HU190165B - Heat exchanger arrangement for automatic thawing the normal cooling space of twin-space compressor coolers being in the same box body - Google Patents

Abstract

The invention relates to a Waermetauscheranordung for automatic defrosting of the heat exchanger in the standard cavity of compressor Kühlehlenken with several Kuehlraeumen. With the invention, a well controllable de-icing and de-icing process is achieved without additional expenditure of energy at relatively low design effort. The essence of the invention is that the evaporator plate is disposed in the entire volume below the closed freezer compartment and are provided on the connecting lines between the heat exchangers of the standard and the freezer compartment refueling elements. As a result, the defrosting heat exchanger can heat up after the individual cooling period under the influence of the natural heat flow during standstill and automatically defrost it.

Description

BACKGROUND OF THE INVENTION The present invention relates to an apparatus for the automatic defrosting of a conventional refrigerated space heat exchanger of dual-cooled compressor refrigerators in the same cabinet body.

This arrangement provides a separate energy investment, without electric heating, on the evaporator plate of the normal cooling space under well-controlled conditions of frost and de-icing under normal operating conditions.

It is a known fact that the humidity of the air in the cooling compartment of a refrigerating appliance is precipitated on the coldest surfaces or parts of the cooling surface.

Frost and ice are constantly formed on these components, which causes a significant problem as the heat transfer capacity of the heat exchangers is reduced.

Most refrigerators used have auto-reset semi-automatic defrosting. When defrosting is required, simply press the defrost button on the temperature controller. At this point, the compressor stops until the heat exchanger is de-iced and then restarts. The defrosted water collected in a plastic container placed for this purpose must then be emptied and replaced. If you forget to start the defrosting process, the ice builds up on the heat exchanger, after reaching a certain thickness it interferes with the proper functioning of the appliance, the temperature rises and deteriorates the frozen food, and results in excess energy consumption.

The above disadvantages can be eliminated by automatically defrosting the refrigerators. The automatic defrosting of the refrigerating units is now solved by electric heating.

Electrically heated defrosting has several disadvantages. The defrost heater unit covers part of the evaporator surface of a normal refrigerator compartment. It prevents natural airflow along the evaporator plate. After each cooling period _f Q amount of heat to be introduced into the cooling chamber in a cooling-air defrost the evaporator. The heat input Q _f thus causes the freezer compartment and the normal compartment to fluctuate in excess of the required temperature. The input electrical heating _f Q amount of heat to be diverted from the additional cooling.

It is an object of the present invention to overcome the above-mentioned drawbacks and to provide automatic defrosting of the refrigerating appliances without electric heating, thereby reducing about one-quarter of the standard, average power consumption.

The temperature control sensor 3 in the closed freezer compartment 2 of the "freezer" temperature of the star stage is located on the surface of the evaporator plate 4 of the normal freezer compartment 2. Its function is to switch off the motor compressor 5 at a predetermined value. 6 air currents develop in the normal space.

The normal coolant heat exchanger reacts directly to a higher temperature in the normal cooler during a shutdown, causing it to automatically defrost. The formation of frost and ice in the refrigerant conveyor line connecting the two heat exchangers due to insufficient surface area is avoided by the additional expansion of heat transfer surface area in this space.

The surface build-up members 8 and the cover members 9 are excluded from the application of hoarfrost and ice so that the automatic defrost criterion is met.

The technical solution according to the present invention is described in the accompanying drawings, in which:

Fig. 1 illustrates an exemplary embodiment of a dual-cooled refrigerator with evaporative heat exchanger, with control elements, air flow from the arrangement,

Fig. 2 illustrates an exemplary embodiment of a section connecting heat exchangers with a so-called heat exchanger. it is provided with surface enlarging elements 8 for perfect heat exchange and de-icing.

Figure 3 shows the location of the design of Figure 2 inside the cooling compartment. It can be seen from Figure 1 that the temperature control sensor 3 of the refrigerator in the closed space below normal space 2 of the freezer freezer at temperature corresponding to the star stage is located on the surface of the evaporator plate 4 in the normal space. Its function is to switch off the motor compressor 5 at a predetermined value. 6 air currents develop in the normal space.

The normal coolant heat exchanger reacts directly to a higher temperature in the normal cooler during a shutdown, causing it to automatically defrost. The formation of frost and ice on the refrigerant conveyor line connecting the two heat exchangers due to inadequate surface area is avoided by additional heat transfer surface expansion in this section in the normal refrigerator compartment.

The surface enhancement elements 8 and the cover element 9 exclude the loading of hoarfrost and ice, so that the automatic defrost criterion is met.

The object of the present invention is achieved by a heat exchanger arrangement which is characterized in that the evaporator plate is located completely below the freezer enclosure. Surface-extending elements are provided on the conduit connecting the two refrigerator compartments.

It is desirable that both sides of the evaporation plate have a heat transfer (active) surface and that the surface enhancement elements are covered by a cover element in metallic contact with the heat exchanger plate.

The heat exchanger arrangement of the present invention thus solves the object that the heat exchanger to be defrosted is heated by natural heat flux during each shutdown period after the cooling period.

It can be seen from Figures 2 and 3 that they are connected to auxiliary elements 8 for preventing icing on both sides of the conduit 7 connecting the freezer and the normal refrigerator. The latter are covered by a decorative cover element 9 in such a way that said cover element also has a metallic connection with the heat exchanger plate 4 of the normal refrigerator.

The present invention provides automatic defrosting of household refrigerating appliances without the use of energy-consuming auxiliaries and, in a simpler way than before, provides the de-icing and de-icing of normal operation.

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Our technical solution can be applied to single-, double-, three- and four-star deep-freezer compressor refrigerators, with the correct choice of evaporator heat exchanger surface with the same cabinet design. ⁵

The invention is not limited to the exemplary embodiment illustrated in the drawing and described in detail above.

Various designs of evaporators between the two refrigerators are possible within the scope described. These ¹⁰ azon- ban function the same in terms of the invention as disclosed above.

Claims (3)

Claims Apparatus for automatically defrosting a normal refrigerator compartment heat exchanger of dual-cooled compressor refrigerators in the same cabinet, the entire evaporator plate of which is located below the freezer enclosure (1), characterized by a conductor (8) connecting the heat exchanger elements (2). Apparatus according to claim 1, characterized in that both sides of the evaporator plate (4) have a heat transfer surface. Apparatus according to claim 1 or 2, characterized in that the surface enhancement elements (8) are covered by a cover element (9) connected to the heat exchanger plate.