RU2577916C1 - System of heating and keeping of optimal temperatures of working liquids and oils in plants of self-propelled machines - Google Patents

Abstract

FIELD: machine building.

SUBSTANCE: system of heating and keeping of the optimal temperatures of working liquids and oils in the plants of self-propelled machines comprising an internal combustion engine (ICE), a waste-heat circuit including a gas-liquid heat exchanger with a gas gate, a circulation pump, a thermal regulator, an expansion tank of the heating medium, supply and drain pipelines; a heat-consuming circuit, comprising the liquid-liquid heat exchanger of the engine cooling system connected in parallel with the gas-liquid heat exchanger, a thermal regulator, a liquid cooling radiator connected in parallel with the heat exchanger of the engine cooling system; the heat-consuming circuit comprising the liquid-oil heat exchanger of the engine lubricating system connected in parallel with the gas-liquid heat exchanger, a thermal regulator, an ICE oil cooling radiator connected in parallel with the heat exchanger of the engine lubricating system; the heat-consuming circuit comprising the liquid-oil heat exchanger of the gearbox connected in parallel with the gas-liquid heat exchanger, a thermal regulator, a gearbox oil cooling radiator connected in parallel with the gearbox heat exchanger; the heat-consuming circuits comprising liquid heat exchangers connected in parallel with the gas-liquid heat exchanger, with thermal regulators located on the external or internal surfaces of the gearbox casings, wherein it additionally has the transmitter of oil temperature in the gearbox, the transmitter of cooling liquid temperature in the ICE, the transmitter of oil temperature in the gearboxes of driving axles, a shutdown solenoid valve terminating the heating medium circulation via the heat exchangers of the cooling and lubricating systems of the ICE, a shutdown solenoid valve terminating the heating medium circulation through the heat exchanger of the gearbox lubricating system, a shutdown solenoid valve terminating the heating medium circulation through the heat exchangers of the driving axles and gearboxes, a bypass solenoid valve, a control box or an onboard PC.

EFFECT: reduced time of after start-up warming of the ICE and come transmission devices, increased economical efficiency, traction power, operation reliability in the wide range of ambient temperatures.

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Description

The invention relates to mechanical engineering and is intended to reduce the warm-up time and maintain a given thermal regime in systems, components and assemblies of self-propelled machines, taking into account the priority of supplying additional heat flow to them.

Currently, the practical use of the heat of exhaust gases from internal combustion engines (ICE) has found application in autonomous heat power plants. These plants generate electricity and at the same time utilize the heat of the exhaust gases using gas-liquid heat exchangers. The water circulating in the heat exchanger circuit can be used for heat supply of stationary and mobile objects (Patent RU 2520796 C2, F02G 5/04).

The installation contains an internal combustion engine, a heat recovery system, and a system for the secondary use of thermal energy. The engine cooling system pump is connected to the internal combustion engine heat exchanger-heat exchanger. The circulation pump of the heat recovery system is connected to the heat exchanger of this system and the heat recovery heat exchanger. The exhaust gases of the internal combustion engine are fed to a heat exchanger-utilizer of their heat, after which it is sent to a device for receiving electricity and other consumers.

The disadvantage of this invention is that it is not able to provide quick heating of the engine and transmission units of mobile machines and maintaining optimal temperatures in them.

The closest technical solution adopted for the prototype is a system for automatically maintaining optimal temperatures of working fluids and oils in units and assemblies of self-propelled machines (Patent RU 2500899 C1, F01M 5/00).

The system contains ICE, utilization and heat-consuming circuits, thermoregulating equipment. The recovery circuit includes a recuperative gas-liquid heat exchanger with a gas damper, a circulation pump, a temperature regulator, an expansion tank for the coolant, and supply and discharge pipelines. The heat-consuming circuit of the engine cooling system includes a liquid-liquid heat exchanger connected in parallel with the gas-liquid heat exchanger, a temperature regulator, a liquid cooling radiator, connected in parallel with the heat exchanger of the engine cooling system. The heat-consuming circuit of the internal combustion engine lubrication system includes a liquid-oil heat exchanger of the internal combustion engine lubrication system, connected in parallel with the gas-liquid heat exchanger, a temperature regulator, an internal combustion engine oil cooler, connected in parallel with the heat exchanger of the internal combustion engine oil system. The heat-consuming circuit of the gearbox lubrication system (KP) includes a KP liquid-oil heat exchanger connected in parallel with a gas-liquid heat exchanger, a temperature regulator, a KP oil cooling radiator, connected in parallel with the KP heat exchanger. The heat-consuming circuits of the gearboxes (drive axles) include liquid heat exchangers connected in parallel with the gas-liquid heat exchanger, with temperature controllers that are located on the outer or inner surface of the gear cases.

A disadvantage of the system for maintaining optimal temperatures of working fluids and oils in the units of self-propelled machines is the inability to redistribute part of the heat between the systems and units, as well as ensuring priority priorities when heating certain machine units, which reduces the efficiency of using the heat of the exhaust gases.

In addition, it is known that during the post-start-up warm-up period of a cold engine there are significant friction power losses, especially in the cylinder-piston group (CPG), which is accompanied by an intensification of its wear. The main reason for the increased wear rate is the operation of the CPG parts in oil starvation mode. For example, tests of the 3D-6 engine showed that when working in winter oil, the time from start-up to the start of oil supply to the CPG parts is 5 min 55 sec at 0 ° C and 7 min 35 sec at minus 24 ° C.

The increased fuel consumption of the engine during the warm-up period is the result not only of a significant increase in friction losses, but also of the poor quality of the mixture formation process. Due to the low thermal regime of the engine, the fuel supplied to the combustion chamber does not have time to completely evaporate and burn out. During the warm-up period of the internal combustion engine, part of the fuel may be released in the form of intermediate products of the oxidation process and vapors that partially condense on the cold walls of the cylinders, falling into the engine sump, and are discharged into the environment through the exhaust pipe. As it warms up, fuel consumption decreases (the change occurs exponentially) and stabilizes at a certain level at a coolant temperature above 65 ° C.

It is known that in the post-start-up period the oil is heated in the lubrication system due to heat transfer from the cooling system and partly due to friction losses in the mates of the operating engine. Fuel heating in the nozzles is also provided by heat transfer from the coolant and due to the heat supplied from the working fluid to the surface of the atomizer located in the combustion chamber. There is no doubt that in order to reduce fuel consumption, reduce the time it takes for plentiful lubrication to come to the CPG parts and, as a result, reduce wear, it is necessary to reduce the time after starting the engine. Since the internal combustion engine is the most complex and expensive unit, which when operating at low thermal conditions has an increased fuel consumption and is subject to intense wear, it is obvious that, first of all, all the heat of the fuel burned in it should be used to reduce its warm-up time.

It is also known that during the cold start there are significant power losses in the gearbox. When you turn on the gear and the subsequent movement of the machine, these losses increase significantly. From numerous literary sources it is known that their value can reach 70% of the total power losses in the transmission units. Since the main share of losses is hydraulic (disk, extrusion from the interdental space, the drive of the oil pump, in the gearbox seals with hydraulic clutches, etc.), the quickest heating of the oil to the optimal thermal regime can be the most effective and economical way . Therefore, after warming up the engine to the optimum temperature, it is advisable, in the second place, to direct the additional heat flow to the gearbox as the most loaded transmission unit.

The technical problem, which is solved in the claimed system, is to reduce the time after starting up the engine, transmission units and other gearboxes, increase efficiency, traction power, reliability of the machine in a wide range of ambient temperatures due to the redistribution of heat generated by the systems and components of the machine, and secondary use of the heat of the exhaust gases, taking into account the priorities of the sequence of their heating. The system for heating and maintaining optimal temperatures of working fluids and oils in the units of self-propelled vehicles differs from the prototype in that it is additionally equipped with an oil temperature sensor in the gearbox, a coolant temperature sensor in the internal combustion engine, oil temperature sensors in the drives of the drive axles, a shut-off solenoid valve that blocks the circulation coolant through heat exchangers of the cooling system and the engine lubrication system, a shut-off solenoid valve that blocks the circulation of the coolant through the heat exchange The receiver of the gearbox lubrication system, a shut-off solenoid valve that blocks the circulation of the coolant through heat exchangers of the drive axles and other gearboxes, a bypass solenoid valve, a control unit or an on-board computer that controls the operation of the system.

The device and operation of the invention is illustrated by the following illustrations:

- FIG. 1. - a functional diagram of a heating system and maintaining optimal temperatures of working fluids and oils in units of self-propelled machines;

- FIG. 2. - a block diagram of the operation of the heating system and maintaining optimal temperatures of the working fluids and oils in the units of self-propelled machines.

Presented in FIG. 1 functional diagram of the system consists of I - utilization circuit; II, III, IV - heat consumption circuits; 1 - recuperative heat exchanger utilization circuit with gas damper; 2 - expansion tank utilization circuit; 3 - shutoff solenoid valve of heat exchangers of the cooling system and the internal combustion engine lubrication system; 4 - heat exchangers for heat-consuming circuits; 5 - shutoff electromagnetic valve of the heat exchanger of the gearbox lubrication system; 6 - gearbox oil cooler; 7 - shutoff electromagnetic valve of the heat exchanger of the driving axle; 8 - control unit or on-board computer; 9 - bypass solenoid valve; 10 - heat exchanger gearbox drive axle; 11 - oil temperature sensor in the drive axle; 12 - oil temperature sensor in the gearbox; 13 - temperature regulators of heat consumption circuits; 14 - oil cooler engine lubrication system; 15 - radiator of the engine cooling system; 16 - temperature sensor coolant in the internal combustion engine; 17 - circulation pump recycling circuit; 18 - temperature regulator drive gas damper recuperative heat exchanger utilization circuit.

The system operates as follows. After starting the cold ICE (liquid temperature tl <60 ° C), the electromagnetic valve 3 of the heat exchangers of the ICE cooling and lubrication systems is turned on. In this case, all the heat of the exhaust gases that is utilized by the recuperative heat exchanger of the recovery circuit is used to warm the engine. When the fluid temperature in the engine cooling system is equal to or more than 70 ° C, valve 3 is turned off and the flow of heat transfer to the heat exchangers is stopped. At the same time, permission is given to turn on the solenoid valve of the heat exchanger KP 5.

Further heating of the internal combustion engine to the optimum temperature (85-95 ° C) is carried out due to the heat that is accumulated by the cooling and lubrication systems during normal operation.

When the oil temperature in the gearbox is less than 60 ° C, the solenoid valve 5 is turned on and the liquid from the recovery circuit enters the heat exchanger of the gearbox lubrication system. The oil is heating up. When the oil temperature in the gearbox is equal to or more than 70 ° C, the solenoid valve 5 is turned off. At the same time, permission is given to turn on the solenoid valve 7 of the heat exchangers of the drive axles. The circulation of the liquid in the recovery circuit through the heat exchanger KP stops.

From numerous literature sources it is known that the oil temperature in the gearbox of machines is considered optimal in the range from 60 to 80 ° C. The given thermal regime makes it possible to ensure the optimum value of the viscosity of the oil, at which the minimum power loss in the gearbox is achieved and the rather high bearing capacity of the oil film on the friction surfaces is maintained, the presence of which contributes to minimal wear of the joints.

When the oil temperature in the heat exchanger of the drive axle is less than 40 ° C, the solenoid valve 7 opens. Hot oil enters the heat exchangers of the drive axles and other gearboxes. If the oil temperature in the drive axle reaches a value equal to or more than 50 ° C, then valve 7 is turned off and the circulation of the liquid through the heat exchanger ceases.

Based on the published data and studies performed by the authors of the invention, an oil temperature of 50 ° C in driving axles 9 can be considered optimal.

As the oil temperature in the gearbox decreases below 60 ° C, the heat supply to the drive axles and other gearboxes is stopped. The solenoid valve 7 closes. If the coolant temperature in the internal combustion engine reaches values less than 60 ° C, then all consumers, except the internal combustion engine, are turned off. The shutoff solenoid valves 5 and 7 are closed, and valve 3 opens. ICE cooling and lubrication systems are reconnected to the recovery circuit.

When optimal temperatures are reached in all heat-consuming circuits, the solenoid valves 3, 5, 7 close and the bypass solenoid valve 9 opens, allowing continuous circulation of the heat transfer fluid through the gas-liquid heat exchanger 1, thereby preventing overheating or boiling of the heat carrier.

The proposed device allows, if necessary, to adjust the values of the optimal operating temperatures of systems and units of specific brands of machines.

Claims (1)

A system for heating and maintaining optimal temperatures of working fluids and oils in units of self-propelled machines, containing an internal combustion engine (ICE), a recovery circuit including a gas-liquid heat exchanger with a gas damper, a circulation pump, a temperature regulator, a coolant expansion tank, supply and discharge pipelines; a heat-consuming circuit, including a liquid-liquid heat exchanger of the engine cooling system, connected in parallel with a gas-liquid heat exchanger, a temperature regulator, a liquid cooling radiator, connected in parallel with the heat exchanger of the engine cooling system; a heat-consuming circuit, including a liquid-oil heat exchanger of the engine lubrication system, connected in parallel with a gas-liquid heat exchanger, a temperature regulator, an internal combustion engine oil cooler, connected in parallel with a heat exchanger of the engine lubrication system; a heat-consuming circuit, including a liquid-oil heat exchanger of the gearbox (KP), connected in parallel with the gas-liquid heat exchanger, a temperature regulator, a radiator for cooling the oil of the KP, connected in parallel with the heat exchanger of the KP; heat-consuming circuits, including liquid heat exchangers, connected in parallel with a gas-liquid heat exchanger, with temperature controllers, which are located on the outer or inner surfaces of the gear cases, characterized in that it is additionally equipped with an oil temperature sensor in the gearbox, a coolant temperature sensor in the internal combustion engine, an oil temperature sensor in the gearboxes driving bridges, with a shut-off solenoid valve that blocks the circulation of the coolant through the heat exchangers of the cooling system and see the internal combustion engine, a shut-off solenoid valve that shuts off the coolant circulation through the heat exchanger of the gearbox lubrication system, a shut-off solenoid valve that shuts off the coolant circulation through the heat exchangers of the drive axles and gearboxes, a bypass solenoid valve, a control unit or an on-board computer.

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