DE615324C - Intermittently working absorption cooling apparatus - Google Patents

Description

Intermittent absorption chiller The invention relates to intermittent absorption chillers and a method to their operation. Under intermittent absorption chillers are Apparatus to understand during which periods in which refrigerant from an absorbent is expelled and liquefied at higher pressure, alternating with periods, at where the liquefied refrigerant evaporates at lower pressure and produces refrigeration from absorbent is resumed.

It is known in such apparatus, absorption solution in the Cooking periods between a heated cooking area and an unheated absorption area to circulate through a temperature changer. With those proposed so far Apparatus of this type but had to use the coolant for the absorption point during the cooking periods are switched off and regularly again at the beginning of the absorption period employed. otherwise an absorption of the cooking gases in the cooled absorption solution would arise. Any air cooling of the red heated absorption solution containing container during the cooking periods is sufficient with the known. Investments not enough to absorb the entire amount of it falling out during the absorption periods Remove absorption heat. Because if you use the air cooling in the known devices; would have made so strong, the cooker fumes in the boiling periods would be equal to theirs Disappearance, as mentioned, is immediately reabsorbed in the adequately cooled solution without to the condenser and in a liquefied state from there to the evaporator to go.

Furthermore, intermittent absorption refrigerators are already known. which only circulates during the absorption periods between the main amount of Have absorption solution absorbing digester and a continuously cooled cooling element. In these systems, the majority of the absorption liquid is used in the cooking periods brought to the high expulsion temperature. Only a small part of the solution will be kept cool during cooking periods. This has the disadvantage that when changing periods from boiling to cooling capacity, most of the absorption liquid is hot and the entire heat of the liquid must first be withdrawn from it in order to. the absorption enable ztt. With water cooling, this requires a very large amount of cooling water and with air cooling, extremely large cooling surfaces, because apart from the absorption towers also the total liquid heat of the absorption solution through the cooling device must be removed. Furthermore, the large amount of hot cooking liquid that the pressure reduction in the apparatus at the beginning of the absorption period is slow can occur, because only when the total amount of hot liquid on the lower Absorption temperature the pressure in the apparatus can increase decrease to such a low value that, the vaporizer the generally desired low temperatures. '' The time that goes by, uni when changing from the Cooling season to heating season A1) -sorption solution from the absorption temperature to bring the expulsion temperature, and the time it takes to get everyone at the bottom During the boiling period, the absorption solution, which is at the expulsion temperature, is at the absorption temperature are dead times for the operation of the apparatus, in which the apparatus is practically ineffective. The invention aims to shorten these dead times, to eliminate the above-mentioned disadvantages of the known apparatus and an apparatus to create at which in the boiling and absorbing periods absorbent liquid and the one with a constantly exposed to the influence of an external coolant Cooling device is provided whose heat dissipation capacity to remove the largest absorption heat is insufficient per unit of time. This is opposite the known devices with circulation of the solution only in the boiling period the advantage achieved that the external coolant can remain permanently employed, which z. B. for exclusive air cooling of apparatus is particularly desirable and advantageous is. Opposite the second group of apparatus with circulation of the solution in the absorption periods there is the advantage that the pressure in the apparatus is brought down much more quickly can be so that useful cold is generated faster, and that the cooling device can be much smaller because it only absorbs the heat of absorption per unit of time, but does not have to carry away larger amounts of liquid heat at the same time, which at the same time means an improvement in the degree of efficiency.

The invention is to be described in more detail with reference to the accompanying drawing are described, with further characterizing features of the invention will.

In the figure, ii denotes an unheated storage vessel for absorption solution, 12 a liquid temperature changer, 13 the digester, 14 the condenser and 15 the evaporator of the apparatus. It is assumed that the apparatus works with water as the absorbent and anionic as the refrigerant, but the apparatus can be operated with any other known refrigerant and absorbent. The apparatus is originally filled up to the level line, which is marked with I. The storage vessel ii is therefore completely filled with absorption solution and remains completely filled, especially during the cooking periods of the apparatus.

The apparatus works as follows: During the cooking periods, the cooker 13 is used in any known manner, e.g. B. by a heating cartridge, a gas flame, an oil burner, a steam jacket o. The like., Heat is supplied. By supplying heat to the cooker, which is provided with insulation 30 in a manner known per se, the liquid in it becomes lighter than the solution in the unheated storage vessel or in one leg of the temperature changer due to the thermosiphon effect. so that the cooker level rises and the liquid tends to circulate between the boiling point and the storage vessel. In order to increase this still further, as shown in the figure, a pump loop 13a, ie a gas bubble boiling lifter, can be used, which is heated in a known manner by the supply of heat to the cooker and the absorption solution between the unheated storage vessel by gas bubble effect ii and the boiling point r3 circulates. In this case in particular, it is expedient to provide a chimney 31 which extends through the insulation 3o, around which the pump loop 13a is wound on the one hand, and which is in good metallic connection with the, for example, tubular cooker 13. It is advisable to cast metal compounds with good thermal conductivity between the two pipes so that the chimney and stove are connected to one another with large metallic surfaces.

The rich liquid lifted by the pump loop 13 "in the exemplary embodiment is degassed by the heat supply in the digester 13, which is designed as a relatively narrow tube, and flows through a line 20 to the temperature changer 12, which is surrounded by insulation 32, similar to the digester This insulation can expediently consist of cork or the like, while the insulation of the cooker 13 and the .Punipschlinge 13a is expediently designed as foil insulation or as vacuum insulation to have the lowest possible thermal capacity 2o into the upper part of the storage vessel i ra. The part i ia of the storage vessel consists in the exemplary embodiment of a cylindrical vessel, (read by two lines i ic and i id with (l a lower part of the storage vessel i Lb is connected. This lower part too Part i i11 is designed as a cylindrical vessel, the contents of the parts i ia and I Ih of the storage vessel The absorption solution contained therein may be exposed to a cooling device which is exposed to the constant influx of an external coolant both in the boiling and in the absorption period. In the exemplary embodiment, the "feile ti" and I Ib are therefore provided with cooling fins 33 which are offset from one another in the vertical plane in such a way that the cooling fins. Both the vessel iIb and the vessel eia were naturally ventilated with fresh air. In the exemplary embodiment, the cooling device 33 required to dissipate the absorption heat from the apparatus is attached directly to the storage vessel i in general. From the lower part IIb of the storage vessel, the rich solution is led through line 19 via the insulated temperature changer 1 2 to the unip loop 13a and lifted from there to the cooker. This line 16 can be provided in a manner known per se with finite insert plates 34 and optionally with cooling plates 35, but any other rectification arrangement or other device that prevents the liquid from boiling up in the narrow boiler tube can also be used a vessel-like enlargement 36, which is provided on the outside with cooling flanges 3; and on the inside finitely perforated insert plates 38. Two lines 39 and 40 are led from the vessel 36 to a vessel 41 located lower down, and the line 39 opens into vessel 36 at a slightly higher point than the conductive dough 40. The stopping point is also in the vessel 41 The line 39 is higher than that of the line 40, which in any case must be pulled down below the point at which the line 39 converges. During operation, a certain amount of liquid condenses in the vessel 36, which amount mainly consists of absorbent and which collects on the insert plates 3S. Excess amounts of liquid flow into the vessel .t.1 and collect there. These excess quantities can be dewatered through a line 42 to a storage vessel, for example after the 1_line iId. The amount of liquid that is collected in vessel 4i has a purpose to be discussed later Line 18 further to the condenser 14, which can be designed in any known manner is insulated by an insulation 43. From this part i5a of the evaporator protrudes ", in the exemplary embodiment the actual evaporator 15b, right down into the cooling space, for example a refrigerator. In the exemplary embodiment, this actual evaporator is formed in forums of a cylindrical vessel 44, from your from in the known way Rolirschlangen-45 to from Pull towards the ice box or other items that need to be cooled quickly. However, any other type of vaporizer can also be used without affecting the essence of the invention. The evaporator is expediently seen with an automatically acting drainage device. However, the automatic drainage of the evaporator is not a fundamental requirement of the invention. Rather, the drainage can also be done by known, manually operated or periodically controlled valves. In the exemplary embodiment, the automatic drainage of the evaporator is achieved by a () -pipe 46 which opens into a vessel 47. Since the water remaining in the evaporator in one absorption period is heavier than the newly arriving ammonia in the next boiling period, the brightly bleached water is at the lowest part of the evaporator and is therefore pushed up into the tube 46 when it is filled again until it is filled overflows into container 47 at the end of the next cooking period. This overflowing water is drained through a line 4S to the pipe iä, vessel 41 and line 42. However, this line 48 can also be led directly after the liquid in the storage vessel ii or to any other amount of preheated liquid. However, the drainage can also be done in any other way.

The formation of the evaporator and rectification arrangement 34, 35 in the line 16 and the vessel 36 can be designed as desired. It can for example, instead of the rectifying arrangement shown, rectification of the steam coming from the cooker by its own before it enters the condenser Condensate occurs, or the cooker vapors can bubble through rich or poor absorption solution. like in. Vessel 41 shown, brought and thereby rectified or through other heat exchange with rich or poor solution. Of the The upper part of the vaporizer must be insulated as shown. being expedient an insulation of low \ V <irine capacitance, e.g. B. Foil insulation or V actitim insulation, is used. Any other means can also be used will, to prevent uncondensed refrigerant vapor from being released during cooking periods enters the evaporator and heats it up. For example, the evaporator can be partially be filled with an auxiliary liquid that is lighter than the refrigerant, so that during the boiling periods this liquid forms parts 44 and 4.5 of the figure fills, but gradually displaced towards the top by the running in of the condensate will.

As soon as the heating is turned on in the apparatus shown, due to the small amount of liquid that has to be heated in the cooker, a strong gas development from this small amount of liquid will immediately occur, so that only a short time elapses before the first refrigerant vapors reach the condenser. Since the cooling element moving away the heat of absorption by means of the cooling fins 33, i.e. 1i. the actual absorption point, which emits the heat of absorption, is designed as a storage device and is filled with liquid during the cooking period, no condensation or absorption of cooker vapor can occur in it. ' Rather, the liquid in the line 4.2 represents a discharge that keeps the cooking gases away from the cold absorption solution and ensures that they are immediately routed to the condenser, so that this is fully utilized from the beginning to the end of the cooking period. Through the circulation device, i. left either by the thermosiphon effect of the digester, which is caused by the specific weight difference of the liquids in the digester and storage vessel and the lines connecting them, or, as shown, by the gas bubble pipe 130, the degassed digester contents are gradually replaced, and that of the liquid in the digester The heat absorbed is used in the temperature changer 12 to pre-warm the new rich solution flowing to the cooker. The poor solution emerging from the temperature changer into the storage vessel is withdrawn in the exemplary embodiment by the cooling device 33, which removes the heat of absorption in the absorption periods, during the cooking period, so that a certain part of the clay-running solution is always ready for absorption and so the cooling device 33 is constant is exploited. If the entire solution contained in parts i ja and 1 1b of the storage vessel and in temperature changer 12 is sufficiently degassed, for example from its original concentration of 40% a to 18% a, for example, then in any known manner, for example by means of a thermostat system , which is controlled in a manner known per se either by the temperature or the pressure in any of the apparatus parts, the heating is turned off.

As soon as the heating is switched off, the pressure drops very quickly because of the cooling flanges 37 in the vessel 36 and, in the exemplary embodiment, also through the cooling flanges 35 in the line 16, especially since the Koclierinhalt is extremely low in relation to the overall system. The lowering of the pressure in the line 16 and in the vessel 36 has the consequence that the liquid rises out of the vessel .41 into the lines 39 and .4o and thus automatically a pressure column in the connecting line between the evaporator that locks the evaporator gas to the boiling point on the one hand and the cooker or the apparatus parts cooled by the cooling fins 37 and 35 on the other hand when the heat supply to the apparatus changes or when the period changes. The upper part lja of the storage vessel is connected via a line 49 of small diameter to a compensating vessel 2i, which is expediently cylindrical and is surrounded by any insulation jacket 50 . In the exemplary embodiment, the actual liquid level of the storage vessel ii, the volume of which is expediently smaller than that of the storage vessel, is moved into this equalization vessel. A line 5i leads from the upper part of the vessel 2i to the gas space of the digester or to the pressure area of the vessel 36. The mouth of this line 51. can open either directly above the digester level or a rectification device of any kind, not shown, or above the bumpers 3.4. This line has the effect that the pressure above the level of the compensation vessel 21 in the boiling and absorption periods is just as great as the pressure above the expulsion point. What is essential is the connection of the line 51 to the apparatus area, as the pressure drops rapidly when the boiler heating is switched off, as is the case, for example, in FIG. B. is achieved by the vessel-like enlargement 36 in the embodiment. This balancing vessel 21 ensures that the pressure drop in the area of the vessel 36 and the line 16 is transferred to the vessel 21 and thus to the storage vessel ii.

As soon as the boiling period is over and the pressure drop in the vessel 36 and thus at the same time in the digester 13 and compensation tank 21, flows out of the Gas coming from the vaporizer, which produces cold when it is generated, as it is the way zuin cooker is locked by the liquid lock 39.4o, from the evaporator over Line 18, vessel 41 and line.Iä after the line iid and pearls in the line i id upwards. The columns of liquid arising in lines 39 and -o keep your pressure the counterbalance. The one in the upper one, which serves as an absorption point Gas entering part i i11 of the storage vessel is quickly absorbed. (1a yes the solution in both parts i i11 and i ib of the storage vessel already during the Heating season was cooled. The absorption and thus the cooling capacity begins a lot faster than it was possible with machines of the previous type, where only the entire Absorbents are cooled from the digester temperature to the absorption stone temperature must be. The refrigerant vapors entering the uncooled line i 1d cause absorption solution to circulate during the absorption period your part i ib of the storage vessel serving only as storage through the cooling device the actual absorption point, which in the exemplary embodiment by the upper Part i i "of the storage vessel is formed. The refrigerant vapors also cause a circulation of the solution between the parts i ra and I 1 b via the line iic. The storage vessel ii therefore adjusts itself during the absorption period self closed. from the circulation system operated by the thermosiphon 13a During the cooking period there is a different circulation system, in which the one from the evaporator coming refrigerant vapors because of this circulation <lurking with new ones poor solution come into contact. The heat of absorption is lost through the constantly exposed to the air cooling cooling device 33 discharged, but can Cooling of the absorber as well as that of the condenser 14. also by water cooling or indirect cooling systems.

Appropriately, the confluence points of the lines iid, iic, i9 and 2o in the storage vessel are chosen so that during the absorption periods enriched solution can only enter the line i id from below when the entire contents of the storage vessel have already become rich, and that During the Kocliperioden poor solution can only come into the flow of the line i9 when the entire remaining contents of the storage vessel are already poor, so that no or the smallest possible mixtures of the absorption solution in the storage vessel itself, instead of, as shown, to consist of two cylinders with connecting lines, the porin of a single vessel, the content of which is prescribed, e.g. by perforated partition walls, a certain path, or in the form of a spiral spiral, the diameter of which is so narrow that no mixture is possible Both solutions can enter the storage vessel. Line d.9, which is an open liquid, is particularly expedient Establishes a connection between your storage vessel ii and the equalizing vessel 21, made of such a tight flow that no convection currents can arise between your storage vessel and the vessel 21. The content, in particular the liquid level, of the vessel 21 therefore does not take part in the circulation of the absorption solution, but is withdrawn from all flow movements. The equalizing vessel 21, which can be located at any point in the liquid circulation, but according to the invention should be spatially and thermally separated from the cooling point of the apparatus, ie the cooling flanges 33, initially has the above-mentioned purpose of reducing the pressure between the cooker level when the cooker heater is switched off and the vessel 41 arises, to be transferred to the storage vessel and to a certain extent, through this suction effect, to make it easier for the evaporator gas to tear open the liquid lock in the line d.2 and to make the way to the absorption point i i11. The vessel 2i also serves to accommodate the level fluctuations of the liquid that occur during degassing and absorption. While, as mentioned, the apparatus was originally filled up to level line I, the level in vessel 21 sinks to level line II during the expulsion. The amount of liquid corresponding to this level difference is again in the evaporator as a liquid refrigerant at the end of the expulsion period. In other words: During the boiling period, the actual absorption point iia is separated from the gas space of the cooker by two columns of liquid .42 and 21, one of which, 4.2, is made to tear open at the change of period, while the other, 21, corresponds to the boiled or boiled-off or . reabsorbed amounts of refrigerant fluctuates and is kept above the condensation temperature of the refrigerant vapors during the boiling period. The vessel 21 is surrounded by a thermal insulation jacket 5o. It is therefore kept at an intermediate temperature between the expulsion and cooling temperatures during the cooking periods. However, it can also with the extension of the digester performing pipeline-16 - viirmeaustauschende connection be brought. In any case, it must be kept at a temperature which is high enough, if necessary by additional heating; in order to prevent condensation of cooker vapors flowing through line 16. When the heat supply to the cooker is switched off, as mentioned, due to the automatic formation of the liquid lock 39.4o, a negative pressure occurs in line 16 and in vessel 36 because of the condensation of the vapors contained in these spaces. If the rectification arrangements, as shown, are carried out with the help of push plates 34 or insert plates 3S arranged at different heights from the height of the cooker level. They serve as storage devices for absorption solution kept below the temperature of the cooker during the cooking period , so caused by the constant cooling of these plates with the help of the outer air cooling fins, the temperature on the plates is reduced. Both from the Kocheroberflä before as the solution contained in the storage vessel different absorption solution a particularly rapid drop in pressure; cla besides condensation there is also absorption of high vapor levels on these plates, which ensure that the high vapor levels come into close contact with the solution. This pressure reduction causes Verdainpfergas entry into the circulation device i id and. As mentioned, liquid is pushed up from the vessel 41 in lines 39 and 4o, so that a liquid lock is created between the evaporator on the one hand and the digester 13, the equalizing vessel 21 and the absorption solution stored on the plates 38. On the other hand, another path is opened for the evaporator gas, namely through line 42, to the absorption solution different from the solution standing on the plates 38, namely the solution contained in the storage vessel ii. In order to ensure in the event of rapid pressure drops in the system of vessels 36, line 16 and in the digester that the liquid cannot be ejected from the liquid lock 39, .Io and runs back to the digester, the vessel 36 is firstly provided with the insert plates 38, which run back prevent the liquid to your digester, and furthermore the line .4o is connected to the vessels 36 and 41 in such a way that if the liquid seal is torn open through the line 39, the expelled liquid can flow back through the line .1o and the liquid: can be re-established.

The vessel 41, the content of which is a - permanently maintained liquid lock between the. Gas space of the expansion tank 21 and the condenser and / or evaporator its contents can either be caused by condensation coming from the stove D: inipfen received, or it is, as shown in the figure, at a height arranged, which corresponds approximately to the level line I, so <leave it with the filling the apparatus is immediately charged with solution. As can be seen, the vessel is 41 through line 18 to the evaporator, through lines 39 or .4o and line 16 -with the cooker and through pipe.I2, which doubles as a drainage pipe for the vessel 41 and, if necessary, for the automatic evaporation drainage (Line .I6, vessel 4.7 and line 48) is connected to the storage vessel. At the end of the boiling period, the evaporator gases coming through line 18 'occur, not just the solution contained in the vessel 41 in the lines 39 and 4o high, but they also push the solution in line 42 into the storage vessel i i, so that the line .42 is filled with liquid in the boiling period, in the But absorption period is gas-filled. The one pressed into the storage vessel The amount of liquid in the line 42 leads to a slight increase in the level in the Vessel 21 and in the cooker, the mirror of which is reflected in the vessel by the effect of negative pressure 36 and strive to lift in line 16. In other words: the actual absorption site iia has two connecting paths to the evaporator, one of which, IId, 42, 41, 18, during the cooling period, evaporator gas leads to the absorption site, while the other way 49, 21, 16, 36, 39, 41, 18 contains means that in the exemplary embodiment, exist in the liquid column 39. 4o, the pressure difference between the Maintain the absorption point and the vaporizer independently. Because of the open Gas connection of the vessel.2i with the cooker can be the last7.Individual connection path can also be understood as a connection between the evaporator and the cooker.

Temporary negative pressure can also arise in line i8 and in the condenser: 14. if the vapors contained therein condense. However, the pressure here can never fall below the condensation pressure of the refrigerant at the temperature prevailing in the upper part of the evaporator 15.

If the pressure in the vessel 36 and in the line 16 has dropped far enough, the evaporation occurs in the evaporator, and these vapors will tear the liquid lock from the lines .I2 and I id helcletell U-tube and into the line iid TrAen, where they act as a gas bubble pump and cause a strong circulation in the circulation system of the absorption period, into which other liquid lines than in the boiling period run, <la ini -Example the cooker content during the absorption period not part of the circulation of the solution takes. Part of the funding il; inipfe already in the leg 1 Id of the [) pipe absorbed. This absorption as well as the \ r more absorption of the Verdanipfergase in im actual absorber element i ill contained, \ 'o11 cler on the plates 38 thermally separated absorption solution causes a wide tere Drucksenkttttig ini Allparat over the through the plates 35 introduced pressure lowering hinaila. Those in the Leittingell 39 and .I0 removes the negative pressure ini Gefiil.i 36 and pressure column III 'arising in line 16 between the evaporator and the cooker at a value that is greater than the Difference in pressure between \ - 'erdanillfer and Absorption point and larger than the pressure s: iule 111, the difference between yours during the boiling period over the condenser sation temperature of the coconut vapors tten liquid level 1111 vessel 21 and the Connection of line _.12 to line I Ilt represents. In other words: the pressure ini evaporator is in the absorption periods greater than 'the pressure above the gel of the expansion tank 21. The pressure difference between. III 'and III represents the Pressure, with your the Verdanipfergase in the storage vessel or the absorber element be squeezed and the circulation of the effect sorption solution. Characteristic of the apparatus according to of the invention is, as from the above obviously that by changing the Heat supply to the allparat occur in it- the internal changes of state a displacement of columns of liquid .12. 24 39. 40 effect that during the high and Periods of absorption in different positions have while your the absorption solution of the storage vessel in both periods circulating gas in different ways. to write. As for the size dimensions of each Apharatteile angelfit, it should be mentioned that the Evaporator or evaporator plus condenser container for example 11: - Ammo niak can grasp. Accordingly, that would be Dimension of the '.-, laxative vessel like this train that it is appropriate at least contains poor solution. The vessel 21 is to be trained in such a way that e. the mirror difference of i kg of Aninlontak and the Evaporator drains automatically before the Vessel -21 is empty. The cooker is purposeful To be trained moderately so that he is about 11'l0 des Voltinicns des', contains storage vessel. Indeed can the I, 7, oclier \ -olunien in relation to food .., dlergrf; @ 1. @ unll "l'eml.eratur \ vechsler., @ :: r @ -c, kluinrr, for example "`, and even less cies Storage vessel volume included. J'e greater the difference between your volume of hocbers and the storage vessel is made uni faster the cast out and absorption periods may alternate, cla in an apparatus of the invention, both the cooking gelllüß directly with your pitching of the heater and the absorbing begins immediately after switching off the heating b & glnnt, because large amounts of poor solution at absorption temperature are already available ready for absorption when the heating is switched off. The periods can therefore only be repeated several times, e.g. B. every 1 hour, change, d.] 1. generally be of the same length, or a short cooking period of 15 minutes, for example, can be followed by an absorption period of several hours until all of the expelled refrigerant has evaporated. Such an arbitrary change in the length of the cooking periods enables simple regulation of the cooling power.

The invention is not limited to the illustrated embodiment. Any evaporator construction, any rectification device can be used as well as other known improvements of the schematic Drawing use. The storage vessel that is used during periods of absorption in the exemplary embodiment also serves as an absorber and a self-contained liquid circulation system can also be found in continuously operating apparatus. ,

Claims (1)

PATE NTAN SPRÜCFIE: I. Intermittently working absorption tion refrigeration apparatus finite in the cooking uncl Absorption periods of non-running absorption tion liquid and one constantly the Influence of an external coolant put cooling device, whose @ \ 'ürme- filling capacity for the continuation of the largest all- sorption is sufficient. 2. Absorption chiller after saying i, marked by a periodically heated stove, one-point. on which was conditioned by boiling Perform mirror fluctuations, and one thermally separated from this point Cooling point for the discharge of the absorption investment warranties. 3. Intermittently working absorbers tion refrigeration apparatus according to claim i with von etnenl ]: linen cooker separated, s ti ändh e chilled, absorption solution containing vessel: iß (storage; @ efäl3i, Vohnliell a @ "icliarhr: (1e: h () - chers is. .. absorption refrigerator according to claim 3, characterized in that the storage vessel is completely filled with liquid during the cooking periods. 5. absorption refrigeration apparatus according to claim 3 or q., Characterized in that the liquid level of the storage vessel is moved out of it and into a non-cooled vessel (compensation vessel), the content of which is suitably smaller than that of the storage vessel. 6. absorption refrigeration apparatus according to claim 5, characterized in that the liquid level of the equalizing vessel is above the condensation temperature of the refrigerant vapors during the cooking periods. Absorption refrigerator according to claim 6, characterized in that the liquid level of the equalizing vessel is greater than the liquid level of the cooker. S. absorption refrigeration apparatus according to claim 5, characterized in that the volume of the equalizing tank is approximately the same size as the evaporator or evaporator plus any condensate collecting container. G. Absorption refrigerator according to Claim S, characterized in that the volume of the expansion vessel is so large that at the end of the boiling period the contents of the evaporator overflow before the expansion vessel is empty. ok Absorption refrigeration apparatus according to claim i or one of the other preceding claims, characterized by air cooling of the heat-emitting parts. i i. A method for operating intermittently operating absorption refrigeration apparatus according to claim i, characterized in that only part of the absorption solution is heated in the boiling period, part in the absorption periods by a cooling device which is exposed to the influence of an external coolant in both periods, the heat dissipation capacity of which is used to remove the largest per The amount of absorption heat that is lost is sufficient for a unit of time, is circulated and the liquid circulating between the heating location and the cooling location changes heat during the cooking periods. 12. The method according to claim ii, characterized in that a further part of the absorption solution is kept at an intermediate temperature lying between heating and cooling temperature. 13. The method according to claim 12, characterized in that the level of the absorption solution kept at the intermediate temperature is kept at a temperature which is higher than the condensation temperature of the refrigerant vapors. 14 .. The method according to claim ii, characterized by a circulation between the periodically heated and an unheated, expediently permanently cooled part of the absorption solution, while the level of the part kept at intermediate temperature is withdrawn from circulation. 15. The method according to claim 11, 12 or 14, characterized in that the part of the solution kept at the intermediate temperature is reduced during the cooking periods by the amount of the refrigerant liquefied in the condenser. 16. The method according to any one of the preceding claims, characterized in that the level of the absorption solution kept at the intermediate temperature is brought into connection with your gas space of the cooker. 17. The method according to any one of the preceding claims, characterized in that the level of the absorption solution kept at intermediate temperature is withdrawn by suitable arrangement or devices SWiniing movements.