DE661751C - Periodic absorption refrigeration machine - Google Patents

Description

Periodic Absorption Chiller Present Invention refers to automatic, periodically operating absorption chillers that due to the internal processes during the cooking or cooling period shift and thereby perform tilting movements.

In order to achieve the greatest possible tilting power with these cooling devices, an embodiment has become known in which the absorption liquid by boiling or is relocated by decanting into two separate containers. Here one serves as a storage container and the other as an absorber. There are here two containers corresponding to the total amount of liquid required.

It has also become known for refrigerators that do not tilt automatically, not to cool the stove during the cooling period and continue to exchange heat to be provided during the transfer of the liquid. This arrangement also requires a greater amount of building materials, in addition, the heat exchange is only inadequate, as it is only present during the transfer period. It is further known at to arrange cycles of the absorption liquid in periodically operating cooling devices, which are in the cooking period between the cooker and the storage container and in the Play the cooling period between the reservoir and an absorption point. Complicated lines in connection with water locks are required here. In addition, the absorption point must be designed accordingly for discharge the heat of absorption required. It is also known the condenser as an absorber to use, including a circuit of absorption liquid between the condenser, the cooker, the temperature changer and the storage tank. The heat contained in the cooker and in the temperature changer does not only go here lost, but it must also be carried away.

To compensate for the 'degassing of the absorption liquid In known designs, reducing the volume is a special expansion tank has been proposed. It has also become known the withdrawing ones to cool hot cooker vapors by passing them through the absorption liquid be passed through. Here, however, the liquid is swirled around, so that cooling can only take place inadequately.

The object of the invention is, inter alia, to remedy these shortcomings to eliminate and the arrangements known by their nature in non-tilting apparatus to be transferred to an automatically working, tilting movements executing cooling device and to increase the efficiency with a lower cost of building materials.

The tilting movements are used to control the internal processes, which the condensate, refrigerant vapor and absorption liquid by change the gradient in the condenser or by changing the level of the connecting lines guide in the required direction. During the cooling period, the Absorption liquid between the reservoir and the condenser so between always cold parts. The circulation here is caused by the rising refrigerant vapor operated.

A high tilting power for the cooling device without additional effort for you special container is achieved that the refrigerant between the in countercurrent working cooker and the collecting tank for the refrigerant is relocated and that the cooker and the collecting container are as far away from the center of gravity as possible are arranged. To prevent the collecting container from icing up, the function of the device is adversely affected, the collecting container is provided with thermal protection and arranged outside the refrigerator.

By the arrangement and the choice of the size of the counterflow cooker the use of a special expansion tank is also superfluous. The upheaval the absorption liquid in the boiling period takes place without any special pumping device by the boiling of the absorption liquid and by the various specific Weight, as there is only a small difference in height to be overcome during the cooking period is. The circulation is also regulated by the degree of degassing.

The invention is shown in Figs. Fig. I shows this Refrigerator in the cooking period, while Fig. 2 shows the position in the cooling period. These figures show the circulation of the absorption liquid and the refrigerant vapor.

Fig. 3 and 5 show sections through the horizontal cooker with the assembled temperature changers that make up the circulation and the heat exchange can be seen. Fig.q. shows the spatial arrangement of the individual liquid containers of the cooling unit, based on the tilting axis. The illustrations show versions in an exemplary arrangement. An example of the absorption liquid is water and ammonia is provided as the refrigerant.

The degassing of the absorption liquid according to Fig. I takes place in the digester i. The cooker x is connected to the temperature changer 29 in a thermally conductive manner and with combined with him in a common container so that he works as a countercurrent cooker. By using a countercurrent cooker, which in this example is a horizontal, If the container is heated on one side, the greatest possible utilization is made the withdrawn heating gases reach a lower temperature when an open heating flame serves as a heat source, e.g. B. Gas heating. The use of a countercurrent cooker allows a high degree of degassing even without deterioration of the efficiency, because the co-evaporated absorption liquid has its heat of evaporation in the countercurrent part of the stove returns. At the beginning of the cooking process, some ammonia vapor condenses in the downstream part of the cooker. The lighter condensate remains on the surface and heats the surface of the liquid as well as the part free of liquid of the countercurrent cooker. Little by little, the temperature will be equal to the floor out and assumes higher values. The evacuating cooker vapors are in the borderline case in equilibrium with the vapor tension of the incoming saturated solution. Around The storage container also needs to be preheated for this borderline case fo designed as a temperature changer in the upper part. It is used for electrical heating the part 29 of the countercurrent cooker that adjoins the hotplate predominantly as Temperature changer.

The circulation of the liquid is caused by the boiling. Of the expelled refrigerant vapor flows through the horizontal one, which is divided into chambers Countercurrent cooker, where it gives off its heat to the rich absorption liquid. The absorption liquid that is evaporated and entrained is passed through the partition walls deposited and the heat contained in it also in the temperature changer 29 delivered to the rich solution. The cooled ammonia vapor passes through the Tube 2 into the absorber condenser 3. In tube 2, the steam cools down to its Condensation temperature, the rest of the evaporated liquid separates from here and flows back into the countercurrent boiler and arrives from here with the inflowing suffice absorption solution to the hotplate., The condensate runs out of the condenser 3 via the U-tube q. into the collecting container 5 and from this into the evaporator fi. By the Expelling the refrigerant in the countercurrent cooker and the The accumulation of condensate in the collecting tank 5 shifts the focus of the Cooling device that can be pivoted about axis 6. Having expelled so much ammonia which corresponds to the amount of refrigerant according to the contents of the counterflow cooker, the device tilts to the other side. The tilting movement is known in Way turned off the heating. According to Fig. 2, now step through the bent pipe 7 the cold poor absorption liquid in the knee 8 of the U-tube q ..

As soon as the temperature in the absorber capacitor 3 decreases by a small amount has fallen, a negative pressure is created in the absorber condenser 3. The still warm refrigerant in the collecting container 5 initially begins to evaporate and this is expressed in the U-tube Liquefied refrigerant located in the top of the absorber condenser 3, here runs it to the other side through the pipe 9 into the reservoir io. From the reservoir new poor cold absorption liquid flows from the floor, that of the refrigerant vapor is also pressed into the absorber capacitor 3 through which it flows. Here the poor liquid absorbs the refrigerant vapor and gives the absorption heat to the absorber capacitor 3, which now takes over the function of the absorber Has. The rich absorption liquid which forms during absorption flows through the pipe 9 back into the storage container ok. As soon as the collecting container 5 by the evaporation of the refrigerant has assumed the temperature of the cold room, evaporation stops here on. The evaporation now takes place in the evaporator ii, and the refrigeration is initiated.

The vapors from the evaporator ii reach the collecting container 5 and push the poor solution at the knee 8 into the absorber condenser 3, where it absorbs will. The condensate from the collecting container 5 flows in the same way as in the evaporator forming vapor in the evaporator ii down, so that the amount of refrigerant in the collector 5 becomes smaller and smaller until the gradually from the reservoir io Rich solution flowing into the counter-current cooker 29 because of its excess weight the device swings over from the cooling period according to Fig. 2 to the heating period according to Fig. i. The game then starts all over again.

The water remaining in the evaporator n increases during the boiling period when filling the collecting tank 5 with new refrigerant in the drainage line 12 and accumulates in extension 13. The condensation of ammonia vapor in the upper part of the pipe 1q. is made by isolating it during the cooking section prevented, so that there is no refrigerant on the rising liquid residue piles up. During the cooling period, the thermal protection 15 of the pipe 1q. and of the intermediate container 13 completely or partially lifted by the tilting movement, so that these parts are exposed to the outside temperature. Under this elevated temperature based on the temperature of the refrigerator, steam will form in the residue, which promotes him in the absorber capacitor 3. In order to have as little resistance as possible Pipeline 1q is to enable the residue to be recirculated. according to fig. i and a have been fed directly into the absorber capacitor 3. The pipeline 1q. can also be passed into the connecting pipe 9 in the same curved manner be, and expediently at such a height that the confluence in the boiling period below the liquid level, so that no condensation of ammonia vapor in pipe 1q. is possible.

A simple adjustment of the thermal protection 15 is made possible by that the exposure of the parts can be regulated. The exposure is expedient so far made that the intermediate container 13 assumes a temperature that is not too is well below the outside temperature so that the refrigerant does not evaporate unused.

It is advisable to tip out of the cooling period before the Collection container 5 has completely emptied. This causes condensation of the refrigerant vapor prevented in the evaporator at the beginning of the cooking period.

To adjust the cooling capacity to the prevailing outside temperature To enable an additional switching element 16 is provided in the form of a two-metal strip. When the outside temperature rises, the strip bends a little upwards, and the switchover occurs earlier. The deflection of the bimetal strip. is sized so that they only takes effect on part of the way, causing the device to stop between the two endpoints is avoided. This results in a greater cooling capacity achieved, as the absorption is much faster at the beginning than at the Enough.

For greater cooling requirements, for example for making ice, a adjustable stop 17 is provided with which an earlier reset from the Cooling period is adjustable.

About the tearing up of the refrigerant from the collecting tank when it is opened of the refrigerator due to the stronger evaporation that occurs in the upper part of the collecting container 5 and in the exhaust pipe obstacles i9 in the form of perforated plates o. The like. Arranged.

The circulation of the liquid during the Boiling period is expediently dependent on the degree of degassing, so that the expenditure of heat as possible becomes low. A measure of the degassing is the temperature of the liquid or the specific gravity of the same.

When heating the temperature for circulation becomes a facility provided according to Fig. 3 and 5. This facility consists essentially of one small impeller 2o. The lower end of the axle is barbed and is in a container 2i, which is filled with a neutral melt is. The melting temperature corresponds to the desired degassing temperature. Has the liquid reaches the melting temperature, then the mass melts, and that The impeller can start moving if the liquid counteracts it while boiling pushes the wings. The liquid can now into the upper opening 22 of the drain line 23 arrive and flows off after the reservoir io.

The specific gravity is used to control the fluid circulation is used, then a specific gravity-matched float 24 is used in the Arranged drain line. The float, which does not close completely, steers in Depending on the specific weight, the opening of the drain line. The degassed, Specifically heavier solution remains at the bottom of the storage container and flows through it the distributor disc 25 slowly, according to the inflow amount evenly upwards, until the entire content is circulated.

The drain line 23 is in the 29 serving as a temperature changer Part of the countercurrent cooker and in the upper part of the storage container io with cooling fins 26 provided so that the degassed liquid, the liquid heat to the after Can give off flowing saturated absorption solution. Through the cooling fins 26 the countercurrent cooker is divided into individual chambers. The individual cooling fins have passage openings which are arranged so that the incoming absorption liquid is guided in a zigzag to the hotplate.

The counter-current cooker i, 29 is just as big in terms of its content as the collecting tank 5 for the refrigerant. As the degassing progresses, the Contents of the countercurrent cooker always lower, because the inflow due to the altitude of the Inflow line 28 is limited until it empties almost completely to Scbluß. The temperature of the stove will now rise slightly, and the time for the tilting movement came out of the cooking position. So that the tilting movement does not occur before emptying of the countercurrent cooker takes place, a thermal locking member 27 is attached to it, only when the countercurrent cooker has reached a certain temperature does the tilting movement releases. This ensures that all of the heat supplied except for the is exploited contained in the components of the countercurrent cooker. In the pictures the thermal member consists of a ratchet wheel 27, which with its pivot in stored in a solder container and in the cooking position with a fixed pawl is latched. The solder pot is attached to the cooker and takes the temperature of the cooker at the attachment point. The solder prevents them when cold Rotation of the ratchet wheel. When a certain temperature is reached, the solder melts, the ratchet wheel can move under the influence of the excess weight of the collecting container 5 turn, the anchoring of the cooling device is lifted and the tilting movement can now take place.

In order to reduce the heat losses even further, there is a counter-current cooker The upper part of the storage container is also provided with heat protection.

The countercurrent cooker i, 29 fills up during the cooling period the increase in volume of the absorption liquid gradually with liquid. Of the Degree of saturation of the absorption liquid at the end of the cooling period is located in the countercurrent cooker depends on the temperature of the appliance part has assumed during the cooling period due to the cooling that has occurred. After the Tilt it to the cooking position and gasification begins after switching on the heating without delay.

As Fig. 4 shows, the cooker i is as far as possible from the collecting container 5 arranged remotely so that the greatest possible tilting force is achieved.

Claims (16)

PATENT CLAIMS: i. Periodic absorption chiller, which shifts its center of gravity by relocating the refrigerant and thereby tilting movements executes and their cooker with a storage container in constantly open fluid connection stands, characterized in that the tilting movements take place so that during the Cooking period, the condensate flows in a collecting container (5) and that during the Cooling period through the rising refrigerant vapor a cycle of the absorption liquid between the condenser, which now acts as an absorber, and the storage container (= o) is effected. 2. Absorption refrigeration machine according to claim i, characterized in that that the temperature changer (29) wholly or partially with the cooker (i) in one common container is housed and that both parts - thermally conductive to one Countercurrent cookers are combined. 3. Absorption chiller after Claim i and 2, characterized in that the countercurrent cooker consists of a one-sided heated, horizontally arranged, tubular container divided into chambers consists in which the expelled hot vapor mixture and the degassed hot absorption liquid in countercurrent to the cold rich solution. ¢. Absorption chiller according to claim i to 3, characterized in that the collecting container and the Countercurrent cookers are arranged as far away from the pivot point as possible. 5. Absorption chiller according to claim i to ¢, characterized in that the circulation of the liquid between Countercurrent cooker and storage container during the cooking period depending on the temperature or the specific gravity of the degassed absorption liquid is regulated. 6. absorption refrigeration machine according to claim = to 5, characterized in that that the tilting movement at the end of the cooking period apart from the repositioning of the center of gravity also depends on the temperature of the cooker. 7. Absorption chiller after Claims i to 6, characterized in that the tilting movement at the end of the cooling period takes place before the evaporator begins to be emptied. B. Absorption chiller according to claim i to 7, characterized in that the drainage line of the Evaporator leads directly into the absorber condenser. 9. Absorption chiller according to claim i to 8, characterized in that the drainage line in the height of the collecting tank for the refrigerant is expanded like a container. = o. Absorption refrigeration machine according to Claims i to 9, characterized in that the During the cooking period, the drainage pipe was completely insulated during the cooling period or is partially exposed to the outside temperature. = i. Absorption chiller according to claims i to io, characterized in that the exposure of the drainage line can be regulated by the thermal insulation during the cooling period. i2. Absorption chiller according to claims i to ii, characterized in that the time of the tilting movement can be adjusted at the end of the cooling period by changing the center of gravity. 13. absorption refrigerator according to claim i to 12, characterized in that the time of the tilting movement at the end of the cooling period from the outside temperature being affected. = q .. Absorption refrigeration machine according to claims x to 1,3, characterized characterized in that the container for the refrigerant according to the content as well big is like. the countercurrent cooker. 15. Absorption chiller according to claim i to 1q., characterized in that the line for the return of the hot Absorption liquid in the temperature changer of the countercurrent boiler and in the upper one Part of the storage space is provided with cooling fins. 16. Absorption chiller according to claims i to 15, characterized in that the upper part of the storage container (= o) is carried out isolated for the absorption liquid.