EP0651214A1 - Cooling or freezing apparatus - Google Patents

Abstract

A cooling or freezing apparatus is provided with a flat or plate-shaped evaporator (5) which is arranged in a housing wall (1) which delimits a cooling space (20) and is provided with a heat insulation (4). In order to be able to cool the cooling space (20) sufficiently even when the power supply of the compressor is temporarily interrupted, a cold store (6) is arranged on the side of the evaporator (5) facing away from the cooling space. <IMAGE>

Description

The invention relates to a refrigerator or freezer with a planar or plate-shaped evaporator arranged in a housing wall delimiting a cooling space and provided with thermal insulation.

Refrigerators and freezers of this type are known in different embodiments. In these, the evaporator, which can consist of a double-walled circuit board with embossed channels and cavities, is foamed behind a housing wall consisting of a plastic plate.

Conventional refrigerators or freezers can only be cooled when the evaporator is in operation, i.e. a sufficient amount of evaporable coolant is supplied to it. There is now also a need to provide refrigerators or freezers with sufficient cooling capacity if the evaporator is temporarily not supplied with coolant due to a power failure or for other reasons.

The object of the invention is therefore to provide a refrigerator or freezer whose cooling space is sufficiently cooled even when the power supply to the compressor is temporarily interrupted or the compressor is not operated for other reasons shall be.

According to the invention, this object is achieved in a refrigerator or freezer of the generic type in that a cold store is arranged on the side of the evaporator facing away from the refrigerator. The cold storage device provided according to the invention is a space which is in heat-conducting connection with the evaporator and which is filled with a medium which is able to absorb and store a large amount of heat. This medium can be a eutectic sole, for example. Heat stores of this type are known, for example, in the case of so-called "cold accumulators" which are inserted in cool boxes. During the operation of the evaporator, heat is extracted from the cold or heat accumulator, so that because of the periods in which the evaporator is not in operation, it can extract a large amount of heat from the refrigerator, so that it is kept at the desired low temperature level for a long time can be. Because of its great heat absorption capacity, the cold storage device according to the invention can also be referred to as "latent heat storage device". The cold or heat storage is known per se, so that its detailed description can be dispensed with.

The refrigerator or freezer equipped with the cold store according to the invention is able to maintain a sufficiently low temperature over a longer bridging period in the event of a power failure of the device in the refrigerator. The device according to the invention is therefore suitable for photovoltaically operated devices in which the operation of the compressor is ensured only because of the time of day.

The device according to the invention can also be used, for example, in hotel operations in which noises caused by compressors are undesirable during the night. Conversely it is also possible to charge the cold storage with cheaper night-time electricity so that the compressor does not have to be operated at all during the day or only for shorter times.

However, if the cold store is directly coupled to the evaporator, it is connected to the evaporator in such a way that the heat-storing medium of the cold store is only separated from the evaporator by a good heat-conducting wall. Difficulties arise in defrosting the evaporator because of defrosting is only possible if the cold storage is also emptied, ie has absorbed so much heat that the evaporator can warm up to temperatures above zero degrees. Furthermore, flexible and fast temperature control is not possible if the evaporator is directly connected to the cold storage.

The invention is therefore based on the further object of allowing defrosting of the evaporator and flexible temperature control, if necessary, despite the arrangement of a cold store.

According to the invention, this object is achieved in a refrigerator or freezer with the features of claim 1 in that the cold store is separated from the evaporator by a gap which, if necessary, can be filled and emptied with a highly heat-conducting liquid. This embodiment of the refrigerator or freezer according to the invention makes it possible to inactivate the cold storage at any time by withdrawing the heat-conducting liquid from the gap, so that it forms a good heat-conducting layer between the evaporator and the cold storage. If the evaporator is isolated from the cold store by the gap, the evaporator can be defrosted by interrupting the supply of refrigerant. Furthermore, the temperature in the cooling space can be essentially unaffected by conventional control of the supply of refrigerant to the evaporator control from the cold storage in the desired manner. As the cold storage can be extracted from the evaporator more quickly from the evaporator when the cold storage is disconnected, the cooling compartment can also be cooled down faster if necessary.

The gap between the evaporator and the cold store can be formed by a flat container, the walls of which consist of a good heat-conducting material. The gap can also be formed directly by walls of the plate-shaped evaporator and a wall of the container that holds the medium of the cold store, a circumferential, narrow wall, which can be made of plastic and / or a suitable sealing material, having to be provided between the two walls.

In order to allow filling and emptying of the gap or of the flat container with a good heat-conducting liquid in a simple manner, a liquid-holding reservoir is provided, which is connected to the flat container by lines in which at least one valve and a pump are arranged connected is.

In a further embodiment of the invention it is provided that the flat container is divided into sections by at least one narrow intermediate wall, each of which can be filled and emptied with the liquid. In this way, for example, a partial defrosting of the evaporator is possible if the cooling of the cooling space is not to be completely interrupted during the defrosting.

Finally, it is also possible to arrange at least a part of the evaporator directly in the cold store if it is desired to remove the necessary amount of heat from it immediately and very quickly.

Fig. 1

einen Schnitt durch eine Wandung eines Kühl- oder Gefriergeräts in schematischer Darstellung, bei dem sich der Kältespeicher in unmittelbarer wärmeleitender Berührung mit dem Verdampfer befindet,

Fig. 2

einen Schnitt durch Wandungen eines Kühl- oder Gefriergeräts in schematischer Darstellung, bei dem sich zwischen dem Kältespeicher und dem Verdampfer ein Spalt befindet, der sich nach Bedarf mit einer wärmeleitenden Flüssigkeit füllen läßt, und

Fig. 3

eine schematische Vorderansicht des den Spalt bildenden Behälters, der durch eine Zwischenwand in Abschnitte unterteilt ist.

Embodiments of the invention are explained below with reference to the drawing. In this shows

Fig. 1

2 shows a section through a wall of a refrigerator or freezer in a schematic representation, in which the cold store is in direct heat-conducting contact with the evaporator,

Fig. 2

a section through walls of a refrigerator or freezer in a schematic representation, in which there is a gap between the cold storage and the evaporator, which can be filled with a heat-conducting liquid as required, and

Fig. 3

is a schematic front view of the container forming the gap, which is divided into sections by an intermediate wall.

1, the wall 1 of the housing of the refrigerator or freezer is formed by an inner shell 2, which may be made of plastic, and an outer wall 3, for example made of sheet metal, the space between the plate-shaped walls 2 , 3 is foamed with an insulating plastic 4. A plate-shaped evaporator 5 is arranged immediately behind the inner shell or wall 2. This usually consists of an evaporator board. It could of course also consist of coils arranged in one plane. A cold store (latent heat store) is arranged immediately behind the evaporator 5 and extends essentially over the width of the evaporator. This cold storage 6 is also a flat container of suitable thickness, which holds the medium with good heat storage Record properties, the container is in direct contact with the evaporator in the manner shown.

In the embodiment according to FIG. 2, a gap-shaped space 7 is provided between the flat evaporator 5 and the cold storage 6, which can be filled with a highly thermally conductive liquid 8 as required. This heat-conducting liquid 8 can be stored in a storage container 9, which is also foamed into a wall of the device above the evaporator 5. The storage container 9 is connected to the gap-shaped space 7 via a line 11 in which a solenoid valve 10 is arranged. In order to be able to return the liquid from the gap-shaped space 7 back into the storage container 9, a return line 12 is provided, in which a pump 13 is arranged. In addition, vents of the usual type are provided in order to be able to fill and empty the gap-shaped space 7 with liquid 8, if necessary.

By a suitable control of the valves and the pump, a heat-conducting connection between the cold store 6 and the evaporator 5 can thus be established in the desired manner and this can also be canceled.

In the exemplary embodiment according to FIG. 3, the flat container 15 forming the gap-shaped space 7 is divided into two container sections 17, 18 by a vertical partition wall 16. The container sections 17, 18 are connected to one another and to the inflow and outflow lines, so that the sections 17, 18 can be filled and emptied independently of one another.

The descriptions of the three arrangements in addition to Figures 1 to 3 are part of the description.

Application and purpose:

The purpose of the arrangement of a cooling system with latent heat storage is to operate a cooling device even when a continuous power supply to the device cannot be guaranteed or the operation of the cooling unit is to be limited to certain periods. In the case of a purely photovoltaically operated device, the charge during the day, i.e. H. cooled latent heat storage, ensure adequate cooling for the night. For hotel operations, devices would be conceivable that are only in operation at the time when the refrigeration unit is not disturbing. Furthermore, the operation of the devices with night power would be conceivable.

Arrangement according to FIG. 1:

Evaporator coupled directly to the latent heat storage. Problem: defrosting is not possible without the memory being completely empty. The device is cooled until the memory is empty. Difficulties with temperature control are also to be expected since the cold supply cannot be interrupted.

Arrangement according to FIG. 2:

Evaporators and latent heat storage are not directly coupled. There is a cavity between the evaporator and the latent heat store, which has poor thermal conductivity in the unfilled state. A connection between the evaporator and the latent heat storage can be established by means of a thermally conductive liquid.

The liquid is circulated by a small pump. For this purpose, the pump would only have to be operated briefly in order to raise the liquid to an appropriate level. If necessary, the liquid is then drained from the higher-lying container into the necessary spaces.

The device can be cooled briefly if the evaporator is operated without coupling and the entire cooling capacity can thus be used to cool the interior.

The memory can be charged when the evaporator is operated in the coupled state. The cold room is also cooled, but with reduced performance. If there is a coupling and the evaporator is not operated, the device is cooled from the storage tank.

It may be possible to defrost the device if the coupling can be interrupted sufficiently (the insulating distance between the evaporator and the latent heat storage is sufficiently large) and the internal temperature does not rise too much until the defrosting has taken place, since the heat from the rear wall directly defrosts supported the evaporator, not applicable. The defrosting process could be supported by a fan.

Arrangement according to FIG. 3:

By designing or dividing the intermediate space into different zones, it is possible to only partially create the coupling between the evaporator and the latent heat store. In the meantime, the temperature of the zones that are not coupled to the storage unit can rise to the cold room temperature, ie the evaporator thaws in this zone while the device is still being cooled.

It is also conceivable to install part of the evaporator in the latent heat store (direct storage), e.g. B. when very long breaks have to be bridged.

Claims (6)

Refrigerator or freezer with a flat or plate-shaped evaporator arranged in a housing wall delimiting a cooling space and provided with thermal insulation,
characterized,
that a cold accumulator (6) is arranged on the side of the evaporator (5) facing away from the cooling space (20). A refrigerator or freezer according to claim 1, characterized in that the cold store (6) is separated from the evaporator (5) by a gap (7) which, if necessary, can be filled and emptied with a highly heat-conducting liquid (8). Refrigerator or freezer according to claim 1 or 2, characterized in that the gap (7) is formed by a flat container, the large walls of which consist of a good heat-conducting material. Refrigerator or freezer according to claim 2 or 3, characterized in that the flat container (7) through lines (11, 12), in which at least one valve (10) and a pump (13) are arranged, with a storage container (9 ) for the liquid (8). Refrigerator or freezer according to one of Claims 2 to 4, characterized in that the flat container (7) is divided into sections 17, 18 by at least one narrow intermediate wall (16), each of which fills and empties with the liquid (8) to let. Refrigerator or freezer according to one of claims 1 to 5, characterized in that at least part of the evaporator is arranged directly in the cold store.

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