EP2104818A1

EP2104818A1 - Condenser for a refrigerator

Info

Publication number: EP2104818A1
Application number: EP07847280A
Authority: EP
Inventors: Detlef Cieslik; Jochen HÄRLEN; Michaela Malisi; Berthold Pflomm
Original assignee: BSH Bosch und Siemens Hausgeraete GmbH
Current assignee: BSH Hausgeraete GmbH
Priority date: 2006-12-22
Filing date: 2007-11-22
Publication date: 2009-09-30
Also published as: RU2447378C2; CN101568783B; US20100037645A1; DE102006061084A1; WO2008077698A1; RU2009124422A; CN101568783A; US8418492B2

Abstract

A condenser assembly for a refrigerator comprises a condenser (8) which is arranged in a frame (23, 29) and through which a refrigerant can flow. The frame (23, 29) has at least one evaporation tray (24; 35) which is arranged above the condenser (8) and one evaporation tray (24; 35) which is arranged below the condenser (8).

Description

Condenser for a refrigeration device

The present invention relates to a condenser assembly, in particular for a household refrigerator.

In a conventional household refrigerator, a recess is recessed in a lower rear portion of the housing, in which a compressor for the refrigerant circulating in the refrigerator is housed. A condenser is mounted on a rear wall of the housing. When the refrigeration device is installed in an apartment, this back wall, together with a building or furniture wall, usually limits a chimney in which air heated by the condenser rapidly rises, whereby cool fresh air flows into the compressor niche. With the help of this fresh air on the one hand, the compressor is cooled, on the other hand, it contributes to the evaporation of condensate discharged from the interior of the refrigerator and collected in a shell mounted on the compressor condensed water.

Modern, compact compressors have a high power density and, due to improved thermal insulation of the devices, their running times are shortened compared to older devices. Although improved by these measures the efficiency of the devices, but there is the problem that the efficiency of cooling and condensate evaporation suffers, because the heating of the condenser and thereby driven draft through the evaporator chamber set each delayed after the compressor. Thus, at the beginning of each operating period of the compressor, there is a period during which the compressor is inefficiently cooled and condensate water heated by it does not evaporate or can not be efficiently discharged from the compressor table due to draft.

In order to save the space required by a backwall condenser and to achieve efficient cooling of the compressor and removal of water vapor from the compressor niche, it has been proposed to accommodate the condenser in a compact design in the niche and to cool the compressor and condenser by means of a fan. Even with such a construction, however, it proves difficult to have a sufficient evaporation rate of the condensed water Especially when this occurs due to frequent door opening or the storage of moist chilled goods in large quantities. In order to absorb such peaks in the formation of condensation water, conventionally, large evaporation shells are required whose placement in the compressor niche is at the expense of the usable volume of the refrigeration device.

The aim of the present invention is to provide a compact condenser assembly that achieves rapid evaporation of the condensate with low energy consumption.

The object is achieved by a condenser assembly for a refrigeration device with a arranged in a frame, can be traversed by a refrigerant condenser, wherein the frame comprises at least one arranged above the condenser evaporation tray and arranged under the condenser evaporation tray: By the evaporation trays a the condenser receiving Limiting space above and below, on the one hand, the upper shell is heated efficiently by heat given off by the condenser by convection and, on the other hand, the surface of water contained in the lower shell is exposed to direct contact with an air flow through the condenser which causes evaporation in the lower shell promotes even at low temperatures.

Conveniently, the upper evaporation tray has an overflow, passes through the water from the upper to the lower evaporation tray.

In order to guide loss of air through the condenser space, the frame expediently has a side wall extending between the two shells.

When a flow path of the water from the overflow into the lower shell passes over a surface of the side wall facing the condenser, water flowing on this side wall to the lower shell can also efficiently evaporate.

On the flow path on the side wall, a drip edge lying above the lower evaporation tray is preferably formed. The drip edge prevents water from flowing down past the sidewall, leaving water has passed, even then reliably reaches the lower shell, if the side wall itself does not end in or above the lower shell. This simplifies in particular the assembly of the condenser assembly.

In order to further improve the evaporation performance of the shells, the condenser is preferably connected in series with one through one of the evaporation trays, preferably the lower, extending refrigerant line.

A fan blade of a fan that drives air flow through the condenser assembly is preferably located in an opening of an end wall of the frame. The front wall prevents air around the impeller from flowing back to its upstream side, ensuring high airflow through the condenser assembly at low fan speed.

As a liquefier, a wire tube liquefier is preferred.

In order to achieve a compact construction of the condenser, it comprises a plurality of plate-like heat exchanger elements connected in series, preferably in a package-like arrangement. In order to stabilize the arrangement of the heat exchanger elements, at least one stabilizing element is preferably provided with a plurality of notches, wherein in each case an edge of one of the heat exchanger elements engages in one of the notches of the stabilizing element.

The stabilization element is preferably formed in the shape of a column with a rear side contacting a side wall of the frame or a niche of the refrigeration device receiving the condenser assembly. Thus, the stabilizing element can still perform an additional function, namely to concentrate the air flow circulating through the condenser assembly inside the condenser assembly and to prevent air from flowing past the condenser laterally without being heated substantially.

A particularly compact construction results when the stabilizing element has pairs of notches at the same height, wherein the two notches of each pair of pipes of the same plate-like heat exchanger element engage. Preferably, two stabilizing elements are provided which oppose each other on opposite sides of the condenser.

Further features and advantages of the invention will become apparent from the following description of embodiments with reference to the accompanying figures. Show it:

Figure 1 is a perspective view of a refrigerator according to the invention, as seen from the back of its housing.

Figure 2 is a schematic view of the condenser assembly of the refrigeration device of Fig. 1.

Fig. 3 is a perspective view of the condenser;

Fig. 4, 5 are each perspective views of stabilizing elements of the condenser;

6 shows the condenser in combination with the stabilizing elements, a dryer and a heating loop for an evaporation tray;

Fig. 7 is a perspective view of the top of a condenser receiving frame; and

Fig. 8 is a perspective view of the lower part of the frame.

Fig. 1 shows a rear view of a household refrigerator such as a refrigerator or a freezer. In the base of the device there is a niche 1 open to the rear, towards the viewer, through which a cross member 2 attached to the side walls of the housing extends. On this cross member, a compressor 3 and a condenser 4 are mounted. On a side facing away from the compressor 3 side, the condenser 4 is closed by an end wall 5 to a passage on which a fan 6 is arranged. The end wall 5 closes on the one hand tight against a rear wall 7 of the housing 4; On the other hand, an opposite edge of the end wall 5 touches a not visible in the figure vertical insulating wall between the niche 1 and the interior of the refrigerator.

A view of the condenser assembly from the opposite direction, relative to the refrigerator housing from the front, is shown in Fig. 2. As you can see, the condenser housing 4 is open to the front of the device, and a Drahtroh rverflüssiger 8 in its interior can be seen. As can also be seen in the perspective view of the condenser in FIG. 3, a cold center tube 9 of the condenser 8 forms a plurality of plate-like sections 1 1 arranged parallel to one another, in which straight lines connected by 180 ° arches 12, 13 are formed Pipe sections parallel to the viewing direction of Fig. 2 extend. The plate-shaped sections 1 1 are stiffened in a conventional manner by soldered to the rectilinear pipe sections wires 14. A columnar stabilizing element 15 engages from the front between each two front sheets 12 of each plate-shaped portion 1 1 in the plate-shaped portions 1 1 and is provided with a plurality of pairs opposed slots 16, in each of which parts of the adjacent sheets 12 engage. A corresponding stabilizing element 17 engages from the rear side between rear sheets 13 of the plate-shaped sections 11.

The stabilizing elements 15, 17 are shown in Figures 4, 5 each in a perspective view. They are hollow bodies of two shells assembled along a vertical plane. The stabilizing element 15 carries on an outer side a vertical web 18, whose width increases from top to bottom, so that the web 18 snugly against the niche 1 from the interior of the refrigerator separating, not completely vertical wall hugs. The stabilizing element 17 also carries an outwardly directed, the rear wall 7 facing web 19 which is interrupted in the middle to follow the contour of the rear wall 7. Both stabilizing elements 15, 17 carry the webs 18 and 19 opposite in the Drahtrohrverflüssiger 8 engaging webs 20, which reduce the free air passage cross-section of the condenser 8 and bundle a driven by the fan 6 air flow in the center of the condenser 8.

6 shows a perspective view of the complete wire tube liquefier 8 together with the stabilization elements 17 inserted from the lateral direction, 19. At one end of the tube 9 of the condenser 8, a dryer cartridge 21 is inserted in the path of the refrigerant, the other end is extended by a extending below the condenser 8 loop 22.

The condenser 8 receiving housing 4 is composed of two plastic moldings shown in Fig. 7 and 8, respectively. The upper molded part 23 shown in FIG. 7 comprises the end wall 5, the rear wall 7 and a cover of the condenser housing 4 designed as an evaporation shell 24. From the end wall 5 in a direction away from the observer, one-piece protruding hollow pins 25 serve to position the one shown in FIG Blower 6, not shown, in front of a central opening 26 of the end wall 5. Below the opening 26, a horizontal rib 27 projects into the interior of the housing 4. It serves together with a complementary groove 28 of the lower mold part 29 shown in FIG. 8 for fixing the height of the upper mold part 23 at the lower 29th

At the bottom of the evaporation tray 24, an opening 45 surrounded by a wall 30 is formed near the rear edge thereof. The wall 30, which is slightly lower than the outer edge of the evaporation tray 24, defines an overflow water level of

Shell 24. When condensation that is supplied to the shell 24 from inside the refrigerator rises above the top of the wall 30, water flows through the opening

45 of the shell 24 and at the condenser 8 facing and heated by him inside the rear wall 7 down. The rear wall 7 has a inside of the

Condenser housing 4 projecting middle section 31, which at its lower

Edge is connected to a lower portion 32 of the wall by a rising wall piece 33. On the rear wall 7 down flowing water can thus the lower

Section 32 of the wall 7 not reach, so that the lower edge of the central portion 31 forms a drip edge 34 from which drops of water fall directly into an evaporation tray 35 formed by the lower mold part 29.

The upper edges of two elongate ribs 36 projecting from the bottom of the evaporation pan 35 serve as a support surface for the wire tube condenser 8. Curved ribs 37 which are higher than the elongate ribs 36 serve as lateral stops defining the position of the wire tube condenser 8 in the horizontal direction. Two hooks 38 are provided to engage behind and pipe sections of the lowest plate-shaped portion 1 1 of the Drahtrohrverflüssigers 8 so to fix on the lower evaporation tray 35. The shape and placement of the ribs 36, 37 are each chosen so as to allow placement of the loop 22 near the bottom of the evaporation tray 35.

The already mentioned horizontal groove 28 is formed by a plurality of outwardly directed hooks 39 on an end wall 40 of the shell 35 facing away from the observer in FIG. 8. A viewer facing outer wall 41 of the shell 35 has a

Indentation 42, the walls of which in the assembled state engage in two notches 43 of the lower portion 32 of the rear wall 7 and so support the upper mold part 23. A hook 44 formed at the level of the recess 42 on the outer wall 41 is provided to engage in an opening 45 of the lower portion 32 and thus to lock the two mold parts 23, 29 together.

Claims

claims

1. Condenser assembly for a refrigeration device with a on a support (23, 29) arranged, can be traversed by a refrigerant condenser (8), characterized in that the carrier (23, 29) at least one above the condenser

(8) and arranged below the condenser (8) arranged evaporation tray (24, 35).

2. Condenser assembly according to claim 1, characterized in that the upper evaporation tray (24) has an overflow (30, 45) over which

Water from the upper into the lower evaporation tray (35) passes.

3. condenser assembly according to claim 1 or 2, characterized in that the carrier (23, 29) at least one between the two shells (24, 35) extending side wall (7).

4. Condenser assembly according to claim 2 and claim 3, characterized in that a flow path of the water from the overflow (30, 45) in the lower shell (35) via a condenser (8) facing surface of the side wall (7).

5. Condenser assembly according to claim 4, characterized in that on the flow path on the side wall (7) over the lower evaporation tray (35) lying drip edge (34) is formed.

6. Condenser assembly according to one of the preceding claims, characterized in that the condenser (8) with a by at least one of the evaporation trays (35) extending refrigerant line (22) is connected in series.

7. Condenser assembly according to one of the preceding claims, characterized in that at least the lower evaporation tray (35) has latching means for latching of the condenser (8) provided counter-latching means.

8. Condenser assembly according to one of the preceding claims, characterized in that the upper evaporation tray (24) releasably detachable on with the other evaporation tray (35) connected to carriers (7, 5) is held.

9. Condenser assembly according to one of the preceding claims, characterized in that the carrier (23, 29) has an end wall (5) with an opening

(26), in which a paddle wheel of a blower (6) is arranged.

A condenser assembly according to claim 9, characterized in that the opening (26) in the end wall (5) is at least approximately nozzle-shaped towards the condenser.

1 1. Condenser assembly according to claim 9 or claim 10, characterized in that the impeller of the fan (6) at least approximately fills the opening (26) in the end wall.

12. Condenser assembly according to one of the preceding claims, characterized in that the condenser (8) is formed as Drahtrohrverflüssiger with a plurality of series-connected plate-like heat exchanger elements (1 1).

13. Condenser assembly according to one of the preceding claims, characterized in that the condenser (8) comprises at least one stabilizing element (15; 17) with a plurality of notches (16), wherein in each case an edge of one of the heat exchanger elements (1 1) in one of Notches (16) of the stabilizing element (15; 17) engages.

14. Condenser assembly according to claim 13, characterized in that the plate-shaped heat exchanger elements (11) are arranged one above the other.

15. Condenser assembly according to claim 14, characterized in that the stabilization element (15; 17) has a columnar shape with a rear side (18, 19) contacting a side wall (7) of the frame (23; 29) or a niche (1) of the refrigeration device receiving the condenser assembly ) is trained.

A condenser assembly according to claim 14 or 15, characterized in that the stabilizing element (15; 17) has pairs of equally spaced notches (16), into the two notches (16) of each pair of conduits (9) of the same plate-like heat exchanger element (1 1) intervene.

17. Condenser assembly according to one of claims 14 to 16, characterized in that two stabilizing elements (15; 17) oppose on opposite sides of the condenser (8).

18. Condenser assembly according to one of claims 14 to 17, characterized in that the at least one stabilizing element (15; 17) made of foamed plastic, preferably foamed polystyrene is formed.

19. Kätgerät with a condenser assembly according to one of claims 1 to 18.

20. Refrigerating appliance according to claim 18, characterized in that the

Condenser assembly is set in a provided on the rear wall of the refrigeration device compressor niche, wherein for fixing the condenser assembly between this and the refrigeration device damping elements are provided.