmespeicherisolierung mit einer Wärmeleitfähigkeit von unter 0.01 W/(m K) umfasst sein, der insbesondere zwischen einem Ölsaugrohr und einer Ölpumpe oder zwischen einer Ölpumpe und einer Wärmequelle, oder zwischen einer Wärmequelle und einer Schmierstelle angeordnet ist, wobei bevorzugt ein Temperaturverlust von Öl mit einer Temperatur von 100°C auf 80°C bei 25°C Umgebungstemperatur in mehr als 6 Stunden erfolgt. Bevorzugt kann die Wärmespeicherisolierung als Vakuumisolierung ausgeführt sein.According to an advantageous development, a highly insulated heat accumulator may in particular be provided with at least 5 mm thick heat storage insulation with a thermal conductivity of less than 0.01 W / (m K), in particular between an oil suction pipe and an oil pump or between an oil pump and a heat source, or between a heat source and a lubricating point, wherein preferably a temperature loss of oil at a temperature of 100 ° C to 80 ° C at 25 ° C ambient temperature in more than 6 hours. Preferably, the heat storage insulation can be designed as a vacuum insulation.
Um eine Verbesserung der Wärmespeicherung in dem vorgenannten Wärmespeicher zu erreichen, kann es sich als vorteilhaft erweisen, wenn die Ölanschlussleitungen und/ oder ein Außenmantel des Wärmespeichers aus einem wärmeisolierenden Material mit einer Wärmeleitfähigkeit kleiner als 20 W/(m K) besteht. Hierzu kann vorteilhafterweise eine Kunststoffisolierung eingesetzt werden. Des Weiteren kann der Außenmantel des Wärmespeichers doppelwandig ausgeführt sein und in dem Zwischenraum zwischen der Innenwand und Außenwand des Außenmantels kann eine Isolierschicht aus Aerogel angeordnet sein, die eine Wärmeleitfähigkeit von unter 0.04 W/(m K) aufweist. Weiterhin kann das mit Aerogel gefüllte Volumen einen Unterdruck zur Umgebung aufweisen. Hierdurch wird die Isolierung deutlich verbessert und Wärmeverluste bzw. ein ungewollter Wärmeeintrag verhindert.In order to achieve an improvement in the heat storage in the aforementioned heat storage, it may prove advantageous if the oil connection lines and / or an outer jacket of the heat accumulator consists of a heat-insulating material having a thermal conductivity of less than 20 W / (m K). For this purpose, advantageously a plastic insulation can be used. Furthermore, the outer jacket of the heat accumulator can be double-walled and in the intermediate space between the inner wall and outer wall of the outer jacket, an insulating layer of airgel can be arranged, which has a thermal conductivity of less than 0.04 W / (m K). Furthermore, the filled with airgel volume may have a negative pressure to the environment. As a result, the insulation is significantly improved and prevents heat loss or unwanted heat input.
Auf das Schmiersystem mit dem Wärmespeicher aufsetzend kann in einer weiteren vorteilhaften Ausbildung der Erfindung das Schmiersystem ein Umleitungsventil umfassen, so dass der Wärmespeicher bei Erreichen einer zweiten oberen Ölgrenztemperatur außerhalb des Wärmespeichers von mindestens 90°C mit Öl gefüllt wird und bei einem Kaltstart der zu schmierenden Bauteile unter einer vorgegebenen ersten unteren Ölgrenztemperatur von höchstens 50°C außerhalb des Wärmespeichers das gespeicherte Öl im Wärmespeicher an das Schmiersystem abgegeben kann.In a further advantageous embodiment of the invention, the lubrication system may comprise a bypass valve, so that the heat accumulator is filled with oil at least 90.degree. C. when reaching a second upper oil limit temperature outside the heat accumulator and at a cold start the oil to be lubricated components under a predetermined first lower oil limit temperature of at most 50 ° C outside the heat storage, the stored oil in the heat storage can be delivered to the lubrication system.
Der Einsatz von Wärmespeichern in einem Schmiersystem ist seit mehreren Jahren bekannt. Diese werden oftmals dazu eingesetzt, den Fahrgastinnenraum bevorzugt zu erwärmen und Abgase zu reduzieren, insbesondere bei Kaltstart unter 0°C, wie es bereits in der Veröffentlichung SAE 922244 dargestellt wurde. Die Nachteile von derartigen Wärmespeichern sind vergleichbar mit denen der vorgenannten zweiteiligen Ölsümpfe bzw. Ölspeicher, wobei die Treibstoffeinsparung nur gering ausfällt, wie Untersuchungen bei Umgebungstemperaturen von 24°C gezeigt haben. Auch die Erläuterung, warum derartige Wärmespeicher nur einen geringen Beitrag zur Reduzierung des Kraftstoffverbrauchs leisten können, sind dieselben wie bei einem zwei- oder mehrteiligen Ölsumpf, da die eingebrachte Wärme in den Zylinderköpfen und im Motorblock in der Kaltstartphase schnell wieder abgegeben wird. Der vorgeschlagene Wärmespeicher kann dies allerdings mit den vorgeschalteten Ausführungsformen vorteilhaft überwinden, wobei überschüssige Wärme im Wärmespeicher von einem Kühlsystem oder durch einen Kühler oder durch einen Ölkühler abgegeben werden kann, und durch die verbesserte Wärmeisolierung die Wärme direkt die Ölviskosität senkt und zur Reibungsreduktion beiträgt und somit zu einer Verringerung des Kraftstoffverbrauchs führt.The use of heat accumulators in a lubrication system has been known for several years. These are often used to heat the passenger compartment preferred and reduce exhaust gases, especially at cold start below 0 ° C, as it was already shown in the publication SAE 922244. The disadvantages of such heat accumulators are comparable to those of the aforementioned two-part oil sumps or oil reservoirs, the fuel saving being low, as investigations at ambient temperatures of 24 ° C. have shown. Also, the explanation of why such heat storage can make only a small contribution to reducing fuel consumption, are the same as in a two- or multi-part oil sump, since the introduced heat is released quickly in the cylinder heads and in the engine block in the cold start phase. However, the proposed heat accumulator can advantageously overcome this with the preceding embodiments, wherein excess heat in the heat accumulator can be discharged from a cooling system or through a radiator or through an oil cooler, and through the improved thermal insulation the heat directly lowers the oil viscosity and contributes to friction reduction and thus leads to a reduction in fuel consumption.
Auf das Schmiersystem mit dem Wärmespeicher aufsetzend kann in einer vorteilhaften Weiterbildung der Wärmespeicher zumindest eine separate Kammer aufweisen, die mit einem Phasenwechselmaterial, insbesondere mit einem Zuckeralkohol, wie Erythrit, Threit oder ein Paraffin oder ähnliches oder einem Salz, bevorzugt ein Hydrat, Nitrat, Hydroxyd oder Chlorid wie Magnesiumchloridhexahydrat oder Magnesiumnitrathexahydrat gefüllt sein. Die latente Schmelzwärme des Phasenwechselmaterials sollte wesentlich größer als die Wärme, die der Wärmespeicher aufgrund der Temperaturdifferenz der ersten unteren und ersten oberen Ölgrenztemperatur speichern kann, sein. Hierbei sollte insbesondere die Schmelztemperatur des Phasenwechselmaterials niedriger als die erste obere Ölgrenztemperatur sein, und bevorzugt - sofern die Schmelztemperatur des Phasenwechselmaterials größer 100°C ist - das Phasenwechselmaterial Erythrit mit einer Schmelztemperatur von ca. 120°C sein, so dass im Kaltstart eine höchst mögliche Temperatur im Wärmespeicher vorliegt. Vorzugsweise wird als Phasenwechselmaterial ein Zuckeralkohol eingesetzt, und die Schmelztemperatur des Phasenwechselmaterials wird auf über 100°C vorgesehen.Attaching to the lubricating system with the heat storage can have in an advantageous development of the heat storage at least a separate chamber with a phase change material, in particular with a sugar alcohol, such as erythritol, threit or a paraffin or the like or a salt, preferably a hydrate, nitrate, hydroxide or chloride such as magnesium chloride hexahydrate or magnesium nitrate hexahydrate. The latent heat of fusion of the phase change material should be much greater than the heat that the heat storage due to the temperature difference of the first lower and first upper limit oil temperature can be. Here, in particular, the melting temperature of the phase change material should be lower than the first upper oil limit temperature, and preferably - if the melting temperature of the phase change material is greater than 100 ° C - the phase change material erythritol be with a melting temperature of about 120 ° C, so that in cold start a highest possible Temperature is present in the heat storage. Preferably, a sugar alcohol is used as the phase change material, and the melting temperature of the phase change material is provided above 100 ° C.
Wie bereits weiter oben erwähnt, sind Latentwärmespeicher bereits aus dem Stand der Technik bekannt. Sie benutzen in diversen Ausführungen Salz, dass eine Schmelztemperatur von 60°C bis 80°C aufweist, wie z.B. Bariumhydroxid oder Sodiumsilikate, wobei derartige Salze materialaggressiv sind und Korrosionsschäden verursachen, die zu Undichtigkeiten im Kühlsystem oder im Schmiersystem führen können. Aus diesem Grund wurde eine Serienproduktion derartiger Latentwärmespeicher eingestellt. Ein weiterer Nachteil der vorbekannten Latentwärmespeicher mit Phasenwechselmaterial war, dass die Schmelztemperatur typischerweise zwischen 60°C und 80°C liegt, die deutlich zu gering ist für eine optimale Temperatur zur Ölschmierung, die bei bevorzugt 120°C liegt. Somit konnte auch der Einsatz derartiger Latentspeicher mit Phasenwechselmaterial auf Salzbasis keine nachhaltig verbesserte Schmiereigenschaft im Kaltstartbereich ermöglichen. Eine Verwendung von Phasenwechselmaterial mit Phasenwechseltemperaturen über 80°C, insbesondere Erythritol als Latentwärmespeichermedium, überwindet diese Probleme, da es eine Schmelztemperatur aufweist, die optimal für die Schmierung mit Motorölen ist.As already mentioned above, latent heat storage are already known from the prior art. They use in various embodiments salt that has a melting temperature of 60 ° C to 80 ° C, such as. Barium hydroxide or Sodium silicates, such salts are material aggressive and cause corrosion damage that can lead to leaks in the cooling system or in the lubrication system. For this reason, a series production of such latent heat storage has been set. Another disadvantage of the known latent heat storage with phase change material was that the melting temperature is typically between 60 ° C and 80 ° C, which is clearly too low for an optimum temperature for oil lubrication, which is preferably 120 ° C. Thus, the use of such latent storage with salt-based phase change material could not sustainably improved lubrication in the cold start area. Use of phase change material with phase change temperatures above 80 ° C, especially erythritol as latent heat storage medium, overcomes these problems because it has a melting temperature that is optimal for lubrication with engine oils.
Auf das Schmiersystem mit dem Wärmespeicher aufsetzend kann in einer vorteilhaften Ausbildung der Erfindung der Wärmespeicher zylindrisch ausgeführt und einen Freikolben aus wärmeisolierendem Material umfassen, der den Wärmespeicher in zwei Kammern aufteilt. Hierdurch wird beim Füllen des Wärmespeichers mit Öl oberhalb einer ersten oberen Ölgrenztemperatur von mindestens 90°C in die erste Kammer ein Ölvolumen aus der zweiten Kammer in das Schmiersystem zurückgeschoben und beim Entleeren des Öls aus der ersten Kammer in einer Kaltstartphase unter einer ersten unteren Ölgrenztemperatur von höchstens 50°C in das Schmiersystem wird die zweite Kammer mit Öl gefüllt. Somit wird der Ölstand in dem Ölspeicher nur unwesentlich beeinflusst und der Wärmespeicher ist bedarfsweise als Wärmequelle, insbesondere als Heizeinrichtung und als Wärmesenke, insbesondere Kühleinrichtung nutzbar. Die Ölgrenztemperatur kann eine Öltemperatur von Schmieröl irgendwo im Schmierölkreislauf sein, vorteilhafterweise unmittelbar an einer Anschlussstelle des Wärmespeichers oder einer Ölauslassstelle, an der typischerweise die höchsten zu erwartenden Öltemperaturen auftreten, wie bspw. Austrittsstelle aus dem Motorblock etc. Im Falle des Füllens des Wärmespeichers wird heißes Öls des Ölkreislaufs vom Wärmespeicher aufgenommen und kühleres Öl abgeben, der Wärmespeicher dient somit als Wärmesenke. In einer Kaltstartphase und beim Entleeren des Wärmespeichers wird kühleres Öl aufgenommen und wärmeres abgegeben, der Wärmespeicher dient als Wärmequelle.Attaching to the lubrication system with the heat storage can be carried out cylindrically in an advantageous embodiment of the invention, the heat storage and comprise a free piston of heat-insulating material, which divides the heat storage in two chambers. This is when filling the Heat storage with oil above a first upper limit oil temperature of at least 90 ° C in the first chamber, an oil volume from the second chamber pushed back into the lubrication system and when emptying the oil from the first chamber in a cold start phase below a first lower limit oil temperature of at most 50 ° C in the lubrication system will fill the second chamber with oil. Thus, the oil level in the oil reservoir is only insignificantly influenced and the heat storage is required, as a heat source, in particular as a heater and as a heat sink, in particular cooling device usable. The oil limit temperature may be an oil temperature of lubricating oil somewhere in the lubricating oil circuit, advantageously directly at a junction of the heat accumulator or Ölauslassstelle where typically the highest expected oil temperatures occur, such as. Exit point from the engine block, etc. In the case of filling the heat accumulator is hot Oil of the oil circuit absorbed by the heat storage and emit cooler oil, the heat storage thus serves as a heat sink. In a cold start phase and when emptying the heat accumulator cooler oil is absorbed and released warmer, the heat storage serves as a heat source.
Bei einer hohen Belastung der zu schmierenden Teile erhöht sich die Öltemperatur, so dass eine Kühlwirkung des im isolierten Wärmespeicher gespeicherten und niedertemperierten Öls ausgenutzt werden kann. So kann vorteilhafterweise der Wärmespeicher eingerichtet sein, ein Entleeren von Öl aus der ersten Kammer zur Ölkühlung zu bewirken, sobald Öl im Ölkreislauf eine zweite obere Ölgrenztemperatur von mindestens 110°C überschreitet. In diesem Fall ist typischerweise eine Öltemperatur von Öl in der ersten Kammer niedriger als die zweite obere Ölgrenztemperatur, so dass das aus dem Wärmespeicher ausströmende Öl kälter als das einströmende Öl ist. Hierdurch kann effektiv eine Kühlung des Öls erreicht und eine optimale Schmierwirkung und Viskosität erreicht und eine Überhitzung im Ölkreislauf verhindert werden.At a high load on the parts to be lubricated, the oil temperature increases, so that a cooling effect of stored in the insulated heat storage and low-temperature oil can be exploited. Thus, advantageously, the heat accumulator can be arranged to effect an emptying of oil from the first chamber for oil cooling, as soon as oil in the oil circuit exceeds a second upper oil limit temperature of at least 110 ° C. In this case, typically, an oil temperature of oil in the first chamber is lower than the second upper oil limit temperature, so that the oil flowing out of the heat accumulator is colder than the inflowing oil. This effectively achieves cooling of the oil and achieves optimum lubricity and viscosity, and prevents overheating in the oil circuit.
Ein weiteres Problem von Wärmespeichern ist es, dass während der Kaltstartphase rücklaufendes abgekühltes Öl sich mit dem gespeicherten erwärmten Öl mischt, so dass sich eine Mischtemperatur einstellt, die niedriger ist als die vorherige Temperatur im Wärmespeicher, bevor ein Austausch mit der Umgebung stattfand. Durch das Absenken der Temperatur vermindert sich die Schmiereigenschaft und damit die Reibung im Schmiersystem. Dieses Problem kann dadurch gelöst werden, dass im Wärmespeicher ein Freikolben vorgesehen ist, wobei der Wärmespeicher bevorzugt eine zylindrische Form aufweist, die den Speicher in zwei Unterkammern unterteilt, die durch Schaltventile miteinander verbunden sind, so dass das vorgewärmte Öl sich nicht mit dem zu setzenden kalten Öl vermischen kann. Durch den Freikolben wird das Ölvolumen konstant gehalten, so dass sich dies nicht nachteilig auf die Druckverhältnisse und das Ölvolumen im Schmierkreislauf auswirkt.Another problem of heat accumulators is that during the cold start phase returning cooled oil mixes with the stored heated oil to establish a mixing temperature lower than the previous temperature in the heat storage before interchanging with the environment. Lowering the temperature reduces the lubricating property and thus the friction in the lubrication system. This problem can be solved in that a free piston is provided in the heat accumulator, wherein the heat accumulator preferably has a cylindrical shape, which divides the memory into two sub-chambers, which are interconnected by switching valves, so that the preheated oil does not settle with the can mix cold oil. By the free piston, the oil volume is kept constant, so that this does not adversely affect the pressure conditions and the oil volume in the lubrication circuit.
Gemäß einer vorteilhaften Weiterbildung der Erfindung können das Schmiersystem, Ölspeicher, Strukturumgebung und Wärmequelle von einer Verbrennungskraftmaschine umfasst sein, insbesondere von einer Verbrennungskraftmaschine eines Kraftfahrzeuges.According to an advantageous development of the invention, the lubricating system, oil reservoir, structural environment and heat source can be comprised by an internal combustion engine, in particular by an internal combustion engine of a motor vehicle.
Alternativ oder zusätzlich zur vorstehenden Weiterbildung können das Schmiersystem, Ölspeicher und Strukturumgebung von einem Getriebe umfasst sein, insbesondere einem Kraftfahrzeuggetriebe und die Wärmequelle kann durch eine Verbrennungskraftmaschine und/oder eine elektrische Batterie und/oder einen Inverter bereitgestellt werden. Ein Inverter kann Gleich- in Wechselstrom und umgekehrt wandeln und wird zum Antrieb von Wechsel- und Drehstromantrieben durch Batterien und Akkumulatoren verwendet. So kann ein Schmiermedium in einem Getriebe oder einer Kraftübertragungsmechanik durch eine Abwärme eines Verbrennungsmotors erwärmt werden, oder beispielsweise beim Einsatz in einem Elektro- oder Hybridfahrzeug durch eine Erwärmungseigenschaft einer Batterie bzw. Akkumulators oder eines elektrischen Verbrauchers, die bei Energieabgabe oder -aufnahme warm werden. Auch ist denkbar, dass eine Brennstoffzelle, z.B. im Falle eines Wasserstoffantriebes, eine Wärmequelle zur Erwärmung des Schmiersystems für die Antriebsmechanik/Getriebes zur Verfügung stellt.Alternatively or additionally to the above development, the lubrication system, oil reservoir and structural environment may be comprised of a transmission, in particular a motor vehicle transmission, and the heat source may be provided by an internal combustion engine and / or an electric battery and / or an inverter. An inverter can convert DC to AC and vice versa and is used to drive AC and AC drives through batteries and accumulators. Thus, a lubricating medium in a transmission or a power transmission mechanism may be heated by waste heat from an internal combustion engine, or, for example, when used in an electric or hybrid vehicle by a heating characteristic of a battery or an electrical consumer, which become warm when the energy is released or absorbed. It is also conceivable that a fuel cell, for example in the case of a hydrogen drive, a heat source for heating the lubrication system for the drive mechanism / transmission provides.
Elektrische Fahrzeuge und Hybridfahrzeuge, die aus einer Kombination aus Elektro- und Verbrennungsmotor angetrieben werden, sind mit dem Problem konfrontiert, dass sie zum einen keine intrinsische Wärmequelle wie einen Verbrennungsmotor aufweisen, und dennoch die Schmiereigenschaft insbesondere bei Temperaturen unterhalb 30°C deutlich nachlassen und damit Reibung erhöht und der Energieverbrauch gesteigert wird. Zur schnellen Aufheizung des Schmieröls kann Abwärme genutzt werden, die beispielsweise durch einen Inverter, eine Brennstoffzelle oder eine elektrische Batterie erzeugt wird, oder es kann Abwärme eines elektrischen Aggregats verwendet werden, um eine optimale Schmiertemperatur zu erreichen, insbesondere für ein Getriebe. Es kann beispielsweise ein Kühlkreislauf vorgesehen werden, der Getriebe, Inverter und Batterie miteinander verbindet, um das Getriebe schneller zu erwärmen bzw. durch einen Kühlmittel-Ölwärmetauscher Getriebeöl zu erwärmen und den Inverter bzw. die Brennstoffzelle bzw. die Batterie zu kühlen, wodurch eine verbesserte Effizienz, erhöhte Reichweite und niedriger Verbrauch erreicht werden kann.Electric vehicles and hybrid vehicles, which are powered by a combination of electric and internal combustion engine, are confronted with the problem that they on the one hand have no intrinsic heat source such as an internal combustion engine, and yet the lubricating property, especially at temperatures below 30 ° C significantly lower and thus Increased friction and increased energy consumption. For rapid heating of the lubricating oil waste heat can be used, which is generated for example by an inverter, a fuel cell or an electric battery, or waste heat of an electrical unit can be used to achieve an optimum lubrication temperature, especially for a transmission. For example, a refrigeration cycle may be provided which interconnects the transmission, inverter, and battery to more quickly heat the transmission or heat transmission oil through a coolant-oil heat exchanger and cool the inverter or fuel cell, thereby providing improved performance Efficiency, increased range and low consumption can be achieved.
Gemäß einer vorteilhaften Ausbildung nach den beiden obigen Ausführungsformen der Erfindung kann ein Wärmespeicher Motoröl und Getriebeöl in einer Baueinheit, und insbesondere zumindest eine Kammer für Motoröl und eine Kammer für Getriebeöl umfassen.According to an advantageous embodiment according to the above two embodiments of the invention, a heat storage engine oil and transmission oil in a structural unit, and in particular comprise at least one chamber for engine oil and a chamber for transmission oil.
Durch einen kombinierten Wärmespeicher für Motoröl und Getriebeöl, der insbesondere separate Kammern für beide Ölschmiersysteme umfasst, kann ein einheitliches Tankvolumen bereitgestellt werden, wobei der Speicher eine einzige hochwertige Isolation aufweist und nur wenig Bauraum benötigt. So kann beispielsweise ein hochwertig isolierter Tank, der eine Vakuumisolation aufweist oder der mit einem Phasenwechselmaterial gefüllt ist, bereitgestellt werden, der insbesondere zwei Kammern für die beiden getrennten Schmiersysteme aufweist. Durch Integration in eine einzige Baueinheit kann das Gesamtvolumen deutlich reduziert werden, insbesondere bei kritischen Platzproblemen, wie sie in einem Kraftfahrzeug auftreten. Des Weiteren können Bauteilkosten eingespart und eine hochwertige Isolation für die gesamte Baueinheit verwendet werden, was deutlich geringere Kosten und minimierte Problemen bei der Entwicklung derartiger Schmiersysteme mit sich bringt.By a combined heat storage for engine oil and transmission oil, which in particular includes separate chambers for both oil lubrication systems, a uniform tank volume can be provided, the memory has a single high-quality insulation and requires little space. Thus, for example, a high-quality insulated tank, which has a vacuum insulation or which is filled with a phase change material, are provided, in particular two chambers for the two separate lubrication systems having. By integration into a single unit, the total volume can be significantly reduced, especially in critical space problems, such as occur in a motor vehicle. In addition, component costs can be saved and high-quality insulation used throughout the assembly, resulting in significantly lower costs and minimized problems with the development of such lubrication systems.
Gemäß einer weiteren vorteilhaften Weiterbildung kann die Wärmequelle im Falle einer Verbrennungskraftmaschine einen Abgaswärmetauscher umfassen, oder die Wärmequelle insbesondere im Falle der Anwendung bei einem Getriebe einen Kühlmittelwärmetauscher und/oder einem Abgaswärmetauscher einer Verbrennungskraftmaschine umfassen. Im Falle einer Kombination von Kühlmittelwärmetauscher und Abgaswärmetauscher kann der Abgaswärmetauscher stromabwärts des Kühlmittelwärmetauschers angeordnet sein. Im Kühlmittelkreislauf kann ein Kühlmittelventil angeordnet sein, welches bei Unterschreiten einer Kühlmittelgrenztemperatur, insbesondere unterhalb einer Öffnungstemperatur des Kühlkreislaufthermostats zur Aktivierung eines Hauptwasserkühlers, insbesondere höchstens 10°C unter der Kühlkreislaufthermostattemperatur, geschlossen ist und bei Überschreiten der Kühlmittelgrenztemperatur geöffnet wird. Insbesondere unterhalb der Öffnungstemperatur des Kühlkreislaufthermostats kann das Kühlmittelventil geöffnet werden, bevorzugt unterhalb 5°C unter der Öffnungstemperatur des Kühlkreislaufthermostattemperatur.According to a further advantageous refinement, in the case of an internal combustion engine, the heat source can comprise an exhaust gas heat exchanger, or the heat source, in particular in the case of application in a transmission, can comprise a coolant heat exchanger and / or an exhaust gas heat exchanger of an internal combustion engine. In the case of a combination of coolant heat exchanger and exhaust gas heat exchanger, the exhaust gas heat exchanger may be arranged downstream of the coolant heat exchanger. In the coolant circuit, a coolant valve may be arranged, which is closed when falling below a coolant limit temperature, in particular below an opening temperature of the cooling circuit thermostat for activating a main water cooler, in particular at most 10 ° C below the Kühlkreislaufthermostattemperatur and is opened when the coolant temperature limit is exceeded. In particular, below the opening temperature of the cooling circuit thermostat, the coolant valve can be opened, preferably below 5 ° C below the opening temperature of the Kühlkreislaufthermostattemperatur.
Gemäß einer vorteilhaften Ausbildung der Erfindung kann das Getriebe ein manuelles Schaltgetriebe oder ein Automatikschaltgetriebe sein, welches keine Ölpumpe aufweist, wobei im Ölspeicher ein Kühlmittelwärmetauscher angeordnet ist, so dass das Getriebeöl vom Motorkühlmittel aufgewärmt wird. Hierbei ist es vorteilhaft, dass der Kühlmittelwärmetauscher kühlmittelseitig mit einem Kühlmittelventil versehen ist, welches bei Unterschreiten einer Kühlmittelgrenztemperatur, insbesondere unterhalb der Öffnungstemperatur eines Kühlkreislaufthermostats zur Aktivierung des Hauptwasserkühlers, insbesondere 10°C oder mehr unterhalb der Kühlkreislaufthermostattemperatur, geschlossen wird und bei Überschreiten der Kühlmittelgrenztemperatur geöffnet wird, insbesondere unterhalb der Öffnungstemperatur des Kühlkreislaufthermostats geöffnet wird, insbesondere unterhalb 5°C unter der Öffnungstemperatur des Kühlkreislaufthermostattemperatur geöffnet wird.According to an advantageous embodiment of the invention, the transmission may be a manual transmission or an automatic transmission, which has no oil pump, wherein a coolant heat exchanger is arranged in the oil reservoir, so that the transmission oil is warmed up by the engine coolant. It is advantageous that the coolant heat exchanger is provided on the coolant side with a coolant valve, which falls below a coolant temperature limit, in particular below the opening temperature of a cooling circuit thermostat for activating the main water cooler, in particular 10 ° C. or more below the Kühlkreislaufthermostattemperatur, is closed and is opened when the coolant limit temperature is exceeded, in particular below the opening temperature of the Kühlkreislaufthermostats is opened, in particular below 5 ° C below the opening temperature of the Kühlkreislaufthermostattemperatur is opened.
Ein Schaltgetriebe, bzw. ein Automatikschaltgetriebe eines Fahrzeugs kann durch eine verbesserte Schmierwirkung deutlich den Kraftstoffverbrauch senken. Bevorzugt kann das Öl zur Schmierung des Schaltgetriebes durch einen Kühlkreislauf erwärmt werden, wobei insbesondere bei hohen Belastungen die Öltemperatur schnell erwärmt werden kann, bzw. eine erhöhte Temperatur durch eine hohe Last im Schaltgetriebe durch den Kühlkreislauf gekühlt werden kann. Daneben ist denkbar, dass das Getriebeöl und das Kühlmittel durch einen Abgaswärmetauscher erwärmt werden kann, wie es beispielsweise in der SAE 2011-01-1171 beschrieben ist. Wird allerdings unmittelbar ein Kühlmittelwärmetauscher zur Erwärmung des Getriebeöls eingesetzt, so hat dies den Nachteil, dass sich das Kühlmittel durch seine größere spezifische Wärmekapazität langsamer erwärmt als das Getriebeöl und dadurch Reibung und Wärmeverluste des Motors insbesondere in der Kaltstartphase verschlechtert werden, so dass der Treibstoffverbrauch höher ist, als die Vorteile, die durch den Austausch von Wärme zwischen Kühlmittelkreislauf und Getriebeöl erreicht werden. So hat beispielsweise die SAE 2011-01-1171 Untersuchung gezeigt, dass die Kühlmitteltemperatur langsamer steigt als die Schmieröltemperatur innerhalb eines Automatikgetriebes. Um dies zu überwinden, kann es vorteilhaft sein, wenn zusätzlich zu der verbesserten Isolation des Schmiersystems der Wärmeaustausch zwischen Kühlmittel und Getriebeöl unterbrochen wird, wenn die Kühlmitteltemperatur geringer ist als die Schalttemperatur eines Kühlkreislaufthermostats, wodurch ein externer Wasserkühler zugeschaltet wird, und wenn der Kühlmittelfluss durch den Kühlmittelgetriebeölwärmetauscher erst dann geöffnet wird, wenn die Kühlkreislaufthermostattemperatur überschritten ist und somit das Kühlmittel deutlich erwärmt ist, insbesondere erst dann, wenn ein Wärmeaustausch vom Kühlmittel zum Öl stattfinden kann, d.h. wenn die Temperatur vom Kühlkreislauf nur geringfügig unter der Temperatur des Kühlkreislaufthermostates liegt. Somit ist sichergestellt, dass ein Wärmeübergang bzw. eine Erwärmung des Schmieröls durch den Kühlkreislauf erst dann stattfindet, wenn der Kühlkreislauf entsprechend warm geworden ist, bzw. eine Kühlung des Ölkreislaufs erst dann stattfindet, wenn das Fahrzeug in einer Warmlaufphase angelangt ist.A manual transmission, or an automatic transmission of a vehicle can significantly reduce fuel consumption through improved lubrication. Preferably, the oil for lubrication of the gearbox can be heated by a cooling circuit, in particular at high loads, the oil temperature can be heated quickly, or an elevated temperature can be cooled by a high load in the transmission through the cooling circuit. In addition, it is conceivable that the transmission oil and the coolant can be heated by an exhaust gas heat exchanger, as described for example in SAE 2011-01-1171. However, if a coolant heat exchanger is used directly for heating the transmission oil, this has the disadvantage that the coolant heats up more slowly due to its greater specific heat capacity than the transmission oil and thereby friction and heat losses of the engine are impaired, especially in the cold start phase, so that the fuel consumption is higher is than the benefits that can be achieved by the exchange of heat between the coolant circuit and transmission oil. For example, the SAE 2011-01-1171 investigation has shown that the coolant temperature rises more slowly than the lubricating oil temperature within an automatic transmission. To overcome this, it may be advantageous if, in addition to the improved isolation of the lubrication system, the heat exchange between coolant and transmission oil is interrupted when the coolant temperature is lower than the switching temperature of a cooling circuit thermostat, whereby an external water cooler is switched on, and if the coolant flow through the coolant transmission oil heat exchanger is opened only when the Kühlkreislaufthermostattemperatur is exceeded and thus the coolant is significantly heated, in particular only if a heat exchange From the coolant to the oil can take place, that is, when the temperature of the cooling circuit is only slightly below the temperature of the cooling circuit thermostat. This ensures that a heat transfer or heating of the lubricating oil by the cooling circuit takes place only when the cooling circuit has become correspondingly warm, or a cooling of the oil circuit takes place only when the vehicle has arrived in a warm-up phase.
Gemäß einer weiteren vorteilhaften Weiterbildung kann im Falle eines Getriebeschmiersystems das Getriebe ein Handschaltgetriebe sein und die Ölpumpenfunktion kann durch die Verdrängungswirkung eines Zahnradpaares, insbesondere eines Getriebeendantriebs, erbracht werden. Hierbei kann vorteilhaft eine Öldruckleitung auf der Seite angeordnet sein, auf der sich die beiden Zahnflanken aufeinander zu bewegen und eine Ölrücklaufleitung kann auf der Seite angeordnet sein, auf der sich die beiden Zahnflanken voneinander weg bewegen.According to a further advantageous development, in the case of a transmission lubrication system, the transmission can be a manual transmission and the oil pump function can be provided by the displacement effect of a gear pair, in particular a Getriebeendantriebs. In this case, advantageously, an oil pressure line can be arranged on the side on which the two tooth flanks move toward one another and an oil return line can be arranged on the side on which the two tooth flanks move away from one another.
Vergleichbar mit Automatikgetrieben sind auch Schaltgetriebe deutlich effizienter und verbrauchsärmer, wenn die Öltemperatur der Getriebe erhöht ist. Allerdings weisen typische Schaltgetriebe keine separate Ölpumpe auf, wie sie beispielsweise in Automatikgetrieben vorhanden sind, so dass das Öl in einem Schaltgetriebe nicht durch einen Wärmetauscher gepumpt werden kann und ein effektiver Schmierkreislauf in Schaltgetrieben nicht vorhanden ist. Zum einen können zusätzliche elektrische Ölpumpen vorgesehen sein, um einen Ölkreislauf und insbesondere einen Wärmeeintrag durch eine Wärmequelle für die Getriebeschmierung zur Verfügung zu stellen, jedoch benötigt dies zusätzlichen Bauraum, zusätzliche Kosten und verbraucht mehr elektrische Energie, die einen Teil der Treibstoffreduzierung durch die verbesserte Schmierung wieder auffrisst. Aus diesem Grund kann entsprechend der vorteilhaften Weiterentwicklung zum einen ein Schmierkreislauf für ein Schaltgetriebe vorgeschlagen werden, bei dem ein Wärmetauscher mit einem Kühlsystem verbunden ist, der das Öl im Ölsumpf des manuellen Schaltgetriebes schneller erwärmt. Um eine Ölpumpenwirkung herzustellen, kann ein Ölsaugrohr, das Öl zum externen Öltauscher führt, in der Nähe eines Getriebeendzahnrades angeordnet sein, wobei die Zahnräder sich zueinander bewegen und dadurch einen Druck erzeugen können, der für die Ölpumpenwirkung genutzt werden kann. Die Rückleitung vom Ölwärmetauscher kann an einem entgegengesetzten Ende des Getriebeendantriebs vorgesehen sein, wo Zahnräder sich voneinander weg bewegen, wobei sie einen Unterdruck erzeugen und eine Ölansaugwirkung bereitgestellt werden kann. Hierdurch lässt sich ohne zusätzlichen Aufwand eine Ölpumpenwirkung zum Betrieb eines Schmierkreislaufs zur Verfügung stellen, wobei durch eine externe Wärmequelle und eine verbesserte Isolation des Schmiersystems ein niedrigerer Verbrauch erreicht werden kann.Like automatic transmissions, manual transmissions are also significantly more efficient and lower consumption, if the oil temperature of the transmission is increased. However, typical gearboxes do not have a separate oil pump, such as those found in automatic transmissions, for example, so that the oil in a manual transmission can not be pumped through a heat exchanger and an effective lubrication circuit in manual transmissions is not present. On the one hand, additional electric oil pumps may be provided to provide oil circulation and, in particular, heat input through a heat source for transmission lubrication, but this requires extra space, additional cost, and consumes more electrical energy, part of the fuel reduction through the improved lubrication eating again. For this reason, according to the advantageous development, on the one hand, a lubricating circuit for a manual transmission can be proposed, in which a heat exchanger is connected to a cooling system, which is the Heated oil in the oil sump of the manual gearbox faster. In order to produce an oil pumping action, an oil suction pipe carrying oil to the external oil exchanger may be disposed in the vicinity of a transmission end gear, which gears may move toward each other and thereby generate a pressure that can be used for the oil pumping action. The return from the oil heat exchanger may be provided at an opposite end of the gearbox drive, where gears move away from each other, creating a vacuum and providing an oil suction action. As a result, an oil pump action for operating a lubrication circuit can be provided without any additional effort, whereby a lower consumption can be achieved by an external heat source and improved insulation of the lubrication system.
Blow-by-Gase sind Gase, die vom Zylinderbrennraum am Kolben vorbei in das Kurbelwellengehäuse gelangen können und die nicht direkt in die Umwelt abgegeben werden dürfen, um entsprechende Abgasnormen zu erfüllen. Diese Gase werden in der Regel in die Motorzuluft zurückgeleitet, und nicht in die Umwelt abgegeben, ohne vorher durch einen Katalysator gereinigt zu werden. Der am meisten bekannte Einsatz hierbei entspricht der sogenannten PCV, der positive crankcase ventilation. Dabei wird eine Kurbelwellenabgasöffnung mit der Luftzufuhr des Motors gekoppelt und ein Blow-by-Gasventil wird vorgesehen, dass das Kurbelwellengehäuse mit einer Frischluftzufuhr, typischerweise mit einem Luftfilter verbindet. Ein Nachteil dieser Konstruktion liegt darin, dass Frischluft in das Kurbelwellengehäuse eindringt und die Frischluft in den meisten Fällen kälter als die Kurbelwellentemperatur ist und demzufolge die Kurbelwelle entsprechend abkühlt, so dass das die Viskosität des Schmieröl steigt und insbesondere in der Kaltstartphase eine höhere Reibung und damit ein erhöhter Kraftstoffverbrauch auftritt.Blow-by gases are gases that can pass from the cylinder combustion chamber past the piston into the crankcase and that can not be released directly into the environment in order to comply with corresponding emission standards. These gases are usually returned to the engine supply, and not released into the environment, without first being cleaned by a catalyst. The most common use here corresponds to the so-called PCV, the positive crankcase ventilation. In this case, a crankshaft exhaust port is coupled to the air supply of the engine and a blow-by gas valve is provided, which connects the crankshaft housing with a fresh air supply, typically with an air filter. A disadvantage of this design is that fresh air penetrates into the crankcase and the fresh air in most cases is colder than the crankshaft temperature and consequently the crankshaft cools accordingly, so that the viscosity of the lubricating oil increases and especially in the cold start phase, a higher friction and thus an increased fuel consumption occurs.
Gemäß einer vorteilhaften Weiterbildung kann die Wärmequelle eine Verbindungsleitung der Abgasleitung einer Verbrennungskraftmaschine mit einem Kurbelgehäuse oder einem Motorblock umfassen, wobei das Kurbelgehäuse keine Verbindungsleitung zwischen Umgebungsluft und Kurbelgehäuse aufweist, so dass keine Abkühlung des Kurbelgehäuses durch die Umgebungsluft erfolgen kann Durch das Kurbelgehäuse strömt somit mehr Abgas der Verbrennungskraftmaschine. Somit wird verhindert, dass Frischluft in das Kurbelwellengehäuse eintritt, die eine Ölschmiertemperatur herabsetzen könnte.According to an advantageous development, the heat source, a connecting line of the exhaust pipe of an internal combustion engine with a Crankcase or include an engine block, wherein the crankcase has no connecting line between the ambient air and crankcase, so that no cooling of the crankcase can be done by the ambient air through the crankcase thus flows more exhaust of the internal combustion engine. Thus, fresh air is prevented from entering the crankcase, which could lower an oil lubricating temperature.
In vielen modernen Verbrennungskraftmaschinen insbesondere mit Turboaufladung sind Kolbenspritzkühlungsvorrichtungen vorgesehen, bei dem ein Ölkühlstrahl Öl aus dem Kurbelgehäuse oder durch eine Öffnung der Ölleitung im Pleuel auf die Unterseite des Zylinderkolbens mit hohem Druck spritzt, wenn hohe Drehzahlen oder hohe Lastphasen auftreten, um ein Verkoken des Motoröls, das sich hinter dem Kolbenring befindet, zu verhindern. In vielen Fällen wird die Kolbenspritzkühlung in Abhängigkeit von einem Motoröldruck gesteuert, so dass beispielsweise bei niedrigen Öldrücken, wie kleiner 2 Bar, kein Öl durch die Spritzdüsen austritt und die mechanische Leistung, die von der Ölpumpe aufgenommen wird, dadurch verringert wird. Nachteilig hieran ist, während einer Warmlaufphase der Öldruck an den Kolbenspritzdüsen relativ gering ist und aufgrund der niedrigen Motordrehzahlen keine Kolbenspritzkühlung erfolgt. Wenn allerdings Öl durch die Kolbenspritzdüsen austreten würde, würde eine schnellere Erwärmung des Öls stattfinden können, die in Kombination mit einer verbesserten Isolierung, bei der die Ölgalerie und das Kurbelwellengehäuse bzw. die Kurbelwelle isoliert sind, zu einer deutlich verbesserten Ölerwärmung führen würde. Da die Öffnungen der Kühldüsen relativ gering sind, kann nur ein geringer Anteil des gesamtes Ölflusses durch Kolbenspritzdüsen treten, normalerweise weniger als 30 % während eine Kolbenspritzkühlung aktiv ist.In many modern internal combustion engines, in particular with turbocharging piston injection cooling devices are provided in which an oil cooling jet injects oil from the crankcase or through an opening of the oil line in the connecting rod to the underside of the cylinder piston at high pressure when high speeds or high load phases occur to coking the engine oil , which is located behind the piston ring to prevent. In many cases, the piston spray cooling is controlled in response to engine oil pressure, such that, for example, at low oil pressures, such as less than 2 bar, no oil leaks through the spray nozzles and the mechanical power consumed by the oil pump is thereby reduced. This has the disadvantage that, during a warm-up phase, the oil pressure at the piston spray nozzles is relatively low and, due to the low engine speeds, no piston spray cooling takes place. However, if oil spilled out through the piston spray nozzles, faster heating of the oil would take place, which, in combination with improved insulation isolating the oil gallery and crankcase or crankshaft, would result in significantly improved oil heating. Since the openings of the cooling nozzles are relatively small, only a small portion of the total oil flow can pass through plunger nozzles, usually less than 30%, while plunger spray cooling is active.
Gemäß einer weiteren vorteilhaften Weiterbildung kann die Wärmequelle eine Kolbenspritzkühlung einer Verbrennungskraftmaschine umfassen, wobei ein Ölvolumenstrom, der durch Kolbenspritzdüsen an die Unterseite der Kolben der Verbrennungskraftmaschine gespritzt wird, den größten Ölvolumenstrom im Motorschmiersystem darstellt, zumindest aber 30 % des von der Ölpumpe geförderten Ölvolumenstromes darstellt. Hierbei kann - sofern ein Katalysator vorgesehen ist - der Kolbenspritzdüsenölvolumenstrom reduziert werden, sobald die Katalysatortemperatur unter einem Light-off Temperaturgrenzwert, d.h. Anspringgrenzwerttemperatur des Katalysators liegt und der Kolbenspritzdüsenölvolumenstrom kann reduziert, insbesondere auf Null gesetzt werden, sobald ein vordefinierbarer Grenzöldruck unterschritten wird. Durch eine Erhöhung der Austrittsdüsenquerschnitte, die größer als normalerweise ausfallen, wobei ein Ölfluss durch den Kolbenspritzdüsenaustritt, der größer als 30 % des gesamten Ölflusses der Motorölpumpe beträgt, kann bei einer Steuerung der Ölflussmenge durch die Kolbenspritzdüsen unabhängig von der Motordrehzahl ein effizienter Wärmeeintrag in das Motoröl befördert werden. Wenn während der Kaltstartphase die Ölspritzdüsen offen sind, kann das Öl sich schneller erwärmen, wenn es auf die Unterseite der Kolben gespritzt wird, die den wärmsten Bereich des Motors darstellen und so eine deutlich verbesserte Schmierung in der Kaltstartphase ermöglichen.According to a further advantageous development, the heat source may comprise a piston-spray cooling of an internal combustion engine, wherein an oil volume flow which is injected by piston spray nozzles to the underside of the pistons of the internal combustion engine, the largest oil volume flow in Represents engine lubrication system, but at least represents 30% of the funded by the oil pump oil flow. In this case - if a catalyst is provided - the Kolbenspritzdüsenölvolumenstrom be reduced as soon as the catalyst temperature is below a light-off temperature limit, ie Anspringgrenzwerttemperatur of the catalyst and Kolbenspritzdüsenölvolumenstrom can be reduced, in particular set to zero as soon as a predefinable limit oil pressure is reached. Increasing the orifice nozzle cross-sections that are larger than normal with oil flow through the piston orifice being greater than 30% of the total oil flow of the engine oil pump can effectively inject heat into the engine oil, regardless of engine speed, by controlling the oil flow rate through the piston injectors to get promoted. If the oil spray nozzles are open during the cold start phase, the oil may heat up more quickly when sprayed on the underside of the pistons, which are the warmest region of the engine, thus providing significantly improved lubrication in the cold start phase.
In vielen Fällen wird bei einem Verbrennungsmotor Abwärme durch die Zylinderwände hindurch zu einer Wassermantelkühlung geführt, wobei die Wärme durch einen Wasserkühler eines Kühlmittelkreislaufs abgegeben wird. Gemäß einer vorteilhaften Weiterbildung kann die Wärmequelle zumindest einen Teil einer Ölleitung, insbesondere einer nicht isolierten Ölleitung, zwischen einem Brennraum einer Verbrennungskraftmaschine und einem Kühlmittelkanal umfassen. Insbesondere kann die Ölleitung zwischen einer Zylinderlaufbahn der Verbrennungskraftmaschine und einem Kühlmittelkanal im oberen Bereich der Zylinderlaufbahn angeordnet sein, wobei der Abstand zwischen dem unteren Ende der Ölleitung und dem oberen Ende der Zylinderlaufbahn, die mit der Dichtung des Zylinderkopfs abgedichtet ist, maximal 50 % des Kolbenhubes beträgt.In many cases, in an internal combustion engine, waste heat is conducted through the cylinder walls to water jacket cooling, the heat being dissipated by a water cooler of a coolant loop. According to an advantageous development, the heat source may comprise at least part of an oil line, in particular a non-insulated oil line, between a combustion chamber of an internal combustion engine and a coolant channel. In particular, the oil line between a cylinder bore of the internal combustion engine and a coolant channel can be arranged in the upper region of the cylinder bore, wherein the distance between the lower end of the oil line and the upper end of the cylinder bore, which is sealed with the seal of the cylinder head, a maximum of 50% of the piston stroke is.
Gemäß der obigen Weiterbildung kann zumindest ein Teil der Ölleitung, die zwischen Brennraum und Kühlmittelkanal angeordnet ist, einseitig von innen zur Seite des Kühlmittelkanals hin isoliert sein. Die Wärmeleitfähigkeit der einseitigen Isolierung kann deutlich geringer als die Wärmeleitfähigkeit der Strukturumgebung sein und bevorzugt mindestens kleiner als 1 W/(m K) betragen. Die Ölleitung kann insbesondere parallel zur Zylindermittelachse verlaufen.According to the above development, at least a part of the oil line, the is arranged between the combustion chamber and the coolant channel, be isolated on one side from the inside to the side of the coolant channel. The thermal conductivity of the one-sided insulation can be significantly lower than the thermal conductivity of the structural environment and preferably at least less than 1 W / (m K). The oil line can in particular run parallel to the cylinder center axis.
Werden Ölführungskanäle zwischen der Zylinderinnenwand und der Wassermantelkühlung angeordnet, so können diverse Vorteile erreicht werden:
- Sofern das Öl eine höhere Temperatur als das Kühlmittel hat, wird die Zylinderwandtemperatur erhöht, was den Verbrennungsprozess deutlich erhöht und Wärmeverluste durch die Zylinderwand reduziert.
- Das Öl wirkt als Isolation, was die Zylinderwandtemperatur zusätzlich erhöht.
- Das durchgeführte Schmieröl wird deutlich stärker erwärmt, was die Reibung verringert und den Kraftstoffverbrauch reduziert.
- If the oil has a higher temperature than the coolant, the cylinder wall temperature is increased, which significantly increases the combustion process and reduces heat losses through the cylinder wall.
- The oil acts as insulation, which additionally increases the cylinder wall temperature.
- The lubricating oil is heated much more, reducing friction and reducing fuel consumption.
In Kombination beispielsweise mit einer Kolbenspritzkühlung und einer Isolation der Ölgalerien und der Kurbelwelle und insbesondere durch Anordnung eines Wärmespeichers, kann beispielsweise auf einen aufwändigen Abgasölwärmetauscher verzichtet werden.In combination, for example, with a piston spray cooling and insulation of the oil galleries and the crankshaft and in particular by arranging a heat storage, can be dispensed with, for example, a complex exhaust gas heat exchanger.
Sofern die Ölkanäle parallel zur Mittelachse des Zylinders angeordnet sind, können sie relativ einfach gefertigt, z.B. nachträglich gebohrt werden und es müssen keine komplexen Gussformen für die Zylindermäntel für umlaufende, waagerechte Kanäle zur Mittelachse bereitgestellt werden, die das Risiko tragen, dass durch Rückstände von Formsand empfindliche Teile des Ventiltriebs wie die Lager oder Magnetventile von Nockenwellenversteller beschädigt werden können. Des weiteren kann durch einen parallelen Verlauf der Ölkanäle eine effektive Erwärmung erreicht werden, da das Öl vom kälteren, unteren Ende zum heißen, oberen Endbereich fließen und somit einen Temperaturgradienten durchlaufen und entsprechend heiß erwärmt werden kann. Durch eine halbseitige Isolation der Ölführungskanäle gegenüber der Wassermantelkühlung kann die Effizienz der vorgeschlagenen Maßnahmen deutlich erhöht werden.If the oil channels are arranged parallel to the central axis of the cylinder, they can be relatively easily manufactured, for example, drilled later and no complex casts for the cylinder jackets for circumferential, horizontal channels to the central axis are provided, which carry the risk that by residues of molding sand sensitive parts of the valve train as the bearings or solenoid valves of camshaft adjuster can be damaged. Furthermore, effective heating can be achieved by a parallel course of the oil passages, since the oil flows from the colder, lower end to the hot, upper end region and thus a temperature gradient go through and can be heated accordingly hot. By a half-side isolation of the oil guide channels compared to the water jacket cooling, the efficiency of the proposed measures can be significantly increased.
Gemäß einer weiteren vorteilhaften Weiterbildung kann ein Wärmespeicher für das Getriebeöl umfasst sein, der bevorzugt eine Kammer mit einem Phasenwechselmaterial aufweist, und der einen Kühlmittelwärmetauscher zur Erwärmung des Getriebeöls mit Kühlmittel in einer Einheit baulich integriert.According to a further advantageous development, a heat accumulator may be included for the transmission oil, which preferably has a chamber with a phase change material, and structurally integrates a coolant heat exchanger for heating the transmission oil with coolant in a unit.
Der Wärmetauscher benötigt einen großen Bauraum, wobei in einer Kaltstartphase heißes Fluid, welches in dem Tank gespeichert ist, mit Rücklaufluid gemischt wird, so dass die Gesamttemperatur innerhalb des Wärmespeichers herabgesetzt wird, da das heiße Öl von kaltem Schmieröl ersetzt wird. Aus diesem Grund sind in zahlreichen Wärmespeichern komplexe Ölführungskanäle vorgesehen, um die Bewegung des Motoröls zu steuern, wie beispielsweise in der
Es bietet sich vorteilhaft an, im Wärmespeicher mit einem bereits vorhandenen großen Volumen und einer entsprechend guten Isolierung einen Wärmetauscher für zumindest zwei Fluide zu integrieren. Als wärmeabgebendes Fluid könnte insbesondere Abgas und/oder Kühlmittel in Frage kommen, als wärmeaufnehmendes Fluid Motoröl und/oder Getriebeöl in Frage kommen. Bevorzugt ist ein Abgas-/Motoröl-Wärmetauscher und ein Kühlmittel-/Getriebeöltauscher denkbar, aber auch eine Kombination hiervon, z.B. ein Kühlmittel-/Getriebeöl-/Motoröl-Wärmetauscher oder ein Abgas-/Motoröl-/Getriebeöl-Wärmetauscher. Die zumindest zwei Fluide können vorteilhafterweise durch eine Kammer mit einem Phasenwechselmaterial miteinander gekoppelt sein. Ein Phasenwechselmaterial hilft, eine bevorzugte Kopplungstemperatur einzustellen und Wärme bzw. Kälte zu speichern. Durch die Aufnahme von Wärme aus dem wärmeabgebenden Fluid schmilzt das Phasenwechselmaterial und das wärmeabgebende Fluid wird gekühlt. Wenn die Temperatur sinkt, gefriert das Phasenwechselmaterial wieder durch Wärmeabgabe an das wärmeaufnehmende Fluid, so dass dieses erwärmt wird. Das Ergebnis ist eine Speicherung von Wärmeenergie, ein verzögerter Wärmeübergang und eine bevorzugte Wärmeübergangstemperatur.It is advantageous to integrate a heat exchanger for at least two fluids in the heat accumulator with an already existing large volume and a correspondingly good insulation. In particular exhaust gas and / or coolant could be considered as heat-emitting fluid, as heat-absorbing fluid engine oil and / or gear oil come into question. Preferably, an exhaust gas / engine oil heat exchanger and a coolant / gear oil exchanger is conceivable, but also a combination thereof, for example a coolant / gear oil / engine oil heat exchanger or an exhaust / engine oil / gear oil heat exchanger. The at least two fluids may advantageously be coupled together by a chamber having a phase change material. A phase change material helps to set a preferred coupling temperature and to store heat or cold. The absorption of heat from the heat-emitting fluid melts the phase change material and the heat-emitting fluid is cooled. As the temperature decreases, the phase change material again freezes by dissipating heat to the heat receiving fluid, so that this is heated. The result is a storage of heat energy, a delayed heat transfer and a preferred heat transfer temperature.
Auf das Getriebeschmiersystem mit dem Wärmespeicher aufsetzend kann in einer weiteren vorteilhaften Ausbildung der Erfindung der mit dem Wärmespeicher baulich integrierte Kühlmittelwärmetauscher als Plattenwärmetauscher ausgeführt sein, wobei jeweils die beiden äußeren ersten Platten Kühlmittel führen und zwischen der jeweils nächsten, zweiten Platte nach innen Getriebeöl geführt wird und zwischen der jeweils nächsten, dritten Platte nach innen ein Phasenwechselmaterial angeordnet ist, und zwischen der jeweils nächsten, vierten Platte nach innen Motoröl geführt wird, wobei des Weiteren bevorzugt zwischen einer jeweils nächsten, fünften Platte nach innen ein Phasenwechselmaterial angeordnet ist, und weiterhin zwischen jeweils einer nächsten, sechsten Platte nach innen Getriebeöl geführt wird, und weiterhin zwischen einer jeweils nächsten, siebten Platte nach innen Kühlmittel geführt wird, wobei sich die Reihenfolge weiterer Lagen wie vorstehend angegeben beliebig fortsetzen kann. Es ist alternativ denkbar, den Kühlmittelwärmetauscher als Rohrwärmetauscher auszuführen, wobei beispielsweise in einem inneren Rohr Kühlmittel, in einer konzentrisch hierzu geführten äußeren Hohlzylinderwandung Getriebeöl, in einer weiteren konzentrischen Hohlzylinderwandung ein Phasenwechselmaterial und in einer weiteren konzentrischen Hohlzylinderwandung Motoröl. Bei Bedarf kann der konzentrische Aufbau des Rohrwärmetauschers wiederholt werden oder der Rohrwärmespeicher mäanderförmig geführt werden.Placed on the gear lubrication system with the heat storage can be designed as a plate heat exchanger in a further advantageous embodiment of the invention with the heat storage integrated coolant heat exchanger, in each case the two outer first plates lead coolant and between the next, second plate is guided inward transmission oil and between the next, third plate inwardly a phase change material is arranged, and between the next, fourth plate inwardly engine oil is guided, further preferably between a respective next, fifth plate inside a phase change material is arranged, and further between each In the next, sixth plate in gearbox oil is guided, and further between a respective next, seventh plate is guided inwardly coolant, the sequence of further layers as mentioned above beliebi g can continue. It is alternatively conceivable to carry out the coolant heat exchanger as a tube heat exchanger, wherein for example in an inner tube coolant, in a concentrically guided outer hollow cylinder wall gear oil in another concentric Hohlzylinderwandung a phase change material and in another concentric Hohlzylinderwandung engine oil. If necessary, the concentric structure of the tube heat exchanger can be repeated or the tube heat storage can be performed meandering.
Durch eine Verwendung einer einfachen Plattenwärmetauschertechnologie, bei denen verschiedene Fluide wie Motoröl, Getriebeöl, Kühlmittel, Phasenwechselmaterial in verschiedenen Schichten geführt werden, wobei das heißeste Fluid durch Phasenwechselmaterial flankiert ist, und dieses wiederum von Getriebeöl flankiert ist und dieses wiederum von Kühlfluid flankiert ist und der Fluss all dieser Fluide derart gesteuert wird, dass das Getriebeöl nicht mehr fließt, wenn eine Motoröltemperatur unter einem vorbestimmten Motorölgrenzwert fällt und das Kühlmittelfluid nicht mehr fließt, wenn eine Kühltemperatur unter einem vorbestimmten Kühltemperaturgrenzwert fällt, kann eine verbesserte Aufheizung der verschiedenen Schmieröle und geringere Abgasemissionen und Kraftstoffverbrauch erreicht werden.By using a simple plate heat exchanger technology, in which various fluids such as engine oil, gear oil, coolant, phase change material are guided in different layers, wherein the hottest fluid is flanked by phase change material, which in turn is flanked by transmission oil and this in turn is flanked by cooling fluid and the Flow of all these fluids is controlled so that the transmission oil stops flowing when an engine oil temperature falls below a predetermined engine oil limit and the coolant fluid stops flowing when a cooling temperature falls below a predetermined cooling temperature limit, improved heating of the various lubricating oils and lower exhaust emissions and Fuel consumption can be achieved.
Auf das Getriebeschmiersystem mit dem Wärmespeicher aufsetzend können in einer vorteilhaften Weiterbildung ein oder mehrere Ventile, insbesondere ein Kühlmittelventil und/oder ein Getriebeölventil zur Steuerung des Fluidstroms durch die verschiedenen Kanäle des Wärmespeichers vorgesehen sein, so dass eine Kühlmittelzufuhr unterbrochen wird, wenn die Kühlmitteltemperatur kleiner ist als eine erste Kühlmittelgrenztemperatur, insbesondere 90°C und wenn die Getriebeöltemperatur höher ist als die Kühlmitteltemperatur, und dass die Getriebeölzufuhr unterbrochen wird, wenn einer Motoröltemperatur unter einer ersten Motorölgrenztemperatur, insbesondere kleiner 120°C, liegt.One or more valves, in particular a coolant valve and / or a transmission oil valve for controlling the fluid flow through the various channels of the heat accumulator may be provided on the transmission lubrication system with the heat accumulator so that a coolant supply is interrupted when the coolant temperature is lower as a first coolant limit temperature, in particular 90 ° C and when the transmission oil temperature is higher than the coolant temperature, and that the transmission oil supply is interrupted when an engine oil temperature is below a first engine oil limit temperature, in particular less than 120 ° C.
Auf das Getriebeschmiersystem mit dem Wärmespeicher aufsetzend kann in einer weiteren vorteilhaften Weiterbildung die Getriebeölzufuhr zum Wärmespeicher geöffnet werden, sobald die Motoröltemperatur eine zweite Wärmetauscher-Motorölgrenztemperatur, insbesondere grösser als 120°C, erreicht wird. Des Weiteren kann die Getriebeölzufuhr zum Wärmespeicher geschlossen werden, sobald die Motoröltemperatur eine untere dritte Wärmetauscher-Motorölgrenztemperatur, insbesondere kleiner als 90°C, erreicht hat. Daneben kann bevorzugt eine Kühlwasserzufuhr zum integrierten Wärmespeicher geöffnet werden, sobald die Getriebeöltemperatur niedriger als die Kühlmitteltemperatur ist und die Kühlwasserzufuhr zum integrierten Wärmespeicher kann geschlossen werden, sobald die Getriebeöltemperatur grösser ist als die Kühlmitteltemperatur.In a further advantageous development, the transmission oil supply to the heat accumulator can be opened to the transmission lubrication system with the heat accumulator as soon as the engine oil temperature reaches a second heat exchanger engine oil limit temperature, in particular greater than 120 ° C. Furthermore, the transmission oil supply to the heat accumulator can be closed as soon as the engine oil temperature has reached a lower third heat exchanger engine oil limit temperature, in particular less than 90 ° C. In addition, preferably a cooling water supply to the integrated heat accumulator can be opened as soon as the transmission oil temperature is lower than the coolant temperature and the cooling water supply to the integrated heat accumulator can be closed as soon as the transmission oil temperature is greater than the coolant temperature.
Abgasölwärmetauscher sind relativ kostspielig und komplex, da sie hohe Temperaturen und hohe Drücke und der Gefahr von Leckagen bzw. von Feuerentzündung entgegenwirken müssen. Es müssen aufwendige Maßnahmen zur Verhinderung von Korrosionen und Verschmutzung durch die Abgase ergriffen und eine Ansammlung von Wasser, das gefrieren kann, muss verhindert werden. Durch eine einteilige Ausführung eines Abgasölwärmetauschers von Motoröl und Getriebeöl in einer einzigen Baueinheit, wobei eine Abgasbypassleitung mit Abgasbypassventil angeordnet wird, so dass eine Durchleitung von Abgasen durch den Abgasölwärmetauscher schaltbar ist, sofern die Motoröltemperatur oder die Getriebeöltemperatur ein Maximum erreicht, kann eine optimale Steuerung der Aufheizung insbesondere bei hohen Lasten und der Kaltstartphase erreicht werden. Hierdurch kann wiederum eine verbesserte Schmierung erreicht werden.Exhaust gas heat exchangers are relatively expensive and complex because they have high temperatures and high pressures and the risk of leaks or fire have to counteract. It must take costly measures to prevent corrosion and pollution by the exhaust gases and an accumulation of water that can freeze must be prevented. By a one-piece design of an exhaust gas heat exchanger of engine oil and transmission oil in a single unit, an exhaust gas bypass line is arranged with exhaust bypass valve, so that a passage of exhaust gases through the exhaust oil heat exchanger is switchable, provided that the engine oil temperature or the transmission oil temperature reaches a maximum, optimal control of Heating can be achieved especially at high loads and the cold start phase. This in turn can be achieved an improved lubrication.
Gemäß einer vorteilhaften Weiterentwicklung der Erfindung kann ein Abgas-/Ölwärmetauscher für Motoröl und Getriebeöl einteilig ausgeführt sein. Dabei kann es weiterhin vorteilhaft sein, wenn der Wärmetauscher im Gegenstromprinzip durchströmt wird, insbesondere Motoröl und Getriebeöl im Gegenstrom den Wärmetauscher durchströmen, und bevorzugt der Bereich des Getriebeöl-abgaswärmetauschers abgasseitig stromabwärts vom Bereich des Motorölabgaswärmetauschers angeordnet ist. Der Abgas-/Ölwärmetauscher kann abgasseitig mit einer Abgasbypassleitung und zumindest einem Abgasbypassventil versehen sein, so dass ein Abgasstrom durch den Bereich des Motorölabgaswärmetauschers bei Überschreiten einer vordefinierbaren ersten Wärmetauscher-Motorölgrenztemperatur, insbesondere von 120°C, unterbrochen wird. Der Abgasstrom kann durch den Bereich des Getriebeöl-Abgaswärmetauschers bei Überschreiten einer vordefinierbaren ersten Wärmetauscher-Getriebeölgrenztemperatur, insbesondere von 90°C, unterbrochen werden.According to an advantageous development of the invention, an exhaust / oil heat exchanger for engine oil and transmission oil can be made in one piece. It may also be advantageous if the heat exchanger is flowed through in the countercurrent principle, in particular engine oil and gear oil flow through the heat exchanger in countercurrent, and preferably the region of the transmission oil-exhaust heat exchanger downstream of the range of engine oil exhaust gas heat exchanger is arranged. The exhaust gas / oil heat exchanger may be provided on the exhaust side with an exhaust gas bypass line and at least one exhaust gas bypass valve, so that an exhaust gas flow through the region of the engine oil exhaust gas heat exchanger at a predefinable first heat exchanger engine oil limit temperature, in particular of 120 ° C, is interrupted. The exhaust gas flow can be interrupted by the region of the transmission oil-exhaust heat exchanger when a predefinable first heat exchanger transmission oil limit temperature, in particular 90 ° C., is exceeded.
Durch die Integration von Getriebe- und Motorölwärmetauscher in einer Baueinheit mit einem Gehäuse mit einer schaltbaren Abgasbypassleitung kann eine Erwärmung/Kühlung des Öls durch Beeinflussung des Abgasstroms gesteuert werden. So kann der Abgasstrom über die Bypassleitung geleitet werden, wenn das Motoröl oder das Getriebeöl eine Grenztemperatur erreicht hat.The integration of transmission and engine oil heat exchanger in a unit with a housing with a switchable Abgasbypassleitung heating / cooling of the oil can be controlled by influencing the exhaust gas flow. Thus, the exhaust stream can be passed through the bypass line, if the engine oil or the transmission oil has reached a limit temperature.
Gewöhnliches Kühlmittel hat den Nachteil, dass bei maximalen Temperaturen in der Verbrennungskammer die Gefahr besteht, dass das Kühlmittel zu kochen beginnt, so dass die Brennraumwandtemperaturen begrenzt werden müssen, um zu verhindern, dass einzelne Bauteile thermisch überlastet werden und um ein lokales Überhitzen oder einen Schaden des Motors zu verhindern.Common coolant has the disadvantage that at maximum temperatures in the combustion chamber there is a risk of the coolant starting to boil, so the combustion chamber wall temperatures must be limited to prevent individual components from being thermally overloaded and from local overheating or damage to prevent the engine.
Gemäß einer weiteren vorteilhaften Ausbildung der Erfindung kann das Kühlmittel des Kühlmittelkreislaufs ein Phasenwechselmaterial umfassen, dass eine Schmelztemperatur über 0°C und einer Siedetemperatur von mindestens 120°C aufweist, bei dem die Dichte mit steigender Temperatur, insbesondere beim Phasenübergang von fest zu flüssig, steigt. Der mit diesem Phasenwechselmaterial gefüllte Kühlmittelkreislauf kann in der zu kühlenden Verbrennungskraftmaschine derart integriert sein, dass keine zu anderen Bauteile führende Verbindungsleitungen vorhanden sind. Dabei kann ein erster Kühlmittelkreislauf mit dem Phasenwechselmaterial von einem zweiten Kühlmittelkreis umgeben sein und durch diesen gekühlt werden, wobei der zweite Kühlmittelkreis mit Kühlmittel mit einer Schmelztemperatur von zumindest unterhalb -30°C gefüllt ist, und der zweite Kühlmittelkreislauf kann außerhalb der Verbrennungskraftmaschine angeordnete Bauteile, insbesondere einen Kühler, aufweisen.According to a further advantageous embodiment of the invention, the coolant of the coolant circuit may comprise a phase change material having a melting temperature above 0 ° C and a boiling temperature of at least 120 ° C, in which the density increases with increasing temperature, in particular during the phase transition from solid to liquid , The coolant circuit filled with this phase change material can be integrated in the internal combustion engine to be cooled in such a way that no connecting lines leading to other components are present. In this case, a first coolant circuit with the phase change material can be surrounded by a second coolant circuit and cooled by it, wherein the second coolant circuit is filled with coolant having a melting temperature of at least below -30 ° C, and the second coolant circuit can be arranged outside the internal combustion engine components, in particular a cooler.
Ein Phasenwechselmaterial kann eine höhere Siedetemperatur als Wasser bereitstellen, so dass der Einsatz eines solches Materials im Kühlmittelsystem eine höhere Spitzentemperatur in dem Verbrennungsraum ermöglicht. Allerdings weist Phasenwechselmaterial eine niedrige spezifische Wärmekapazität und eine schlechtere Wärmeleitfähigkeit oder beides auf, so dass große Kühler, Pumpen und Verbindungsleitungen im Kühlkreislauf benötigt werden. Des Weiteren kann kein Phasenwechselmaterial verwendet werden, das bei Umgebungstemperaturen zwischen -40°C und 0°C einen festen Aggregatszustand annimmt, da im festen Zustand bei hohen Lasten keine Abwärme zum Kühler transportiert werden kann. Hierzu ist zunächst notwendig, dass das Phasenwechselmaterial schmilzt, was schwer zu erreichen ist, insbesondere in den Teilen des Kühlsystems, die sich außerhalb der Verbrennungskraftmaschine, beispielsweise im Kühler, befinden. Daher wird nach vorgenannter Ausführungsform vorgeschlagen, dass ein Phasenwechselmaterial mit einer Schmelztemperatur zwischen 40°C und 120°C verwendet wird, was nur innerhalb eines inneren Kühlkreislaufs eingesetzt wird, so dass das Phasenwechselmaterial in einer Kaltstartphase sehr schnell an seinen Schmelzpunkt gelangt und flüssig wird und während der Kaltstartphase bereits Wärme abtransportieren kann. Der innere Kühlkreislauf ist mit einem äußeren Kühlkreislauf durch einen Wärmetauscher verbunden, wobei in dem äußeren Kühlkreislauf beispielsweise konventionelles Kühlmittel mit einer Schmelztemperatur von unter -30°C eingesetzt werden kann. Hierdurch kann der Vorteil einer erhöhten Innenraumtemperatur erreicht und trotzdem eine stabile und effiziente Kühlung bei einem Schmiersystem mit verbesserter Isolation eingesetzt werden.A phase change material may provide a higher boiling temperature than water so that the use of such material in the coolant system allows a higher peak temperature in the combustion chamber. However, phase change material has a low specific heat capacity and a lower thermal conductivity or both, so that large radiators, pumps and connecting lines are required in the cooling circuit. Furthermore, no phase change material can be used, which assumes a fixed state of aggregation at ambient temperatures between -40 ° C and 0 ° C, since in the solid state at high loads no waste heat can be transported to the radiator. For this purpose, it is first necessary that the phase change material melts, which is difficult to achieve, especially in the parts of the cooling system, which are outside the internal combustion engine, for example in the radiator. Therefore, it is proposed in the aforementioned embodiment that a phase change material having a melting temperature between 40 ° C and 120 ° C is used, which is used only within an inner cooling circuit, so that the phase change material in a cold start phase very quickly reaches its melting point and becomes liquid and During the cold start phase can already dissipate heat. The inner cooling circuit is connected to an outer cooling circuit through a heat exchanger, wherein in the outer cooling circuit, for example, conventional coolant having a melting temperature of below -30 ° C can be used. As a result, the advantage of an increased interior temperature can be achieved and still a stable and efficient cooling in a lubrication system with improved insulation can be used.
Ein Kühlsystem mit getrennten Kühlkreisläufen zur verbesserten Erwärmung, wobei das Kühlmittel durch einen Zylinderkopf und durch einen Zylinderblock separat verlaufen, ist beispielsweise aus dem
Gemäß einer vorteilhaften Weiterbildung können ein Zylinderkopfkühlmittelkanal und ein Zylinderblockkühlmittelkanal des Kühlkreislaufs einer Verbrennungskraftmaschine baulich getrennt ausgeführt sein, um eine Beschleunigung der Kühlmittelaufheizung zu erreichen. Dabei strömt während einer Aufwärmphase unterhalb einer ersten Kühlmittelgrenztemperatur, insbesondere unter 90°C, ein Kühlmittel zuerst durch den Zylinderkopf zur Aufheizung und von dort durch einen Zylinder-/Motorblock, wo das warme Kühlmittel eine Zylinderwand aufheizt, um Wandwärmeverluste zu reduzieren, und dort wird es einer Kühlmittelpumpe zugeführt. Bei Erreichen der ersten Kühlmittelgrenztemperatur kann im Zylinderkopf ein erstes Kühlmittelstromrichtungsthermostat geöffnet werden und zumindest ein Teilvolumenstrom des Kühlmittels kann an einen Kühler geleitet werden. Bei Erreichen einer zweiten Kühlmittelgrenztemperatur, insbesondere über 100°C, kann ein zweites Kühlmittelstromrichtungsthermostat, insbesondere ein 3-Wegethermostat am bisherigen Ausgang des Zylinder-/Motorblockes eine Verbindung zum Eingang der Kühlmittelpumpe schließen und eine Verbindung zum Ausgang der Kühlmittelpumpe herstellen, so dass das Kühlmittel im Zylinder-/Motorblock in entgegengesetzter Richtung wie das Kühlmittel im Zylinderkopf strömt, und ein vereinigter Kühlmittelstrom von Zylinderkopf und Zylinder-/Motorblock durch den Kühler geleitet wird.According to an advantageous development, a cylinder-head coolant channel and a cylinder block coolant channel of the cooling circuit of an internal combustion engine may be structurally separated in order to achieve an acceleration of the coolant heating. In this case, during a warm-up phase below a first coolant limit temperature, in particular below 90 ° C., a coolant first flows through the cylinder head for heating and from there through a cylinder / engine block, where the warm coolant heats a cylinder wall to reduce wall heat losses, and there it fed to a coolant pump. When the first coolant limit temperature is reached, a first coolant flow direction thermostat can be opened in the cylinder head, and at least one partial volume flow of the coolant can be routed to a radiator. Upon reaching a second coolant temperature limit, in particular above 100 ° C, a second Kühlmittelstromrichtungsthermostat, in particular a 3-way thermostat at the previous output of the cylinder / engine block connect to the input of the coolant pump and connect to the output of the coolant pump, so that the coolant in the cylinder / engine block in the opposite direction as the coolant flows in the cylinder head, and a combined coolant flow from the cylinder head and cylinder / engine block is passed through the radiator.
Demzufolge wird in der vorgeschlagenen Ausführungsform das Kühlmittel zunächst durch den Zylinderkopf geführt, wobei am Ende des Zylinderkopfs das Kühlmittel zurück in den Motorblock geführt wird, so dass der Zylinderblock durch das bereits im Zylinderkopf erwärmte Kühlmittel ebenfalls erwärmt wird und somit eine Verbesserung des Verbrennungsprozesses stattfindet, da der Zylinderkopf sich typischerweise wesentlich schneller erwärmt und wärmer ist als der Zylinderblock - auch aufgrund dessen, dass die Wassermantelkühlung im Zylinderkopf wesentlich weniger Raum einnimmt und heiße Abgase ebenfalls durch den Zylinderkopf geführt werden - so dass die größte Abwärme dort entsteht. In einem weiteren Schritt kann das Kühlmittel sich schneller erwärmen. Wenn das Kühlmittel warm genug ist, kann ein Kühlmittelthermostat die Kühlmittelflussrichtung derart verändern, dass Kühlmittel durch einen Wasserkühler fließt und wenn der Motorblock warm genug wird, kann das Kühlmittel parallel durch den Motorblock und den Zylinderkopf fließen, so dass eine maximale Kühlung durch die Wasserkühler erfolgen kann. Somit wird eine ausreichende Kühlung und eine schnelle Erwärmung bzw. eine gleichmäßige Erwärmung des Motorblocks erreicht, so dass das Schmieröl schneller erwärmt wird.Accordingly, in the proposed embodiment, the coolant is first passed through the cylinder head, wherein at the end of the cylinder head, the coolant is fed back into the engine block, so that the cylinder block is also heated by the already heated in the cylinder head coolant and thus takes place an improvement of the combustion process, since the cylinder head typically heats up much faster and is warmer than the cylinder block - also due to the fact that the water jacket cooling in the cylinder head occupies much less space and hot exhaust gases are also passed through the cylinder head - so that the largest heat there arises. In a further step, the coolant can heat up faster. If the coolant is warm enough, a coolant thermostat may change the coolant flow direction such that coolant flows through a water cooler, and when the engine block becomes warm enough, the coolant may flow in parallel through the engine block and cylinder head for maximum cooling by the water coolers can. Thus, a sufficient cooling and a rapid heating or a uniform heating of the engine block is achieved, so that the lubricating oil is heated faster.
In einer weiteren Ausführungsform des Schmiersystems wird vorgeschlagen, dass der Kolben einer Verbrennungskraftmaschine auf der Innenseite zumindest eines Kolbenschaftes durch eine Isolierung isoliert ist, wobei die Wärmeleitfähigkeit der Isolierung 5% oder weniger als die Wärmeleitfähigkeit des Kolbenschaftes ist und bevorzugt mindestens kleiner als 1 W/(m K) ist, wobei bevorzugt die Innenseite des Kolbenbodens nicht isoliert ist. Somit wird eine Isolierung eines zu schmierenden oszillierenden Bauteils vorgeschlagen, so dass der in der Kaltstartphase einer kalten Zylinderseitenwand zuweisende Kolbenschaft isoliert, allerdings der sich schnell erwärmende Kolbenboden nicht isoliert ist. Somit kann ein zusätzlicher Wärmeeintrag in das Öl bereitgestellt und eine Isolierung zur Verhinderung einer Abkühlung gegenüber dem kalten Zylinderblock erreicht werden. Insbesondere bei einer Kolbenspritzkühlung, bei der eine hohe Menge von Öl mit dem Kolbenboden in Berührung kommt, ist ein derartig isolierter Kolben zur schnellen Erwärmung vorteilhaft.In a further embodiment of the lubricating system, it is proposed that the piston of an internal combustion engine is insulated on the inside of at least one piston skirt by insulation, the thermal conductivity of the insulation being 5% or less than the thermal conductivity of the piston skirt, and preferably at least less than 1 W / (FIG. m K), wherein preferably the inside of the piston crown is not isolated. Thus, it is proposed to isolate an oscillating component to be lubricated, so that the piston stem assigned in the cold start phase of a cold cylinder sidewall is isolated, but the rapidly heating piston crown is not insulated. Thus, additional heat input into the oil can be provided and isolation to prevent cooling from the cold cylinder block can be achieved. In particular, in a piston injection cooling, in which a large amount of oil comes into contact with the piston head, such an insulated piston for rapid heating is advantageous.
Ist ein Wärmespeicher vorgesehen, um Öl in einem gewünschten Temperaturbereich zwischen zu speichern, so kann zur Aufheizung oder Kühlung vorteilhafterweise ein Abgaswärmetauscher vorgesehen sein, der zumindest dreivolumig bzw. dreikanalig oder mit drei Kammern ausgeführt ist, und der baulich in dem Wärmespeicher (14) integriert sein kann. Der Abgaswärmetauscher kann ein erstes Volumen umfassen, dass von zumindest einem ersten Abgasteilstrom durchströmbar ist, wobei das erste Volumen durch eine erste Trennwand begrenzt oder von einer ersten Trennwand umgeben ist, wobei auf zumindest einer der Seiten der ersten Trennwand, die nicht mit dem Abgasteilstrom in Verbindung steht, ein Phasenwechselmaterial in einem zweiten Volumen angeordnet sein kann, das von einer zweiten Trennwand begrenzt oder von einer zweiten Trennwand umgeben ist, wobei auf zumindest einer der Seiten der zweiten Trennwand, die nicht mit dem Phasenwechselmaterial in Verbindung steht, Schmieröl durch ein drittes Volumen strömbar ist. Eine Anordnungsreihenfolge von ersten, zweiten und dritten Volumen bzw. Kanälen in umgekehrter Reihenfolge, (d.h. z.B. die Reihenfolge: erstes Volumen, zweites Volumen, drittes Volumen, zweites Volumen, erstes Volumen, zweites Volumen, drittes Volumen etc.) kann zumindest einmal, insbesondere wiederholt fortgesetzt werden. Das Phasenwechselmaterial kann zumindest ein Zuckeralkohol wie Erythrit, Threit oder ein Paraffin, oder ein Salz wie ein Hydrat, Nitrat, Hydroxyd oder ein Chlorid wie Magnesiumchloridhexahydrat oder Magnesiumnitrathexahydrat umfassen, dessen latente Schmelzwärme größer ist als die Wärme, die der Wärmespeicher aufgrund der Temperaturdifferenz einer ersten unteren Ölgrenztemperatur von 50°C und einer ersten oberen Ölgrenztemperatur von 90°C speichern kann. Vorteilhafterweise kann die Schmelztemperatur des Phasenwechselmaterials niedriger sein als die erste obere Ölgrenztemperatur, und bevorzugt, sofern die Schmelztemperatur des Phasenwechselmaterials größer 100°C ist, das Phasenwechselmaterial Erythrit mit einer Schmelztemperatur von ca. 120°C ist, so dass im Kaltstart eine höchstmögliche Temperatur im Wärmespeicher in kurzer Zeit erreichbar ist. Durch einen derartigen, im Wärmespeicher integrierten Dreikammer-Wärmetauscher mit einer indirekten Kopplung von Öl und Abgas über ein Phasenwechselmaterial wird ein direkter Wärmeübergang von sehr heißem Abgas zum Öl umgangen, da das Phasenwechselmaterial als Wärmepuffer dient. Hierdurch wird eine lokale Überhitzung des Öls durch das Phasenwechselmaterial (PCM - phase change material) als Dämpfungsschicht verhindert. Des Weiteren wird eine Erhöhung der Isolierung und Abdichtung geschaffen, so dass ein direkter Kontakt von Öl und Abgas verhindert wird. Das PCM-Material, beispielsweise Magnesiumchloridhexahydrat (MgCl2 x 6 H2O) ist unbrennbar und reduziert somit eine Entflammungsgefahr. Der Abgaswärmetauscher kann konstruktiv als Plattenwärmetauscher einfach konstruiert und in dem Wärmespeicher integriert werden. Die Isolation des Wärmespeichers isoliert den Wärmetauscher, so dass dieser im Kaltstart sehr schnell eine effektive Wärmeübertragung gewährleisten kann, ohne dass das Abgas die Wandung des Wärmetauschers selbst aufheizen muss.If a heat storage is provided to store oil in a desired temperature range between, may advantageously be provided for heating or cooling an exhaust gas heat exchanger, which is at least three-volume or three-channel or with three chambers, and the structurally integrated in the heat storage (14) can be. The exhaust gas heat exchanger may comprise a first volume that can be flowed through by at least a first partial exhaust gas flow, wherein the first volume through a first partition wall is limited or surrounded by a first partition, wherein on at least one of the sides of the first partition, which is not in communication with the exhaust partial flow, a phase change material may be arranged in a second volume bounded by a second partition or surrounded by a second partition is, wherein on at least one of the sides of the second partition, which is not in communication with the phase change material, lubricating oil is flowable through a third volume. An arrangement order of first, second and third volumes or channels in reverse order (ie, the order: first volume, second volume, third volume, second volume, first volume, second volume, third volume, etc.) may be repeated at least once, in particular to be continued. The phase change material may comprise at least one sugar alcohol such as erythritol, threit or a paraffin, or a salt such as a hydrate, nitrate, hydroxide or a chloride such as magnesium chloride hexahydrate or magnesium nitrate hexahydrate, whose latent heat of fusion is greater than the heat which the heat storage due to the temperature difference of a first lower oil limit temperature of 50 ° C and a first upper oil limit temperature of 90 ° C can save. Advantageously, the melting temperature of the phase change material may be lower than the first upper oil limit temperature, and preferably, if the melting temperature of the phase change material is greater than 100 ° C, the phase change material erythritol with a melting temperature of about 120 ° C, so that in cold start a highest possible temperature in Heat storage can be reached in a short time. By such, integrated in the heat accumulator three-chamber heat exchanger with an indirect coupling of oil and exhaust gas via a phase change material direct heat transfer from very hot exhaust gas to the oil is bypassed because the phase change material serves as a heat buffer. As a result, a local overheating of the oil by the phase change material (PCM - phase change material) is prevented as a damping layer. Furthermore, an increase of the insulation and sealing is provided, so that a direct contact of oil and exhaust gas is prevented. The PCM material, for example magnesium chloride hexahydrate (MgCl2 x 6 H2O) is incombustible and thus reduces the risk of ignition. The exhaust gas heat exchanger can be constructively designed as a simple plate heat exchanger and integrated in the heat storage. The insulation of the heat accumulator insulates the heat exchanger so that it can ensure effective heat transfer very quickly during a cold start without the exhaust gas having to heat up the wall of the heat exchanger itself.
Der vorgenannte Wärmetauscher kann bevorzugt als Rohrwärmetauscher ausgeführt sein, mit zumindest drei ineinander geschobenen Röhren ausgestaltet sein. So können die Rohre doppelwandig ausgeführt sein und sich ein Phasenwechselmaterial im Zwischenraum zwischen dem inneren Rohr und dem äußeren Rohr angeordnet sein. Hierdurch lässt sich eine Trennung, kompakte Bauweise und einfache Herstellung leicht erreichen. Falls eine Leckage auftreten würde, wäre gesichert, dass keine Flüssigkeit in den Wärmespeicher austreten könnte, da eine Leckage höchstens bis zu einer PCM-Kammer vordringen könnte.The aforementioned heat exchanger can preferably be designed as a tube heat exchanger, be configured with at least three telescoped tubes. Thus, the tubes may be double-walled and be arranged a phase change material in the space between the inner tube and the outer tube. As a result, a separation, compact design and ease of manufacture can be easily achieved. If leakage did occur, it would be ensured that no liquid could escape into the heat accumulator since leakage could at most reach up to a PCM chamber.
In einer vorteilhaften Weiterbildung der vorgenannten Ausführung mit Wärmespeicher mit integriertem Abgas/Ölwärmetauscher kann zumindest eine der Abgasanschlussleitungen des im Wärmespeicher integrierten Abgaswärmetauschers durch eine Keramikleitung von dem Wärmespeicher isoliert sein. Hierdurch wird die Isolationswirkung weiterhin verbessert und dadurch Wärmeverluste reduziert.In an advantageous development of the aforementioned embodiment with heat accumulator with integrated exhaust gas / oil heat exchanger, at least one of the exhaust gas connection lines of the exhaust gas heat exchanger integrated in the heat accumulator can be insulated from the heat accumulator by a ceramic line. As a result, the insulation effect is further improved, thereby reducing heat losses.
In einer vorteilhaften Weiterbildung kann eine Ölzulaufleitung eines Zylinderkopfes und / oder eines Turboladers stromabwärts vor der Wärmequelle mit einer Zylinderblock-Ölgalerie verbunden sein. Weiterhin kann in der Ölzulaufleitung des Zylinderkopfes und / oder des Turboladers ein Kühlmittelwärmetauscher angeordnet sein, der von Kühlmittel eines Kühlmittelkreislaufs durchströmbar ist. Durch die Führung der Zylinderkopf- und Turbolader-Ölzulaufleitung stromabwärts vor der Wärmequelle kann die Öltemperatur im Zylinderkopf und Turbo auf einem niedrigen Niveau gehalten werden, da das Öl eine tiefstmögliche Temperatur vor einer Aufwärmung durch die Wärmequelle aufweist. Hierdurch reduziert sich im Zylinderkopf eine Reibung im Ventiltrieb, da eine Mischreibung vermieden wird, insbesondere bei den niedrigen Drehzahlen im Ventiltrieb. Im Turbolader wird die Gefahr von Ölleckagen in der Ansaugseite reduziert, so dass eine Neigung zur Glühzündung durch Ölpartikel verringert wird, insbesondere bei Benzinmotoren mit Direkteinspritzung.In an advantageous development, an oil feed line of a cylinder head and / or a turbocharger downstream of the heat source may be connected to a cylinder block oil gallery. Furthermore, a coolant heat exchanger can be arranged in the oil supply line of the cylinder head and / or the turbocharger, which can be flowed through by coolant of a coolant circuit. By guiding the cylinder head and turbocharger oil supply line downstream of the heat source, the oil temperature in the cylinder head and turbo be kept at a low level, since the oil has a lowest possible temperature before heating by the heat source. This reduces friction in the valve train in the cylinder head, since mixed friction is avoided, especially at the low speeds in the valve train. In the turbocharger, the risk of oil leakage in the intake side is reduced, so that a tendency to ignite by oil particles is reduced, especially in gasoline engines with direct injection.
In einer weiteren vorteilhaften Ausgestaltung kann ein Volumenstrom der Ölpumpe regelbar sein, wobei eine Förderleistung der Ölpumpe erhöht wird, um einen erhöhten Pumpvolumenstrom innerhalb eines Wärmespeichers zu erreichen, sobald eine Ölaustrittstemperatur des Wärmespeichers unterhalb einer vordefinierbaren Ölaustrittsgrenztemperatur von maximal 90° C liegt und eine Öleintrittstemperatur des Wärmespeichers oberhalb einer vordefinierbaren Öleintrittsgrenztemperatur von mindestens 90°C liegt. Es hat sich herausgestellt, dass im Falle einer vorgenannten relativ hohen Öltemperatur im Ölkreislauf kaum zu einer Verdrängung des kalten Öls durch das einströmende heiße Öl kommt, da das heiße Öl kurzschlussartig durch das kalte Öl hindurchströmt. Daher ist es im Falle eines heißen Öls insbesondere in einer Heißphase vorteilhaft, die Öl-Strömungsgeschwindigkeit durch Erhöhung der Pumpenförderleistung zu erhöhen, um eine höhere Strömungsgeschwindigkeit des heißen Öls und damit eine turbulente Strömung zu erzeugen, wobei das kalte Öl mit seiner laminaren Strömung besser verdrängt wird.In a further advantageous embodiment, a flow rate of the oil pump can be regulated, wherein a flow rate of the oil pump is increased in order to achieve an increased pumping volume flow within a heat accumulator as soon as an oil outlet temperature of the heat accumulator is below a predefinable oil leakage temperature of maximum 90 ° C and an oil inlet temperature of the Heat accumulator is above a predefinable oil inlet temperature limit of at least 90 ° C. It has been found that in the case of an aforementioned relatively high oil temperature in the oil circuit hardly comes to a displacement of the cold oil by the incoming hot oil, since the hot oil flows through short circuit through the cold oil. Therefore, in the case of a hot oil, especially in a hot phase, it is advantageous to increase the oil flow rate by increasing the pump delivery rate to produce a higher flow rate of the hot oil and thus turbulent flow, better displacing the cold oil with its laminar flow becomes.
Weitere Vorteile ergeben sich aus der vorliegenden Zeichnungsbeschreibung. In der Zeichnung sind Ausführungsbeispiele der Erfindung dargestellt. Die Zeichnung, die Beschreibung und die Ansprüche enthalten zahlreiche Merkmale in Kombination. Der Fachmann wird die Merkmale zweckmäßigerweise auch einzeln betrachten und zu sinnvollen weiteren Kombinationen zusammenfassen.Further advantages result from the present description of the drawing. In the drawings, embodiments of the invention are shown. The drawing, the description and the claims contain numerous features in combination. The person skilled in the art expediently also the features individually consider and summarize to meaningful further combinations.
Es zeigen:
- Fig. 1
- ein erstes Ausführungsbeispiel eines erfindungsgemäßen Schmiersystems;
- Fig. 2
- ein zweites Ausführungsbeispiel eines erfindungsgemäßen Schmiersystems;
- Fig. 3
- ein Ausführungsbeispiel eines Wärmespeichers für ein erfindungsgemäßes Schmiersystem;
- Fig. 4
- ein weiteres Ausführungsbeispiel eines erfindungsgemäßen Schmiersystems;
- Fig. 5
- ein Ausführungsbeispiel einer Ölschmierleitungsführung im Zylinderkopf einer Verbrennungskraftmaschine für ein erfindungsgemäßes Ölschmiersystem;
- Fig. 6
- ein weiteres Ausführungsbeispiel eines erfindungsgemäßen Schmiersystems;
- Fig. 7
- Ausführungsbeispiele eines Kühlmittelkreislaufs zum Einsatz in einen erfindungsgemäßen Schmiersystem;
- Fig. 8
- Ausführungsbeispiele eines teilisolierten Kolbens einer Verbrennungskraftmaschine zur Verwendung in einem erfindungsgemäßen Schmiersystem;
- Fig. 9
- ein weiteres Ausführungsbeispiel eines erfindungsgemäßen Schmiersystems.
- Fig. 1
- a first embodiment of a lubrication system according to the invention;
- Fig. 2
- a second embodiment of a lubrication system according to the invention;
- Fig. 3
- an embodiment of a heat accumulator for a lubricating system according to the invention;
- Fig. 4
- a further embodiment of a lubricating system according to the invention;
- Fig. 5
- an embodiment of an oil lubrication line guide in the cylinder head of an internal combustion engine for an inventive oil lubrication system;
- Fig. 6
- a further embodiment of a lubricating system according to the invention;
- Fig. 7
- Embodiments of a coolant circuit for use in a lubrication system according to the invention;
- Fig. 8
- Embodiments of a partially insulated piston of an internal combustion engine for use in a lubrication system according to the invention;
- Fig. 9
- a further embodiment of a lubrication system according to the invention.
In den Figuren sind gleiche oder gleichartige Komponenten mit gleichen Bezugszeichen beziffert.In the figures, identical or similar components with the same reference numerals quantified.
In
Aufbauend auf dem in
Um einen Wärmespeicher beispielsweise, wie den in
In der
In der
In den
Die
In der
In der
Des Weiteren zeigt
Die
Es wird darauf hingewiesen, dass die isolierten Ölleitungen in einem Ölversorgungsbereich angeordnet sind, die hinter der Ölpumpe, d.h. im druckführenden Leitungsbereich angeordnet sind. Diese Leitung hat zumindest an einigen Bereichen einen größeren Umfang als der Innendurchmesser der Leitung, so dass ein verbessertes Oberflächenvolumenverhältnis erreicht werden kann. Die Isolierung kann vorzugsweise aus Kunststoff oder Keramik bestehen und kann innen- oder außenwändig angeordnet sein. Die Wärmeleitfähigkeit der isolierten Bereiche der Verbindungsleitung liegt bei 5 % oder weniger als die der umgebenden Metallstruktur oder der Ölgalerie, wobei insbesondere Stahl oder Grauguss eine Wärmeleitfähigkeit von etwa 50 W/mK aufweist und somit die Isolation eine Wärmeleitfähigkeit von 2.5 W/mK, bevorzugt 1 W/mK oder weniger aufweisen sollte.It should be noted that the isolated oil ducts are located in an oil supply area behind the oil pump, i. are arranged in the pressurized line area. This line has a larger circumference than the inner diameter of the line, at least in some areas, so that an improved surface volume ratio can be achieved. The insulation may preferably be made of plastic or ceramic and may be arranged internally or externally. The thermal conductivity of the isolated regions of the connecting line is 5% or less than that of the surrounding metal structure or oil gallery, in particular steel or cast iron having a thermal conductivity of about 50 W / mK and thus the insulation has a thermal conductivity of 2.5 W / mK, preferably 1 W / mK or less should have.
Die zu isolierenden weiteren Bereiche neben Zuführleitungen und den Schmierstellen sind insbesondere Getriebegehäuse oder bei einem Verbrennungsmotor das Kurbelwellengehäuse, die Ölwanne und die Ölgalerie. Zur thermischen Isolation von rotierenden oder oszillierenden Bauteile sind insbesondere Kurbelwelle, Kurbelwellenlager und Kurbelwellengehäuse, Nockenwellen und - Lager und Getriebewelle und Zahnräder berücksichtigen - wobei bevorzugt die Bereiche zu isolieren sind, die mit Öl im Funktionsgebrauch regelmäßig benetzt werden. Es ist vorteilhaft, wenn keine Frischluft in das Kurbelwellengehäuse gelangt, so dass dieses zur kalten Außenluft abgeschlossen ist, und allenfalls Blow-by-Gase austreten, aber keine kalte Frischluft in das Kurbelwellengehäuse eindringen kann, um eine erhöhte oder beschleunigte Erwärmung zu ermöglichen.The other areas to be isolated in addition to supply lines and the lubrication points are in particular gearbox or in an internal combustion engine, the crankcase, the oil pan and the oil gallery. For the thermal isolation of rotating or oscillating components are in particular crankshaft, crankshaft bearings and crankcase, camshafts and bearings and gear shaft and gears - preferably isolating the areas that are regularly wetted with oil in functional use. It is advantageous if no fresh air enters the crankcase, so that it is closed to the cold outside air, and possibly blow-by gases leak, but no cold fresh air can penetrate into the crankcase to allow increased or accelerated heating.
Durch die Zusammenfassung von zwei Wärmetauschern von Motoröl und Getriebeöl und/oder zwei Wärmespeichern für Motoröl oder Getriebeöl lassen sich in einer Baueinheit eine höherwertige Isolation und eine erhöhte Bauteilqualität gegenüber Leckage oder Korrosion erreichen, wobei kritischer Bauraum eingespart werden kann. Wird im Kühlkreislauf ein Phasenwechselmaterial eingesetzt, so bietet es sich an, einen zweiten umhüllenden Kühlkreislauf vorzusehen, wobei der erste Kühlkreislauf mit erhöhter Temperaturen gefahren werden kann, und der zweite Kühlkreislauf dazu dient, den inneren Kühlkreislauf zu kühlen, wobei ein Einfrieren oder einen soliden Zustand des Phasenwechselmaterials verhindert werden kann, so dass eine Betriebsfähigkeit auch bei sehr niedrigen Außentemperaturen erreicht werden kann.By combining two heat exchangers of engine oil and gear oil and / or two heat storage for engine oil or gear oil can achieve a higher-quality insulation and increased component quality against leakage or corrosion in a unit, which critical space can be saved. If a phase change material is used in the cooling circuit, then it is advisable to provide a second enveloping cooling circuit, wherein the first cooling circuit can be operated at elevated temperatures, and the second cooling circuit serves to cool the inner cooling circuit, wherein a freezing or a solid state the phase change material can be prevented, so that an operability can be achieved even at very low outdoor temperatures.
Claims (15)
- Lubrication system (100) for the lubrication of rotating or oscillating components having at least one oil suction pipe, which is arranged in an oil reservoir (1), an oil pump (4) connected to the oil suction pipe (3), and a heat source (7) connected to the oil pump (4) and downstream thereof further connecting lines (10) for supplying oil to lubrication points (11) which are structurally integrated in a metallic structural environment (63) of a metal housing, after which the oil is returned to the oil reservoir (1),
characterised in that
at least one connecting line (10) between the heat source (7) and the lubrication point (11) downstream of the heat source is insulated on the inside wall by an internal insulation (13), wherein the thermal conductivity of the internal insulation (13) is 5% or less than the thermal conductivity of the connecting lines or of the rest of the structural environment (63), and the heat source (7) is switched off or at least reduced in its heat output when a first upper oil limit temperature is reached. - System according to claim 1,
characterised in that
the thermal conductivity of the internal insulation (13) is less than 1 W/(m·K), or in that the outer circumference of the connecting line (10) is at least twice as large as the inner circumference of the connecting line (10). - System according to one of the previous claims,
characterised in that
the housing of the lubrication system or of the oil reservoir (1) is insulated by an internal insulation (13), wherein the thermal conductivity of the internal insulation (13) is 5% or less than the thermal conductivity of the structural environment (11, 63), or in that the oil reservoir (1) is made completely or at least partially from an insulating material and the thermal conductivity is less than 1 W/(m·K). - System according to one of the previous claims,
characterised in that
a highly insulated thermal reservoir (14) with a thermal conductivity of less than 0.01 W/(m·K) is comprised, which is arranged between the oil suction pipe (3) and the oil pump (4) or between the oil pump (4) and the heat source (7), or between the heat source (7) and a lubrication point (11). - System according to claim 4,
characterised in that
the thermal reservoir (14) is designed cylindrical and comprises a free piston (19) of thermally insulating material that divides the thermal reservoir (14) into two chambers (16a, 16b), whereby when filling the thermal reservoir (14) with oil above a first upper oil limit temperature of at least 90 °C into the first chamber (16a), a volume of oil is pushed back from the second chamber (16b) into the lubrication system (100) and when the oil is emptied from the first chamber (16a) in a cold-starting phase under a first lower oil limit temperature of at most 50° C into the lubrication system (100), the second chamber (16b) is filled with oil, so that the oil level in the oil reservoir (1) is thus only affected to an insignificant extent, and the thermal reservoir (14) is usable when required as a heat source and as a heat sink. - System according to one of the previous claims,
characterised in that
the lubrication system (100), oil reservoir (1) and structural environment (11, 63) is enclosed within a combustion engine (41) or a transmission, and in that the heat source (7) is provided by a combustion engine (41) or an electric battery or by an inverter. - System according to claim 6,
characterised in that
the transmission is a manual transmission that does not comprise an oil pump (4), wherein a coolant heat exchanger (24) is arranged in the oil reservoir (1), so that the transmission oil is heated by the engine coolant, and in that the coolant heat exchanger (24) is provided on the coolant side with a coolant valve (25) which is closed when the temperature falls below a coolant limit temperature and is opened when the coolant limit temperature is exceeded, or the transmission is a manual transmission, and the oil pump function is provided by the displacement action of a pair of toothed wheels, wherein an oil pressure line is arranged on that side on which the two tooth faces move towards one another, and an oil return line is arranged on that side on which the two tooth faces move away from one another. - System according to claim 6,
characterised in that
the heat source (7) comprises a connecting line of the exhaust pipe (55) of a combustion engine (41) with the structural environment (11, 63), or the heat source (7) comprises a piston spray cooling, wherein an oil volume flow that is sprayed by the piston spray nozzles onto the pistons (66) of the internal combustion engine (41) represents at least 30% of the oil volume flow conveyed by the oil pump, wherein piston spray nozzle oil volume flow is reduced as soon as a catalytic converter temperature is below a "light-off" temperature limit value (activation limit temperature) and the piston spray nozzle oil volume flow is reduced as soon as the oil pressure falls below a predefinable limit. - System according to claim 6,
characterised in that
the heat source (7) comprises at least a part of an oil line (32) between a combustion chamber (34) and a coolant duct (37), wherein that part of the oil line (32) which is arranged between combustion chamber (34) and coolant duct (37) is insulated on one side from the inside to the side of the coolant duct (37), wherein the thermal conductivity of the one-sided insulation (56) is less than the thermal conductivity of the structural environment (11, 63), and less than 1 W/(m·K). - System according to claims 4 and 6,
characterised in that
a thermal reservoir (14) for the transmission oil is comprised which structurally integrates as one unit a coolant heat exchanger (24) for heating the transmission oil with coolant. - System according to claim 6,
characterised in that
an exhaust gas/oil heat exchanger (60) for engine oil and transmission oil is designed in one piece and at least one exhaust gas bypass valve (29) is provided, so that an exhaust gas flow through the area of the engine oil/exhaust gas heat exchanger is interrupted when a predefinable first heat exchanger/engine oil limit temperature is exceeded, and in that the exhaust gas flow through the area of the transmission oil/exhaust gas heat exchanger is interrupted when a first heat exchanger/transmission oil limit temperature is exceeded. - System according to one of the above claims,
characterised in that
the coolant of the coolant circuit (61) comprises a phase change material (46) that has a melting temperature above 0 °C and a boiling temperature of at least 120 °C, in which the density rises with rising temperature, and in that the coolant circuit filled with this phase change material (46) is integrated in the combustion engine (41) to be cooled in such a way that there are no connecting lines leading to other components, wherein the first coolant circuit (61) is surrounded by and cooled by a second coolant circuit (57) which is filled with coolant having a melting temperature of at least below -30 °C and which has components arranged outside the combustion engine (41). - System according to one of the above claims,
characterised in that
a cylinder head coolant duct (42) and a cylinder block coolant duct (43) of the cooling circuit (61) of a combustion engine (41) are designed structurally separate in order to speed up heating of the coolant, wherein during a warming-up phase below a first coolant limit temperature a coolant first flows through the cylinder head (27) to heat it and from there through a cylinder/engine block (36), where the hot coolant heats up a cylinder wall in order to reduce wall heating losses, and is passed from there to a coolant pump (39); and in that when the first coolant limit temperature is reached in the cylinder head (27) a first coolant flow direction thermostat (44) opens and passes at least a partial volume flow of coolant to a cooler (45), and when a second coolant limit temperature is reached a second coolant flow direction thermostat (40) closes a connection to the inlet of the coolant pump (39) and makes a connection to the outlet of the coolant pump (39), so that the coolant in the cylinder/engine block (36) flows in the opposite direction to that of the coolant in the cylinder head (27), and a combined coolant flow is passed from the cylinder head (27) and the cylinder/engine block (36) through the cooler (45). - System according to one of the above claims,
characterised in that
a piston (66) of a combustion engine (41) on the inside of at least one piston skirt (102) is insulated by an insulation (13), wherein the thermal conductivity of the insulation is 5% or less than the thermal conductivity of the piston skirt (102). - System according to claims 4 and 6,
characterised in that
the exhaust gas heat exchanger (60) is an at least three-volume exhaust gas heat exchanger which is structurally integrated into the thermal reservoir (14) and comprises a first volume through which can flow at least a first partial exhaust gas flow, wherein the first volume is limited by or is surrounded by a first partition wall, wherein on at least one of the sides of the first partition wall not in contact with the partial exhaust gas flow a phase change material (46) is arranged in a second volume which is limited by or is surrounded by a second partition wall, wherein on at least one of the sides of the second partition wall not in contact with the phase change material lubricating oil can flow through a third volume.
Applications Claiming Priority (2)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
DE102013101844.0A DE102013101844A1 (en) | 2013-02-25 | 2013-02-25 | Heat-insulated lubrication system and lubricating process for rotating and oscillating components |
PCT/EP2014/053639 WO2014128308A1 (en) | 2013-02-25 | 2014-02-25 | Heat-insulated system for lubricating rotating and oscillating components of a motor vehicle |
Publications (2)
Publication Number | Publication Date |
---|---|
EP2959123A1 EP2959123A1 (en) | 2015-12-30 |
EP2959123B1 true EP2959123B1 (en) | 2017-09-06 |
Family
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Family Applications (1)
Application Number | Title | Priority Date | Filing Date |
---|---|---|---|
EP14707127.8A Active EP2959123B1 (en) | 2013-02-25 | 2014-02-25 | Heat-insulated system for lubricating rotating and oscillating components of a motor vehicle |
Country Status (6)
Country | Link |
---|---|
US (1) | US10001038B2 (en) |
EP (1) | EP2959123B1 (en) |
JP (1) | JP6152430B2 (en) |
CN (1) | CN105102777B (en) |
DE (1) | DE102013101844A1 (en) |
WO (1) | WO2014128308A1 (en) |
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DE102019108223A1 (en) * | 2019-03-29 | 2020-10-01 | Bayerische Motoren Werke Aktiengesellschaft | Internal combustion engine for a motor vehicle, in particular for a motor vehicle, and motor vehicle |
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- 2014-02-25 CN CN201480010506.9A patent/CN105102777B/en active Active
- 2014-02-25 US US14/769,657 patent/US10001038B2/en active Active
- 2014-02-25 EP EP14707127.8A patent/EP2959123B1/en active Active
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Also Published As
Publication number | Publication date |
---|---|
US20160010520A1 (en) | 2016-01-14 |
EP2959123A1 (en) | 2015-12-30 |
JP6152430B2 (en) | 2017-06-21 |
CN105102777A (en) | 2015-11-25 |
DE102013101844A1 (en) | 2014-08-28 |
JP2016513212A (en) | 2016-05-12 |
WO2014128308A1 (en) | 2014-08-28 |
US10001038B2 (en) | 2018-06-19 |
CN105102777B (en) | 2018-06-12 |
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