CS244833B2 - Arrangement of the heat exchanger for automatic de-icing of standart cooling space of compressor colling boxes with double cooling space - Google Patents

Abstract

A duct (7) interconnecting the respective heat-exchangers of the two compartments of a compressor- type refrigerator is provided with surface-increasing elements (8) to avoid frosting. The surface- increasing elements (8) are covered by a cover element (9) in metallic connection with the heat exchanger plate (10) of the fresh food compartment. <IMAGE>

Description

In a heat exchanger arrangement for the automatic defrosting of the standard refrigeration space of a double-space compressor cooler, the evaporator plate (4) is arranged in its entirety under a closed freezer compartment (1) and on lines (7) connecting the refrigeration space heat exchangers (2) and the freezer The cells (8) are formed to increase the area.

Giant. 1

The invention relates to a heat exchanger arrangement for the automatic defrosting of a heat exchanger in a standard refrigeration compartment of a dual-compartment refrigeration chamber. The arrangement according to the invention ensures a properly controlled course of frost and ice removal from the evaporator plate of the standard refrigeration compartment during normal operation without increasing energy consumption and without electrical heating.

It is known that the moisture contained in the air precipitates on the coldest surfaces, respectively. at certain locations and components in the refrigeration compartment of the refrigeration plant.

Frost and ice build up continuously on these cooling equipment components, causing serious problems as this reduces the heat exchanger's ability to transmit heat.

Most of the refrigerated cabinets that are sold have semi-automatic defrosting with automatic reverse switching. With these devices, simply press the defrost button of the temperature regulator in case of required defrosting. This stops the compressor until the heat exchanger is completely smeared. .

Thawed water from the plastic container intended for this purpose must then be blown in, then the empty container will be returned to its place. If it is forgotten to start defrosting, the ice will accumulate on the heat exchanger and once the ice layer has reached a certain thickness, it will impair the proper functioning of the cooling device.

Thus, the temperature in the refrigeration compartment and the temperature of the stored foodstuffs increase. In addition, energy consumption also increases. The above drawbacks are eliminated by fully automatic thawing. Until now, fully automatic defrosting is carried out by electric heating. ·

The understanding of electrical heating has a number of drawbacks. One of these drawbacks is that part of the evaporator surface in the refrigeration compartment is covered by a defrosting heating unit, thereby preventing natural air flow along the evaporator plate.

After each cooling cycle of the missions, a specified amount of heat Qf is introduced into the cooling chamber to thaw the evaporator. The effect of the applied heat dissipation Q _f occurs in the freezer compartment as well as in the conventional refrigeration compartment to a greater temperature variation than necessary. The amount of heat Qq supplied as a result of the electric heating must be removed for further cooling.

The purpose of the present invention is to overcome the above drawbacks and to provide automatic cooling of the cooling device without the use of electric heating by reducing the average energy consumption specified by the standard by approximately a quarter.

This object is solved by a heat exchanger arrangement for automatic defrosting of the cooling compartment komppesorových refrigerators with refrigerating ^am> azici.prottortm, - in which, according to the invention vp ^ <^^ 1 ^^^ thee evaporator plates arranged throughout the volume enclosed beneath the freezer compartment and Cells for increasing the surface area of the cooling chamber and the lubricating chamber are provided on the lines.

The arrangement according to the invention allows the thawing of refrigeration cabinets for non-frost-free auxiliary energy-consuming appliances and allows the frost and ice to be formed during normal operation to be removed, and the process of the invention is simplified compared to the hitherto known defrosting processes.

In a preferred thrust embodiment of the arrangement according to the invention, the evaporator plate has additional heat transfer surfaces on both sides.

In a further preferred embodiment of the arrangement according to the invention, the cells for increasing the area

Jsou 'are covered by a cover which is connected by a metal connection to the heat exchanger.

The technical solution according to the invention is explained in detail in the following description of a preferred exemplary embodiment, which is shown in the attached drawing.

Obb. 1 illustrates an exemplary embodiment of a refrigeration apparatus with a built-in evaporator heat exchanger, a refrigeration compartment and a freezer compartment, with control circuit elements, and an air flow resulting from the arrangement according to the invention;

Fig. 2 shows an exemplary embodiment of the so-called connecting section between heat exchangers, wherein the connecting section is provided with surface expansion elements which ensure perfect heat exchange, i.e., the complete removal of frost and ice;

Fig. 3 shows the arrangement of the connection section according to the invention shown in Fig. 2, wherein the connection section is incorporated therein within the cooling space.

According to FIG. 1, the temperature regulator sensor 3 is arranged in the cooling space 2 below the closed freezer compartment with a space 6 on the surface of the evaporator plate 6 of said cooling space 7. The purpose of the sensor is to switch off the motor at a predetermined temperature. As a result, an air stream 6 is produced in the cooling chamber.

When the operation is stopped, the heat exchanger reacts directly in the cooling chamber 2 to an elevated temperature and automatically grinds the formation of frost or ice on the refrigerant line, connecting the two heat exchangers which could occur in the cooling chamber 2 due to possibly insufficient area. by additional enlargement of the heat-radiating surfaces of said section.

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As the frost and ice build up, the area and cover elements 9 are prevented and all the fully automatic defrosting criteria are met.

Thus, by providing a heat exchanger according to the invention, the object of the present invention is solved by heating the heat exchanger to be defrosted by the natural heat flow after stopping the operation after each individual cooling cycle.

As can be seen from FIGS. 2 and 3, the conduit 6, which connects the heat exchangers of the freezer compartment 1 and the refrigeration compartment 2 with each other, is connected on both sides with auxiliary links 6 which prevent it from being fined by ice. Said auxiliary links 6 are covered by a decorative cover 2 and the seam so that said cover 9 also contacts the heat exchanger plate 10 of the cooling space 2.

The present invention can be used for climate-controlled refrigeration chambers of any kind with the correct selection of the evaporator surface of the heat exchanger - with the same cooling cabinet formation.

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

It also follows from the above that the mono-vaporizer evaporates between the two cooling spaces in different ways, but this is not to be construed as having the function of the invention.

object of the invention

Claims (3)

object of the invention A heat exchanger arrangement for the automatic de-greasing of a standard refrigeration compartment of a double-compartment compressor cooler, characterized in that. The plate (4) of the arnica is arranged in a celite volume under the enclosed lubrication chamber (1) and on the conduits (7) connecting the heat exchangers of the cooling chamber (2) and the lubrication chamber (1), shells (8) are provided to increase the area. 2. - The heat exchanger arrangement according to item 1, characterized by! The method according to claim 1, characterized in that the evaporator plate (4) has additional heat transfer surfaces on both sides. 3. Heat exchanger arrangement according to claim 1 or 2, characterized in that the surface enlargement elements (8) are covered by a cover (9) which is connected by a metal connection to the heat exchanger. 2 drawings