RU2419045C2 - Refrigerating unit with defroster - Google Patents

Abstract

FIELD: personal use articles. ^ SUBSTANCE: refrigerating unit comprises a storage chamber and an evaporation chamber, which is connected to the storage chamber via an air duct of cold air and an air duct of hot air, an evaporator and a defroster. The defroster in the area arranged near the air duct of hot air has higher density of heating capacity compared to the area arranged near the cold air duct. ^ EFFECT: application of this invention makes it possible to achieve even distribution of temperature, which is only slightly higher than the freezing point, in the evaporating chamber. ^ 12 cl, 4 dwg

Description

Technical field

The present invention relates to a refrigerating apparatus with a storage chamber and an evaporation chamber, which is connected to the storage chamber through a cold air duct and a warm air duct, and which comprises an evaporator in which the air flowing from the storage chamber is cooled and then taken back to the storage chamber. Such refrigeration units are also called units with an automatic defrosting system.

State of the art

The warm air that goes from the storage chamber to the evaporation chamber brings moisture with it, which tends to precipitate on the evaporator, and thus an ice layer forms on it during operation of the refrigeration unit. To prevent deterioration of the efficiency of the apparatus, this layer of ice must be removed from time to time. For this purpose, a thawer is usually located in the evaporation chamber, which allows the ice to melt and drain from the evaporator. The resulting melt water collects at the lowest point of the evaporation chamber and from there it flows out through the passage to where the melt water can evaporate.

The evaporation process violates the energy efficiency of such a refrigeration apparatus, since the heating energy is not fully used to thaw the ice. In order for defrosting to begin at all, the evaporator must first be heated from an operating temperature that is below 0 ° C to 0 ° C, and at the end of the defrosting process, the evaporator must again be cooled to its operating temperature before the storage chamber can again to be chilled. In addition, heat from the evaporation chamber during thawing inevitably leaves the storage chamber, which again must be taken from the storage chamber. This heat outflow is the stronger, the higher the temperature in the evaporation chamber during defrosting.

Therefore, in order to minimize energy consumption during thawing, it will be desirable to realize a temperature distribution as uniform as possible, which is only slightly above the freezing point, in the evaporation chamber.

Disclosure of invention

Unexpectedly, this goal is achieved according to the present invention in a simple manner with a defroster, which has a higher heating power density in the region adjacent to the warm air duct than in the region adjacent to the cold air duct.

The reason for this is that the air flowing through the evaporation chamber gives off its moisture mainly in the area of the evaporator, located next to the warm air duct. Thus, the thickness of the ice layer increases there faster than in the area located next to the cold air duct. Due to the fact that the area of the evaporator located next to the hot air duct receives a higher heating power density than the area located next to the cold air duct, ice in the area located next to the warm air duct melts faster, and thus the ice layer essentially across the evaporator decreases simultaneously. You can refuse to heat the already thawed areas, which leads there to a strong increase in temperature.

The defroster is preferably plate-shaped and thus can be located along the main side of the evaporator.

Preferably, the defrost passes underneath the evaporator and thus the air heated by it can rise through the evaporator.

Preferably, the defroster comprises a carrier plate and a heating element located on the carrier plate.

The heating element may be secured to the carrier plate with material closure, for example, by soldering, to ensure good heat transfer from the heating element to the plate. The fastening of the heating element to the plate by mechanical locking can also be taken into account.

To facilitate heating of the evaporator also by radiation, the heating element is preferably located on the plate side facing the evaporator.

Further, the heating element should be at least part of its length located at a distance from the plate, on the one hand, so as not to impede the outflow of melt water that drips from the evaporator onto the plate, and on the other hand, to limit the outflow of heat from the heating element to the plate , since the outflow of heat reduces the efficiency of thermal radiation.

In this case, it will also be advisable if the plate is made of a material (for example, metal) that effectively reflects the thermal radiation that is generated, in order to nevertheless direct thermal radiation to the evaporator, which is emitted by the heating element in the direction away from the evaporator.

According to the first embodiment, in that region of the carrier plate, which is located next to the hot air duct, the heating element is denser than in the region located next to the cold air duct. This facilitates the use of a heating element with a heating power per unit length that is constant over the entire length of the heating element.

The obstruction of the air flow passing through the evaporation chamber created by the heating element may remain small if the heating element is located in bends extending in the direction of flow of air. In order to realize a different distribution of heating power, preferably at least one of the bends is located completely in that region of the carrier plate, which is located next to the warm air duct.

According to a second embodiment, the heating element may have, in the region adjacent to the warm air duct, a higher heating power per unit length than in the region adjacent to the cold air duct. Then a different distribution of the density of the heating power can also be realized if the heating element in both areas is located on the same pattern.

To make the design of the heating element simple, in this latter case, it is preferable that the heating element contains two series-connected sections, one of which fills the area located next to the warm air duct, and the other contains the area located next to the cold air duct.

In these two sections, the heating element can be located separately in bends that pass through the evaporation chamber in the direction of flow of air.

If a tray for melt water is provided on the bottom of the evaporation chamber, into which melt water flows from the evaporator, it may be advisable to draw a portion of the heating element along the melt water tray to ensure that residual ice in the melt water tray does not prevent melt water from draining from evaporator, and stagnant melt water will not freeze again at the end of the defrosting process.

Brief Description of the Drawings

Other features and advantages of the invention follow from the following description of embodiments with reference to the accompanying figures. They show the following.

Figure 1: schematic section of a refrigeration apparatus proposed by the present invention.

Figure 2: axonometric projection of the case of the evaporator of the refrigeration apparatus of figure 1 with the defrosting device located in it.

Figure 3: a top view of the housing of the evaporator and mounted in it the evaporator according to the second variant implementation of the invention.

4: a schematic partial sectional view of an evaporator body according to a third embodiment of the invention.

The implementation of the invention

Figure 1 shows a schematic section of the upper region of the refrigeration apparatus proposed by the present invention. The refrigerator has a housing 1 and a door 2, which are usually implemented as a hollow body filled with a heat-insulating layer 3 of foam material. Using the heat-insulating dividing wall 4, the inner space of the housing 1 is divided into an evaporation chamber 5 and a storage chamber 6. The evaporation chamber 5 is for the most part filled with the housing 7 of the evaporation unit, and an evaporator 8 of known construction with plates running parallel to the cut plane and a refrigerant pipe bending across the plates is mounted in the interior of the housing 7. Under the evaporator 8, on the bottom of the housing 7 there is a defroster 15. The housing 7 has a warm air duct 9 on its side facing the door 2, and through the duct 9, warm air enters from the storage chamber 6 into the evaporation chamber 5, and also has a duct 10 on its side 19 facing the rear wall of the housing 1. Behind the duct 10 is a fan 11 with blades 12 and an engine 13, and the fan 11 draws air from the housing 7 and pumps cold air into the duct 14 to the storage chamber 6.

Figure 2 shows a perspective view of the housing 7 and the defroster mounted therein 15. The housing 7 has an even, slightly sloping back plate 18, which, together with the electric heating element mounted on it, forms a defroster 15. The carrier plate 18 is made of metal or plastic, which has a metal coating on its upper side to direct heat radiation emitted downward to the evaporator 8.

Between the carrier plate 18 and the rear wall 19 of the housing 7, a drain tray 20 is located on its bottom, which extends across the entire width of the housing 7 and is inclined to the drain hole 21.

The heating element comprises a plurality of bends 16, 17 extending deep into the housing 1. The bends 16, 17 are held on the carrier plate 18 by means of elastic brackets 22 spaced from the carrier plate 18. The brackets 22 hold the heating element at a distance from the carrier plate 18, and thus, meltwater that drips from the evaporator 8 onto the carrier plate 18 can flow unhindered into the drain tray 20.

Short and long bends 16 or 17 alternate in the width direction of the carrier plate 18, which extend only below the area of the evaporator 8 located next to the warm air duct 9, or respectively under the entire evaporator 8 and thus form two sections with different heating power densities. Alternatively, bends can also be provided in more than two different lengths, of which, however, all extend from the side of the evaporator 8, which faces the warm air duct 9, in order to heat more intensively this region of the evaporator 8, which freezes most during operation. A straight portion 23 of the heating element extends along the drain pan 20 to ensure that there are no pieces of ice left there that would prevent meltwater from flowing out.

Figure 3 shows a top view of the housing 7 of the evaporator, and the housing 7 of the evaporator contains the evaporator 8 and the defrost 25 according to the second embodiment of the invention. The view of the housing 7 with the carrier plate 18 and the drain tray 20 is the same as described with reference to FIG. 2. Also, the evaporator 8 with the refrigerant pipe 29 held in the fins 28 is identical to the evaporator described with reference to FIG. 1. The heating element 25 has two sections 26, 27, which differ in heating power per unit length. A more powerful section 26 passes under that section of the evaporator 8, which is located next to the warm air duct 9, and a less powerful section 27 passes under that section of the evaporator, which is located next to the rear wall 19 and thereby with the cold air duct. Both sections 26, 27 are laid according to the same pattern, in the form of bends 30, elongated in length in the direction deep into the body. A bend 31, extending in the transverse direction to the housing 1 and relating to the less powerful section 27, heats the drain tray 20.

Figure 4 shows in section a third embodiment of the invention. In this embodiment, the heating element 15 with alternately long and short bends 16, 17 of the type shown in FIG. 2 is not located at a distance from the carrier plate 18, but is connected to it in a heat-conducting manner with solder 32. In order to avoid that the melt water will stagnate in the facing to the drainage tray 20 of the curved sections 33, they are slightly bent upwards in the case of short bends 16 and thus water can flow between them and the carrier plate 18. In the case of long bends 17, the curved sections extend beyond the drainage tray 20 and thus m case guaranteed free outflow.

Claims (12)

1. A refrigerator with a storage chamber (6) and an evaporation chamber (5), which is connected to the storage chamber (6) through a cold air duct (14) and warm air duct (9) and which contains an evaporator (8) and a defroster (15 ), characterized in that the defroster (15) in the region located next to the warm air duct (9) has a higher heating power density than in the region located next to the cold air duct (14). 2. The refrigeration apparatus according to claim 1, characterized in that the defroster (15) is made in the form of a plate. 3. The refrigerator according to claim 2, characterized in that the defroster (15) passes under the evaporator (8). 4. The refrigeration apparatus according to claim 1, characterized in that the defroster (15) comprises a carrier plate (18) and a heating element (16, 17; 26, 27) located on the carrier plate (18). 5. The refrigeration apparatus according to claim 4, characterized in that the heating element (16, 17) is snapped onto the carrier plate (18). 6. Refrigeration apparatus according to claim 4 or 5, characterized in that the heating element (16, 17; 26, 27) is located on the side of the carrier plate (18) facing the evaporator (8) and at least in part of its length located at a distance from the carrier plate (18). 7. Refrigeration apparatus according to claim 4 or 5, characterized in that the heating element (16, 17) in that region of the carrier plate (18), which is located next to the warm air duct (9), is denser than in the region located next to the cold air duct (14). 8. The refrigerator according to claim 6, characterized in that the heating element (16, 17; 26, 27) is located in bends (16; 17; 30) passing through the evaporation chamber (5) in the direction of air flow, at least one of the bends (16, 30) completely extends in that region of the carrier plate (18), which is located next to the warm air duct. 9. The refrigeration apparatus according to claim 4 or 5, characterized in that the heating element (26, 27) in the region located next to the warm air duct (9) has a higher heating power per unit length than in the region adjacent with duct (14) of cold air. 10. The refrigerator according to claim 9, characterized in that the heating element contains two series-connected sections (26; 27), one (26) of which fills the area located next to the duct (9) of warm air, and the other (27) fills the area adjacent to the cold air duct (14). 11. The refrigerator according to claim 10, characterized in that the two sections (26; 27) contain bends (30) that pass through the evaporation chamber (5) in the direction of air flow. 12. The refrigeration apparatus according to one of claims 1 to 5, 8, 10 and 11, characterized in that a tray (20) for melt water is made on the bottom of the evaporation chamber and a heating coil section (31) runs along the melt tray (20) water.

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