DE1476614U - - Google Patents

Description

Usage pattern report "Device for heat transfer". The invention relates to a Device for heat transfer, e.g. a Evaporation and condensation system, at which the heat transfer can be regulated by special organs. Various devices are already known which are used to transfer heat from a heat source to an object to be heated by evaporation and condensation or by circulating a liquid. There are also known transmission systems with devices that are used to regulate the internal heat transfer capacity of the system to the heat consumer or to limit the maximum transferable heat.

In the case of the known regulating devices for the heat transfer of such systems, it has already been proposed that, on the one hand, the filling quantities, on the other hand the gas volume of the system of to regulate outside who by an elastic element, such. B. a membrane, a bellows or the like. Was achieved. It has also been proposed to create controllable heat transfer in refrigeration systems by expanding or contracting elastic bellows and changing their volume an evaporation and condensation system makes speaking effective or ineffective. In in these cases the elastic organ, e.g. U. the bellows, you same temperature or that exposed to the same pressure as the transmission system itself. If it is a matter of heat transfer systems in which heat at a low temperature, for example below 0, is to be transferred, such systems with elastic organs will work well. However, if heat is to be transferred at temperatures above 100 °, it is undesirable to expose the elastic organ to the high temperatures or the high pressures. It has finally been proposed to provide tiltable, inelastic containers in transfer systems for higher temperature heat, the inclination of which is controlled by a thermostat device, the respective inclination of the container supplying or withdrawing working fluid from the transfer system.

Such systems must have movable connections between the tiltable ones Provide containers and the transmission system, even when using high temperatures and consequently high pressures undesirably because the use of elastic elements, both membrane and bellows and elastic lines in a closed, in operation hot and pressurized system makes very high demands the material and the accuracy of the manufacturing process.

The systems provided with such negative devices were therefore involved and expensive. Particularly when larger amounts of heat are used in the case of relatively low temperatures high temperature (over 1000), the difficulties increased because the elastic elements at high temperatures and consequently also high internal pressure could only react with difficulty to subtle impulses. The present attempts at these disadvantages Invention to eliminate.

It should also be noted that a * Using building material resistant to high operating pressure or a pressure-resistant joint Operational safety forfeit relatively quickly when the temperature rises and that it is precisely the substances which, at ordinary temperatures, are groaao mechanical Have strength, often a dangerous one even at temperatures above 1000 Suffering from lowering of these properties.

The object of the invention is to create means by which the control of the heat transfer of a closed heat transfer system can be carried out in a simple manner, both thermostatically and arbitrarily, without deteriorating the operational reliability through the control device or complicating the construction of the system. According to the invention, this is in essentially achieved by the fact that the Change of the internal heat transfer efficiency Serving control element is kept during operation by virtue of its design or arrangement at a lower temperature and / or a lower pressure than the parts of the transmission system used for heat transfer. With these measures it is possible to always protect the control elements from the high pressure and / or the high temperature of the actual transmission system and thus significantly reduce the stress on its material. In this way it is possible to make the control of the heat transfer of a closed transmission system just as easy and simple as z. B. the regulation of a gas flame or an electrical heat source. A transmission system with such a control can be used for a wide variety of purposes, e.g. B. for the recovery of waste heat or excess heat from an internal combustion engine, a continuous fire stove, or another heat-generating main system.

In addition to the waste heat, this device can also be used to regulate the heat of other, difficult-to-regulate heat sources, such as B. Ölflanrnren, especially flames wickless oil burners. The invention also makes it possible to a continuously generating heat source of energy for the operation of equipment to be heated intermittently, e.g. B. intermittent refrigerators to use.

The drawing shows schematically in Fig. 1 to 3 three different Embodiments according to the invention, the devices for transferring heat represent on the cooker of an absorption chiller and with devices cooperate to regulate the heat transfer.

In Fig. 1, the digester of a usual continuous and with 10 refrigeration apparatus working with pressure-equalizing gas, with 11 its usual pump loop for the liquid circulation and designated with 12 of the heater of the cooker.

The heating element 12 is connected to the cooker 15 through a line 13 that leads downwards. connected to closed utilities. This Cooker is arranged in the form of a jacket rings around a primary heat source 16, ie from an exhaust pipe of an internal combustion engine, long-life furnace o. The like. Can consist. The line 13 is first a short way down, then a longer one Slightly downwards, a short distance goes essentially horizontally and is finally downwards again. In the horizontal part of the line 13 a chamber 14 is provided, through a line 17 opening into its bottom , 17th with the heel device 1 of the transmission asynteaB connected is. The regulating device 18 consists of two metal tubes 19, 20, each separated from one another by a wall 21, 22, but with the walls 21, 22 remaining close to one another.

The bellows 19 is connected to the chamber 14 by a line 17 and, like the aforementioned line, is filled with a vaporizable liquid up to the liquid level in the chamber 14. The lower bellows 20 is connected by a line 23 to a sensing element 24 of a type known per se so that it can with the line 23 and the sensor body 24 a closed the line 2. forms senes, known per se steam and / or liquid containing thermostat system. The sensing element 24 is arranged, for example, in the cold room of the refrigerator.

The liquid contained in the bellows 19, line 17 and chamber 14 should for the heat transfer from the cooker 15 of the transfer system to the cooker heating element 12 of the refrigeration apparatus are used. This liquid has to be applied to both the Desired temperature range can be selected as the amount of heat to be transferred. The condensation temperature of the liquid, i.e. H. the temperature that is im Radiator 12 comes about is on the amount of heat transfer fluid extremely dependent, and in practice it is essentially dependent on the density of the vapor of the filler in question in the system. If therefore at a certain temperature in the cooker 15 all the liquid contained in it has evaporated, the density of the steam in the system has its respective maximum value. As a result, the maximum value of the temperature in the heating element 12 is then also determined.

In order to be able to regulate this temperature, according to the invention is one Any amount of liquid that can be added to or withdrawn from the heat transfer process provided, which are fed to the transfer process or returned to it as required can be withdrawn. Since the liquid in the line 17 and in the bellows 19 is practical is outside of the steam flow from the cooker 15 to the heater 12, this retains Liquid in particular the part in the bellows 19, a significantly lower temperature as z. B. Chamber 14.

Keeping the temperature of the control device 18 low can still can be improved in that the line 17 consists of a poorly conductive heat Metal is made, such as B. German silver or other poorly conductive alloys known per se. The control device 18 and the line 17 can also with Cooling fins or the like are provided.

It is assumed that a temperature of 200 is desirable and that the temperature of the heating source 16 is much higher. Around now to prevent the excessively high temperature of the heat source 16 from affecting the radiator is transmitted, one has to check the density of the vapor in the transmission system on a hold a certain amount respectively. they only up to a certain one Maximum value let rise. According to the invention, this is achieved in that the control device 18 is set in such a way that the amount of liquid withdrawn from circulation is always remains so large that, even if all outside the bellows 19, the line 17 and the chamber 14 existing liquid evaporates, the sealing vapor not the Amount of the desired temperature on the radiator 12 can exceed. It is here to notice that there is an evaporation of liquid from the liquid level of the chamber 14 is not excluded. But this phenomenon has for the practical process no meaning, because in the steady state of the system there is just as much liquid as evaporated from the mirror of the chamber 14, it as condensate from the radiator 12 is running again.

Let us now assume that instead of 2000 a temperature of 2500 im Radiator 12 is desired. To achieve this, the bellows 19 is simply after pressed up, z. B. by a rotating drum or other adjustment device on Bellows, which is not shown to relieve the figure, because it is for those in the figure The execution of the thermostat arrangement shown is common.

As a result, a certain amount of liquid from the chamber 14 is through the line 13 into the cooker 15 overflowed so that the amount of liquid participating in the heat transfer increases by this amount increased. As a result, provided that the heat supply to the cooker 15 is sufficient, the density of the steam and therefore the temperature of the heater 12 increase. Will then again a lower temperature in the radiator 12 is desired, so the bellows 19 simply extended by the mentioned rotating drum, so that aioh the volume from the overflow of the chamber 14 to the bottom of the bellows 19 enlarged. This sinks first the mirror in the chamber 14 by a corresponding amount until it is through liquid coming from the heating element 12 and condensed there is refilled, A corresponding amount of liquid is thus withdrawn from circulation. For a sel automatic change of the Spießelhöhe in the chamber 14 is used in the The thermostat system 20, 23, 24 shown in the figure by placing the sensor element 24 in brings thermal connection with the object whose temperature is regulated shall be. So the packing z. B. with the evaporator one of the refrigerator operated Kühlsohrankea be connected in a thermally conductive manner. if the content of the mentioned thermostat system expands due to the temperature increase of the evaporator, the bellows is elongated 20 so that the plate 22 is against the plate 21 of the bellows 19 pushes and compresses it.

For this purpose, the pressure in the system 15, 14, 12 must be overcome. By corresponding training of the control device 18, for. B. by a known per se Spring arrangement on bellows 18, the mentioned pressure can be more or less compensated.

If you want to connect the sensor body to the Helzpatne 12, the bellows 19 and 20 are, for example, nested and work in well-known white against a feather The transmission device according to Fig. 2 differs from that of fig. 1 in wise in that its control device is not exposed to the internal pressure of its actual (primary) heat transfer system. In addition, the temperature of the control device can be kept significantly lower than that of the primary system at the same time. The reference numerals in FIG. 2 correspond to those in FIG . The drain line 31 is passed through the digester 33 of a secondary heat transfer system which is also closed. The secondary system is also provided with an inlet line 34 and an outlet line 37, which connect its digester 33 to the air-cooled condenser 36. The heat dissipation of the condenser 36 is facilitated by cooling fins 35. The discharge line 37, which returns condensate from the condenser 36 to the digester 33 of the secondary system, is marked with ei. nem liquid closure 38 is provided, which opens into a control device 39. The regulating device 39 contains a membrane 42 which is slightly curved upwards in order to be able to spring upwards and which lies over the openings of the lines 38 and 43 which open into a base plate 44. The membrane 42 presses against the base plate of a bellows 40. The whole is enclosed in a housing 45.

The bellows 40 is through a conduit 41 with a sensing body, not shown connected and thus corresponds to the thermostat system 20, 23, 24 of Fig. 1. The membrane 42 can also, if necessary, with a special valve body or other Seal be provided so that when the membrane 42 is pressed down, the The mouth of the line 43 leading to the digester 33 is tightly closed.

About the mode of operation of the primary transmission system 30, 31, 12, 32 doesn't need anything To be specially mentioned. Suppose only that the temperature of the heater 12 should be about 2000 and that the pressure in System is relatively high at this temperature, for example 20! ttm. To protect the control device 39 from this pressure and temperature, selects for the secondary transmission system 33, 34, 36, 37 a liquid that z. B. at 100 ° a pressure of 1 to 2 atm. Has. Even if you choose a different liquid it can be done by regulating their circulation or by determining the filling quantities achieve that the pressure and temperature in the secondary system do not exceed a certain amount can exceed.

It is now assumed first that the temperature of the trimärheizquelle 16 has approximately the desired height, so that the temperature of the heater 12 is approximately Is 200 °. This state corresponds approximately to the case that, as shown by the cooker 10 of the Refrigerator is to be included, from the heating source 16 to the cooker 30 of the Primary systems just as much heat is supplied, if one disregards the losses. In this desired state, for the secondary transmission system 3, 34, 36, 37 initially assume that its cooker 33 is not being loaded with liquid will, d. H. that it boils completely empty quickly. This requires, that practically all liquid in the secondary system is withdrawn from circulation, which is why achieves that the membrane 42 of the regulating device 39 through the bellows 40 is held in its lower closed position. Namely, if the mouth of the Pipes: 43 is closed, the drainage from the condenser 36 gradually collects Liquid amount in the liquid closure 38 and increases to a certain level in the discharge line 37.

It can therefore no longer reach the digester 33.

From the small amounts of heat generated by the convection currents of the steam are moved within the line 34, can be disregarded in this context. Under these conditions, the secondary transmission system is practically without Effect on what is going on in the primary transmission. system. Now assume that the sensing element of the control device 39 on the evaporator of the one operated by the cooker 10 Kälgeapperatet is arranged. It should also be assumed that the temperature this evaporator drops undesirably. As a result, the content of the Thermostat system 40, 41 and the aforementioned sensor body pulls together, which is a shortening of the bellows 40 causes. The membrane 42 is lifted by its own spring action, so that : the rounding of the tube 43 is exposed.

The liquid column built up in the line 38,37 thus arrives through the control device 39 into the digester 33 of the secondary system 8 and comes there for vaporizing. This takes place with the extraction of heat from the hole punch 30 the line 31 after the radiator 12 flowing steam, the Tempertaur it accordingly falls or thereby completely or partially already before it is reached of the heater 12 is condensed. This lowers the temperature of the Heinz body 12, and the refrigeration capacity of the refrigeration unit decreases or gradually stops on.

The processes in the secondary transmission system 33, 34, 36, 37 correspond essentially those of the primary system, i.e. H. the liquid is from the cooker 33 boiled, introduced through line 34 into the condenser 36, where the vapors condense and through the lines 37, 38 through the control device 45 and the Line 43 flow off again to the digester 33. As a result of the interruption of the heat supply to the radiator 12 and thereby to the cooker 10 but the temperature gradually rises the previously too cold evaporator in the refrigerator, causing an expansion of the liquid causes in the thermostat system 40, 41. As a result, the bellows 40 is elongated and closes aottt again the mouth of the pipe 43. That from the condenser 36 back-flowing condensate is in this way again under the build-up of a new fluid spaces in the lines 38, 37 accumulated. This will make the Cooker 33 gradually emptied again, which interrupts the dissipation of heat caused by the primary system 30, 31, 12, 32.

The dimensions of the secondary transmission system are naturally based according to the respective requirements. Intended to. z. B. an intermittent absorption chiller be heated with the transmission system according to the invention, the only during should be heated relatively short times, and provides the primary heating source 16, for example, the chimney pipe of an oil-operated, permanent heating device , the transmission system 33,34, 36,37 must be dimensioned so large that during the period of the Digester 10, i.e. during the cold period of the intermittent refrigeration apparatus, the Total amount of heat delivered by the heater to the primary transfer system 30, 31, 12, 32 can be withdrawn and transferred to the capacitor 36. Which then required for the periodic switching on and off of the control device 39 Arrangements and devices such as B. the pulse generator are already known.

The device shown schematically in Fig. 3 for operation of refrigerators differs from that of Fig. 2 essentially only by the formation of the control device 39.

Furthermore, in the device according to Fig. 3, the secondary, transmission system is 50, 51, 53 are provided with a common supply and discharge line 51, so that the Steam coming from the cooker 50 on the liquid flowing back from the condenser 53 flows past. The reference symbols otherwise correspond to those in FIGS. 1 and 2.

The control device 39 consists of three bellows 55, 56, 57, of which the bellows 55 belongs to the Term08-stat system 23,24. To the thermostat from the pressure Relief in system 50, 51, 53 and to compensate for the gravity is the bellows 56 connected to a spring 58 in a manner known per se. The bellows 57 is through a rod 59 connected to its bottom with the rod resting against the bellows 55 Cover plate 61 of the bellows 56 connected. The caused by temperature fluctuations on the sensor body The change in length of the bellows 55 caused by 24 therefore has no changes in volume of the bellows system 56,57 result, rather the two bellows 56 and move 57 together.

An expansion of the content of the sensor body thus only has a downward shift of the punch 60 attached to the rod 59 result. But if only this When the punch moves downwards, the one below the exit point of the Line 51 lying part of the bellows contents 57, so that from the capacitor 53 in the direction After the boiler 50, the condensate flowing back is stored in the interior of the bellows 57 will. The amount of circulating heat transport medium in the secondary system 50, 51, 53 therefore decreases accordingly, which has the same implications as for the storage in the container 14 of Fig. 1 or in the pipe 38 of Fig.

2 is described. The advantage of the device according to Fig. 3 in comparison to that of Fig. 2 lies essentially in the fact that when appropriate dimensions are selected and fill quantities the seal required to close the liquid return 42,43 (Fig. 2) can be dispensed with.

The new process can not only be used for the operation of both use continuous and intermittent refrigerators, rather also makes it possible to adjust the temperature of the heat emitting part (the secondary Radiator) one with a heavy one controllable heat source operated closed transmission system so precisely to regulate that the system in relation on the field of application is almost equivalent to a gas flame or the like.

As a result, such a heating element can also be used for apparatuses which require great accuracy with regard to temperature control. If a system is to be used for the intermittent operation of an apparatus, the amounts of heat to be carried away by the secondary system are, as already mentioned, considerable and in many cases even greater than that which are to be supplied to the refrigeration apparatus to be operated in the primary system during its coohperiods. However, according to a further invention, it is also possible to utilize this amount of heat to be dissipated by the secondary system, in particular for the operation of water heaters, heating cabinets or other businesses that can be operated with heat at a lower temperature than that required by the cooker of a refrigeration device . It should be noted that the amounts of heat to be dissipated by means of the secondary system can be significantly greater than that transferred from the primary system to the refrigeration unit, but according to the invention they should be transferred at a lower temperature, which enables moving parts to be arranged in the secondary system. Protection claims --------

Claims (8)

1. Device for thermostatic control of heat transfer from a primary heat source with temperatures above 100 ° to a heat consumer, in particular an absorption chiller, by means of a closed heat transfer system, whose internal heat transfer capability to the heat consumer can be regulated, characterized by a pressure-sensitive control element which, under the influence of thermostatsoher Control the capacity of one of the heat-absorbing part of the transmission ayatema thermally separated liquid collector change and that in the company by a Cooling device at a lower temperature and / or by its design or arrangement is kept at a lower pressure than that for heat transfer serving parts of the transmission system. 2. Apparatus according to claim 1, characterized in that a first there is a closed transmission system with a second, preferably also self-contained transmission system is in a thermally conductive connection and the heat transfer of the first system to the heat consumer by arbitrary or thermostatically induced change in the effective amounts of the working fluid of the second system is controllable. 3. Apparatus according to claim 2, characterized in that the second heat transfer system in a manner known per se a hermetically sealed, Includes thermostatically controlled valve. 4. Transmission system according to claim 2 or 3, characterized in that the heat-absorbing eln Part of the second system during its operation has a temperature lower than or equal to that of the exothermic part of the first system. 5. The device according to claim 1, characterized in that the heat transfer capability of the transmission system with respect to two heat consumers alternately to zero can be regulated. 6. Apparatus according to claim 5, characterized in that the for Regulation of the heat flow to the first heat meter from the system heat quantities to be dissipated wholly or partially as useful heat to a second heat consumer, z. B. a water heater, an intermittent cold apparatus o. The like., be transmitted. 7. transmission system according to claim 1, characterized in that the moving part of the thermostat system through a conduit containing liquid from heat poorly conductive metal, such. B. Neueilber or other poorly conductive Alloys connected to the transmission system. 8. Device for thermostatic control of heat transfer in whole and in their parts as described and illustrated.