DE629736C - Refrigerator with an absorption device - Google Patents

Description

Refrigerator with an absorption apparatus The invention relates to. themselves on refrigerators that are cooled by a refrigeration device with pressure equalizing Auxiliary gas works without gas circulation. Such refrigerators without moving parts, in which the liquefied refrigerant in an essentially dormant indifferent Gas vaporized into it are already known. It is also already known in apparatus in which an auxiliary gas circulates between separate evaporation and absorption vessels, to let the refrigerant evaporate in several evaporation stages and thereby resulting useful cold at different temperatures for different cooling purposes use. It is finally known for heat transfer evaporation and condensation systems to use. The invention combines the known arrangements and makes it possible as a result, in refrigerators working with pressure-equalizing gas, in which the Auxiliary gas remains stationary, different evaporator temperatures for different cooling purposes to make usable.

The invention solves this problem by being in or on the evaporator absorber opposite the absorption surface, which is wetted by the circulating absorption solution is arranged several thermally separated evaporators or evaporator surfaces due to the different partial pressure gradient between the absorption surface and the opposite evaporator surface set different temperatures, the cooling points assigned to the evaporators or the evaporator surfaces are transferred and thus can be used for various cooling purposes. .

The invention will be described in more detail with reference to the accompanying drawings are described, with further characterizing features of the invention will. Figs. I and 2 show different embodiments of the cold transfer different temperatures from a common evaporation and absorption vessel on a refrigerator.

Fig. 3 shows part of such a system.

In Fig. I, io denotes the insulation of a refrigerator Dimension. With i i is a known evaporation and condensation system refers to the one end in a particularly cold part of the refrigerator 27 protrudes where it is for the purpose of better heat transfer with cooling flanges 12 is provided. That part of the element that is inside the refrigerator insulation lies essentially horizontally, so that in the evaporation and condensation system contained liquid, e.g. B. ammonia or the like, if possible the entire length of the wall touches this part, but at the same time also on the whole length of the cross-section has an air space above it, - * ag # which facilitates damping.

In order to keep the liquid in the most favorable position, ih the system ii expediently with a kink 13 in an oblique direction upwards through the insulation io of the refrigerator led. The system i i is then outside the refrigerator Curved vertically upwards and on its outer walls with a spiral circumferential Volume 14 or the like provided.

This part of the system ii, which acts as a condenser for the inside Evaporation and condensation system is used, serves with its outer wall at the same time than the evaporator of the refrigerator. It occurs in a manner known per se a conduit 15 condensate on the spiral tape 14, which is inside the container 16, which also serves as the absorber of the apparatus, comes to evaporation. The absorber 16 is also on its inner walls with a spiral band o. The like. 17 provided, on which the absorption solution -in a known manner by a Line 18 is pumped. The poor solution coming from the cooker trickles down the spiral Volume 17 downwards, accumulating, and passes through a line i9 from lower part of the absorber 16 back to the cooker, where it is restored in a known manner is degassed. The outer wall of the absorber 16 is equipped with any cooling device, for example with a cooling spiral 24, into which cooling water at 25 and from which it exits at 26. But the dissipation of the absorption heat can also be done through Air cooling flanges or a special evaporation and condensation system take place. The latter is particularly useful if you have ventilation ducts or the like. has a stronger air circulation. can be generated than this at the embodiment shown in Fig. i is the case: To avoid heat losses from the cold Part of the evaporator ir to prevent the outside air, is the one between the absorber r6 and the inner cupboard part of the system i i. expediently by a Insulation out and the absorber wall, as shown at 22, drawn in in a bead shape. In the absorption vessel-16 there is one second in the direction of the flow of the absorption solution the system: i i appropriate evaporation and condensation system arranged, whose parts are provided with the index a. The lowest point of the inside of the Absorbers. 16 located part of the ir system is expedient with a top, eaves o. The like. 28 provided, from the liquid refrigerant, -das on the spiral band 14 not, has evaporated, .. on the second element ija and its ribbon: spiral 149 can drip. Since the tape spiral 14 opposite along the absorber wall running absorption solution still very poor. is, is in the space between these two Apparatus parts, the pressure gradient of the refrigerant is particularly large, so that a very strong evaporation from the tape spiral 14 takes place. As a result, the part of the system i i covered with this spiral band 14 has a very low temperature, so that the liquid contained in the part of the system i i located inside the cabinet comes to the boil very much, which means that the cupboard compartment 27 quickly and a lot of heat is withdrawn. The closet compartment 27 is therefore particularly suitable for the production of Ice or the like. Suitable. Naturally, the part located in the interior of the compartment 27 can of the system i i instead of, as shown, with cooling fins 12 also with devices for making ice, for example with a cast block made of aluminum or the like, for recording of boxes for making ice ". The item iia, on the excess If refrigerant drips down from the element i i, it becomes higher when it evaporates Temperature, since the running down on the opposite walls of the absorber 16 Solution, has already become richer, so that the partial pressure gradient between the two Walls has become smaller. The liquid contained inside the system i ia therefore boils less strongly, so that the part i yes located inside the cupboard a higher temperature than the corresponding part of the system i i assumes. Appropriate is to make the element iia larger than that essentially used for ice making serving element i i. One wants to prevent with certainty that oneself in the closet is undesirable Form low temperatures, this can also be achieved by, for example fills an inert gas into the element iia, thereby increasing the boiling point of the Determine the liquid contained in the system .ja more precisely. The absorber 16 is cooled in the exemplary embodiment by a cooling coil 24 and by insulation 21 closed off from the outside air.

About the transfer of heat from the warm absorber wall to the cold one To complicate the evaporator wall, it is useful to turn the warm facing each other and to make cold surfaces out of reflective material. When using water as an absorbent and ammonia as a refrigerant, for example stainless steel into consideration. But other materials can also be used, for example reflective aluminum, bare copper or the like, use Find, depending on the choice of substances used in the refrigerator.

The distance between the cold evaporator wall i i and the warm one Wall of the absorber 16 is suitably small. Made to the diffusion of the evaporating To facilitate refrigerant after the absorption surfaces. It is also advantageous the pressure in the apparatus, for example by choosing suitable operating media, if possible to keep low and accordingly also the admixture of the inert gas very low. Well known is the thermal conductivity and diffusion of stationary gases constant up to a certain lower limit. below this Above all, the diffusibility increases significantly at the limit. It is therefore advantageous to make the admixture of the inert gas so low that the Partial pressure of the gas below this limit of constancy for thermal conductivity and the diffusion lies, d. H. that the partial pressure of the auxiliary gas is less than about 5 mm of mercury pressure.

In these circumstances it will generally be superfluous introduce a special auxiliary gas into the apparatus. Will this before the filling evacuated, a certain amount of gas remains in the apparatus. After loading of the apparatus with the absorption and the refrigerant also occur in general minor decomposition of the equipment (e.g. when using ammonia a breakdown of some molecules into nitrogen and hydrogen). The one in the evacuation Remaining gas residue as well as any decomposition products of the operating resources are are generally sufficient to supply the necessary auxiliary gas. To prevent that oxygen remains during evacuation, it can be useful to use the apparatus After the first evacuation, fill it with nitrogen or hydrogen to evacuate this filling again and only then to charge with the operating resources. When using a higher partial pressure of the auxiliary gas is because of the good Diffusion properties best used hydrogen.

Especially when the apparatus is working at low pressures, it is It is important to use an absorbent that has a low vapor pressure, d. H. has a high boiling point. Because it is to be avoided that at the low Pressure in the 'evaporator and absorber absorbent from the walls of the absorber evaporated, condensed on the cold evaporator part and here the liquid refrigerant binds. In such cases, for example, paraffin oil has proven itself as an absorbent and toluene as refrigerant or fusel oil as absorbent and ethyl chloride as Refrigerants proved to be particularly advantageous.

In Fig. 2 an embodiment is shown in which the cold from the evaporator instead of through an evaporation and condensation system through an air circulation system is transferred to the cabinet contents. Identical reference symbols have the same Meaning as in Fig. I.

Deviating from Fig. I is the evaporator part of the system, which is again equipped with a spiral band 1q. is provided, on which the condensate or, in the case of resorption machines, the rich evaporator solution runs from the line 15, connected to the air in the refrigerator chamber 27 by two connecting pipes 23. The air standing in the evaporator part becomes heavier as a result of the cooling and thereby comes into circulation, with the entire air contained in the compartment 27 gradually having to cool down strongly. It is useful to let the upper line 23 open high on the cabinet ceiling. The lower cooling system is connected to the main room of the refrigerator by line 23a and cools it in a corresponding manner.

The invention is not the same as in the previous figure limited to the side storage of the evaporator absorber on the cabinet, but the evaporator absorber system can be installed above the cabinet, for example will. If necessary, a special ventilation device can also be installed in the Inside the refrigerator or on one of the lines 23. This is particularly useful if; the inner evaporator part, for example, with Air fins are provided to better transfer the heat of the air passing through it to be transferred to the cold evaporator wall.

In Fig. 3 a part of the absorber is in the lower cooling system i i11 shown. The absorption vessel 16 is at his in this embodiment lower end 22 beaded to make way for the warmth from the warm Extend the absorber wall to the cold evaporator wall and thereby the heat transfer to reduce. This bead-like connection 22, which is also used in the aforementioned forms of representation can be used, is in Fig. 3 down to the cabinet insulation io pulled down. Apart from the fact that the heat exchange between the two surfaces thereby is reduced, at the same time the insulation provided in Fig. i -i this Part of the system ii can be saved. However, this requires the lower To form part of the absorber in a cup-shaped manner, as shown at 35, so that the solution dripping down on the absorber wall settles in the bead-shaped cup 35 catches and is discharged through line i9. I3`enn it is convenient to use the room between the element i i and the one here, as it were, designed as a jacket tube To have bead 22 filled with gas, since the gas standing between the walls is less Transfers heat like the absorbent solution would. Naturally, however, must A drainage line 36 is provided at the lowest point of this casing pipe that drains after any part of the refrigeration system. The upper Connection between the warm absorber wall 16 and the cold evaporator wall can be carried out in a corresponding manner. Here, too, the appropriately drafted Absorber wall the walls of the system i i with an elongated but narrow Cover the gas layer.

Both the evaporator and the absorber wall of the above embodiment Instead of the spiral strip shown, it can also be used with porous ones that conduct heat well Fabrics, such as wire gauze or the like, clothed or with capillary action Corrugations or the like, which ensure that the walls are moistened. Instead of the spiral band, a plurality of cells can also be attached to the corresponding Walls be provided, of which the resources by overflows from one Drip the plate down to the next lower plate.

The refrigeration apparatus itself can be used as a refrigeration apparatus in any known manner be designed without moving parts, e.g. B. according to the known methods of Gep p er t, P 1 a t en-Munter; Siemens o. The like. It is also not necessary that the evaporation and condensation system directly represents the evaporator wall. It is also possible to have such an element in the interior of the illustrated evaporator-absorber body use and, for example, by soldering or the like. Thermally conductive with the inner To connect evaporator wall.

The refrigeration apparatus can also work with condensation of the refrigerant or let the refrigerant evaporate from a resorption solution.

The evaporator and absorber walls can finally find their position in relation to one another change so that the absorber part is inside and the evaporator part is outside, with then the condensation part of the evaporation and condensation system i i the evaporator of the apparatus encloses.

To increase the effective absorption area of the absorber part, you can provide special insert walls inside the absorber, over which the same absorption solution seeps down in a manner known per se. These walls can for example consist of wire gauze or be covered with wire gauze, this wire gauze For example, they can simply be hung in the uppermost groove of the spiral tape 17 can.

Claims (3)

PATENT CLAIMS: i. Refrigerator with an absorption chiller without moving parts, in which the refrigerant is converted into an immobile, inert gas Diffused ih an evaporator-absorber, characterized in that in or on the evaporator absorber opposite the absorption surface, which is from the circulating Absorbent solution is wetted ", several thermally separated evaporators or evaporator surfaces are arranged, where due to the different partial pressure gradient between the absorption surface and the opposite evaporator surface have different temperatures set the refrigeration points assigned to the evaporators or the evaporator surfaces can be transferred and thus made usable for various cooling purposes. 2. Fridge according to claim i, characterized in that the evaporator-absorber has several evaporator parts contains, which are designed in the form of a tube, through the interior of which the cabinet air circulates. 3. Refrigerator according to claim i, characterized in that the cold from the evaporator parts is transferred to the inside of the cabinet by known evaporation and condensation systems. q .. Refrigerator according to claim 3, characterized in that a system for making ice or freezing purposes and another system for keeping the cabinet air cold is used. 5. A refrigerator according to claim 3, characterized in that the part of the evaporation and condensation system lying within the cabinet insulation is essentially horizontal and the part of the system cooled by the evaporator is arranged essentially vertically. 6. Refrigerator according to claim 3 or q., Characterized in that part of the evaporation and condensation system is designed with its outer wall as an evaporator of the refrigeration apparatus. 7. A refrigerator according to claim i, characterized in that the heat from the absorber wall of the evaporator-absorber is continued by a special evaporation and condensation system known per se. B. A refrigerator according to claim 3, characterized in that the part of the evaporation and condensation system lying between the evaporator part and the inside of the cabinet is covered with an insulating layer. 9. A refrigerator according to claim i, characterized in that a connection (22, 35) is switched on between the warm absorber wall and the cold evaporator wall passing through it, which connection represents a resistance for the conduction of heat. i o. Refrigerator according to claims 7 and 9, characterized in that the connection between the absorber and evaporator walls includes a heat-insulating gas cushion. i i. Refrigerator according to claim i, characterized in that the mutually facing walls of the evaporator part and the absorber part of the evaporator-absorber are designed to be reflective. 12. A refrigerator according to claim 2, characterized by a ventilation device which pushes the cabinet air through the evaporator part of the evaporator-absorber. 13. A refrigerator according to claim 12, characterized in that the interior of the evaporator part is provided with cooling fins for the air flowing in front. 1q .. Refrigerator according to claim 3, characterized in that the higher-lying evaporator part of the evaporator-absorber is provided with a drip device o. 1 5. Refrigerator according to claim q., Characterized in that the warmer transmission system contains an admixture of inert gas. 16. A refrigerator according to: claim io, characterized in that the evaporator-absorber is extended downwards and that it has a ring above this extension, vulst for discharging the rich solution. 17- refrigerator according to claim 16, characterized in that the jacket space created by the extension of the evaporator-absorber is provided with a drainage pipe. 18. A refrigerator according to claim 3, characterized in that the condensation part of the evaporation and condensation system encloses the evaporator part of the evaporator-absorber.