DE102008054416A1 - The refrigerator - Google Patents

Abstract

The invention relates to a refrigeration device having a condenser (3) connected in a refrigeration circuit, which is designed as a tube heat exchanger with tube sections (5), and at least one heat storage element (15) which is inserted into a mounting space (13) between the tube sections (5) of the Condenser (3) is inserted. According to the invention, the heat storage element (15) is spaced apart from the pipe sections (5) of the condenser (3) via at least one predetermined air flow gap (17).

Description

The The invention relates to a refrigerator according to the Preamble of claim 1.

Freezers have a switched in a refrigeration circuit condenser on. The condenser is a heat exchanger, through the heat absorbed in the cooling process outside of the refrigerator delivered to the ambient air becomes. For this purpose, different types of condensers used: For statically ventilated condensers the surface for better heat dissipation through laminations or by wire rows connecting the heat exchanger tubes together connect, enlarged. The statically ventilated Condenser is on the back of the refrigerator appropriate. Alternatively, there are forced-draft condensers, their dimensions can be made much smaller. Between the condenser and a compressor can a be arranged separate fan, by its air flow dissipates the heat from the condenser.

From the DE 20 2006 007 585 U1 is a generic refrigerator known, in which the condenser is designed as a tube heat exchanger with a coil, which has horizontally extending rectilinear pipe sections, which are connected to each other via edge pipe bends. To increase the efficiency of the refrigeration cycle, the generic refrigeration device on a latent heat storage, which absorbs heat emitted by the condenser. When the heat emitted by the condenser is absorbed, the state of the aggregate is changed. The state of aggregation is reversed during a standstill of the refrigeration cycle by dissipating heat to the environment again.

in the generic refrigeration device is the latent heat storage in direct contact with the condenser tubes. In this way is an immediate heat transfer provided by the condenser in the latent heat storage.

The The object of the invention is a refrigeration device to provide, in which the cooling capacity of the refrigeration cycle is increased by simple means.

The The object is solved by the features of claim 1. Advantageous developments of the invention are in the dependent claims disclosed.

The Invention is based on the knowledge that exists between the heat storage element and the middle pipe sections of the condenser, the in particular horizontal and rectilinear, free flow cross sections an accelerated heat removal from the condenser enable. In departure from the prior art is therefore According to the invention the heat storage element over at least one predetermined airflow gap of the Spaced pipe sections of the condenser. To this Way takes place in the obtained air flow gap an additional natural convection, which accelerates heat dissipation supported by the condenser.

The Surface of the condenser can for better Heat output increased by cooling structures become. Such cooling structures can front side and / or on the back of the coil of the condenser be provided in the form of wire rows. Alternatively, the condenser surface be enlarged by laminations that the pipe sections connect with each other. The front and back Cooling structures limit together with the pipe sections the condenser each mounting spaces, in which the heat storage element can be inserted. According to the invention, the heat storage element non-contact, especially in the middle, between two be arranged adjacent pipe sections. That way is the heat storage element with the same gap dimensions spaced from the upper and lower tube section. The heat storage element can be designed roughly strip-shaped.

From Meaning is a permanently positionally correct arrangement of the heat storage element in the mounting space between the adjacent condenser tube sections. For this purpose, in the respective mounting space an additional Retaining element for positionally secure mounting of the heat storage element be provided. The retaining element may in particular be a retaining wire be on the heat storage element in the mounting space is supported. The retaining element may be on the front and / or be formed on the rear cooling structure, in particular be attached thereto by welding.

alternative or additionally, the heat storage element through a simple clamp connection between the front and rear Cooling structure clamped within the mounting space be.

As mentioned above, the condenser cooling structure may be implemented as front and rear wire rows. In this case, the installation of the heat storage element is carried out by insertion into the laterally open mounting space between adjacent condenser tube sections. The insertion of the heat accumulator in the mounting space is under an elastically yielding bending apart of the front and rear wires of the cooling structure, whereby the gescho bene heat storage element is held securely by the force applied by the wire rows clamping forces.

As already mentioned above, are free flow cross sections between the middle, rectilinear pipe sections of the condenser of great importance for an effective transfer of heat from the condenser to the environment. Against this background may alternatively or additionally edge in the area of the outer pipe bends of the condenser a heat storage element can be arranged. In this way The mounting spaces between the horizontal extending rectilinear pipe sections to increase the flow conditions remain completely free, while only the marginal outer Condenser pipe bends thermal with the heat storage element can be coupled.

Prefers can be on each opposite edge sides the condenser heat storage elements provided be, which extend in the manner of frame strips along the condenser edge sides can.

For a simple holder on the condenser, the heat storage element approximately at right angles to the horizontal condenser tube sections Threaded through this meandering be. The heat storage element can end to Type of loop around a pipe section of the condenser folded and secured.

Especially preferred for effective heat removal from the condenser it is when the marginal heat storage elements in Device side direction outside the front and / or rear condenser cooling structures formed are. In this way, the heat storage elements are in the device side direction not overlapping with the cooling structure arranged. An impairment the operation of the cooling structure due to overlapping arranged heat storage elements can thus be avoided become.

As As described above, the heat storage element for Holder on the condenser meandering and approximately at right angles through the condenser tube sections be guided. Alternatively, the heat storage element outside on the outer pipe bends be placed on the condenser. For one positive connection, the heat storage element have at least one recess into which a pipe bend of the condenser can intervene.

alternative For this purpose, the heat storage element can be an approximately U-shaped Be hollow section part, in the cavity pipe bends of the condenser can claim. In this case, the heat storage element by way of example as an elongated extrusion part, that is in manufacturing technically cheaper by the meter, executed be. The hollow profile part set at the edge of the condenser can the outside pipe bends of the condenser cover like a hood.

The The present invention is applicable to both statically ventilated Condensers applicable as well as forced ventilation Condensers. With such forced ventilation the condenser is assigned a separate fan, passing an air flow through the condenser, which dissipates the condenser heat. Of the Condenser can in a cooling air channel be arranged, in part of at least one heat storage element is limited. Preferably, the heat storage elements be formed as a cooling air channel side walls, between which the condenser is arranged. The heat storage elements can thus in double function in addition as Air guide parts are used.

to Increase of heat removal from the condenser For example, the heat storage element may comprise a material that when absorbed by the cooling process heat its Aggregate state changes. The change of state of aggregation is during a standstill of the refrigeration cycle by heat transfer to the environment again vice versa. The Material may be exemplified by a material fixed in a matrix be that regardless of the actual temperature has the same mechanical properties. This can be used to change the Physical state relevant transition point be warmer than the typical ambient temperatures or those defined in the standards Temperatures for measuring the energy consumption of refrigeration appliances. This ensures that the heat storage element during the refrigeration cycle idle again under the transition point is cooled. For dynamically ventilated The fan can liquefy during the Refrigeration cycle-standing time to be activated, causing the condenser Total can be effectively cooled.

following are three embodiments of the invention with reference to the attached figures described.

It demonstrate:

1 in a perspective view from behind a refrigerator with a condenser with partially inserted heat storage element according to the first embodiment;

2 in an enlarged sectional illustration along the cutting plane II, the inserted into the condenser heat storage element;

3 one of the 2 corresponding view according to a modification;

4 one of the 2 corresponding view according to a further modification;

5 an arrangement of the heat storage element on the condenser according to the second embodiment;

6 in a modification, the heat storage element according to the second embodiment; and

7 According to the third embodiment, provided with heat storage elements forced-ventilated condenser.

In the 1 is in a partial view from the back of a refrigerator 1 with a condenser attached to the back of the housing 3 shown. The condenser 3 is statically ventilated and has a meandering pipe coil with horizontal, straight pipe sections 5 on, which are spaced from each other in a vertical plane arranged one above the other. The according to the 1 middle pipe sections 5 are over side pipe bends 6 in contact with each other.

The condenser 3 has wire rows as front and rear cooling structures 7 . 9 which increase the condenser surface for better heat dissipation. In the 2 a section of the condenser is shown in a side sectional view. As a result, wires of the front and rear wire rows are 7 . 9 about connection points 11 at the respective condenser tube sections 5 attached. The in the 2 shown adjacent pipe sections 5 make up together with the wire rows 7 . 9 a mounting space open in the device side direction in each case 13 , in accordance with the 1 a here exemplified strip-shaped heat storage element 15 is insertable. By way of example, the heat storage element may be an elongated bag filled with a material, wherein the material may change its state of aggregation upon receipt of heat released from the condenser in the cooling process.

Like in the 2 is shown, the strip-shaped heat storage element 15 non-contact via air flow gaps 17 from the upper and lower condenser tube section 5 spaced. In contrast to the prior art is therefore on a direct contact with the condenser tube sections 5 waived. Rather, you can use the airflow column 17 Flow conditions in the area of the condenser 3 be improved so that the efficiency of the heat removal from the condenser 3 is increased.

For a stable mounting of the heat storage element 15 can inside the mounting space 13 as holding elements in the 3 shown wire pieces 19 be provided, for example, via a welded joint on the front and rear wire rows 7 . 9 are attached. The heat storage element 15 is according to the 3 reliable and durable on the two pieces of wire 19 supported.

Alternative to 3 can the width of the heat storage element 15 be dimensioned such that in the installed state clamping forces F _K of the wire rows 7 . 9 on the intermediate heat storage element 15 be exercised as it is in the 4 is shown. In this case, when installing the heat storage element 15 into the liquefier 3 the wires of the wire rows 7 . 9 bend elastically yielding apart so that the strip-shaped heat storage element 15 in the mounting space 13 can be inserted.

In the 5 is in a second embodiment, a rear side provided on the refrigerator condenser 3 with a heat storage element 15 shown. In contrast to the previous figures, the heat storage element 15 according to the 5 in the vertical direction and approximately at right angles to the horizontal condenser tube sections 5 aligned. The strip-shaped heat storage element 15 is approximately meandering in the area of the laterally outer pipe bends 6 through the pipe sections 5 threaded. In this way, the mounting space 13 between the horizontal, straight pipe sections 5 remain completely free, creating a free air convection between the straight pipe sections 5 of the liquefier 3 without impairment by the heat storage element 15 is possible.

The in the 5 not shown left side of the condenser 3 is in the same way with a vertically arranged strip-shaped heat storage element 15 Mistake. Between the two lateral heat storage elements 15 are the wire rows 7 . 9 arranged, without affecting due to einragender heat storage elements, the surface of the condenser 3 enlarge.

The upper end 21 in the 5 shown heat storage element 15 is looped around the top tube section 5 of the liquefier 3 guided and by means of an indicated fastening pin 23 fixed.

In the 6 is in modification to Ausfüh example of the 5 also on the edge of the condenser 3 arranged heat storage element 15 shown. Like in the 5 Here, too, only the right rear of the refrigerator is shown. The left side, not shown, is also substantially mirror-symmetrical, likewise with a peripheral heat storage element 15 educated. In contrast to 5 is in the 6 the heat storage element 15 a rigid, approximately U-shaped hollow profile part. The strip-shaped hollow profile part is hood-like with its open side on the edge pipe bends 6 of the liquefier 3 placed. The one of the U-thighs 24 the heat storage element 5 limited cavity is sized so that the condenser tube bends 6 under construction of a clamping voltage in the heat storage element 15 can be inserted. Like in the 5 are also in the 6 between the two laterally slid heat storage elements 15 the cooling structures 7 . 9 intended.

In the 7 In contrast to the previous embodiments, a refrigeration device with a forced-ventilated condenser 3 together with a compressor 25 and one between the liquefier 3 and the compressor 25 arranged separate fan 27 shown.

The Indian 7 shown device composite, consisting of condenser 3 , Fan 27 and compressors 25 , is in a machine room 28 arranged the refrigeration device. This is formed in a rear bottom area of the refrigerator.

During operation, the fan generates 27 a cooling air flow I flowing through the condenser 3 is pulled. The condenser is here a finned heat exchanger. To prevent a leakage flow past the condenser 3 to avoid is the liquefier 3 in an airtight cooling air duct 30 arranged.

The cooling air duct 30 is in the 7 limited by the upper top wall of the engine room 28 as well as through a lower base plate 32 on which the device group stands. In the Bautiefenrichtung x is the cooling air duct 30 by two edge-sided, vertically arranged heat storage elements 15 limited. These are analogous to 6 laterally on the edge of the condenser pipe bends 6 put on and limit in a dual function airtight the cooling air duct 30 ,

For this purpose, each of the heat storage elements 15 have on its side facing the condenser recesses into which the pipe bends 6 can form-fit.

1

The refrigerator

3

condenser

5

Condenser tube sections

6

Pipe bends of the condenser 3

7, 9

cooling structures

11

access points

13

Mounting space

15

Heat storage element

17

Air flow gap

19

retaining elements

21

upper end of the heat storage element 15

23

fastening pin

24

U-leg of the heat storage element 15

25

compressor

27

fan

28

engine room

30

Cooling air duct

32

baseplate

I

Cooling air flow

x

Bautiefenrichtung

F _K

clamping forces

QUOTES INCLUDE IN THE DESCRIPTION

This list The documents listed by the applicant have been automated generated and is solely for better information recorded by the reader. The list is not part of the German Patent or utility model application. The DPMA takes over no liability for any errors or omissions.

Cited patent literature

• - DE 202006007585 U1 [0003]

Claims (15)

Refrigerating appliance, in particular household refrigerating appliance with a condenser connected in a refrigeration circuit ( 3 ) used as a heat exchanger with pipe sections ( 5 ) is designed to guide the refrigerant, and at least one heat storage element ( 15 ) placed in a mounting space ( 13 ) between the pipe sections ( 5 ) of the liquefier ( 3 ), characterized in that the heat storage element ( 15 ) over at least one predetermined air flow gap ( 17 ) of the pipe sections ( 5 ) of the liquefier ( 3 ) is spaced. Refrigerating appliance according to claim 1, characterized in that the liquefier ( 3 ) a front and / or rear cooling structure ( 7 . 9 ), in particular a wire row, having the mounting space ( 13 ) together with the pipe sections ( 5 ) of the liquefier ( 3 ) limited. Refrigerating appliance according to claim 1 or 2, characterized in that the heat storage element ( 15 ) without contact, in particular approximately in the middle, between two adjacent pipe sections ( 5 ) is arranged. Refrigerating appliance according to one of claims 1 to 3, characterized in that in the mounting space ( 13 ) between the pipe sections ( 5 ) of the liquefier ( 3 ) at least one retaining element ( 19 ) for holding the heat storage element ( 15 ) is provided. Refrigerating appliance according to claim 4, characterized in that the holding element ( 19 ), in particular a holding wire, on the front and / or rear cooling structure ( 7 . 9 ) of the liquefier ( 3 ) is trained. Refrigerating appliance according to one of claims 2 to 5, characterized in that the heat storage element ( 15 ) between the front and rear cooling structure ( 7 . 9 ) of the liquefier ( 3 ) in the mounting space ( 13 ) is clamped. Refrigerating appliance, in particular according to one of the preceding claims, with a liquefier connected in a refrigeration circuit ( 3 ), which is designed as a tube heat exchanger whose straight pipe sections ( 5 ) via pipe bends ( 6 ) and at least one with the condenser ( 3 ) cooperating heat storage element ( 15 ), characterized in that the heat storage element ( 15 ) at the edge in the area of the pipe bends ( 6 ) of the liquefier ( 3 ) is arranged. Refrigerating appliance according to claim 7, characterized in that on opposite, in particular vertical edge sides of the liquefier ( 3 ) each heat storage elements ( 15 ), which extend along the condenser edge sides, and in particular the mounting spaces ( 13 ) between the pipe sections ( 5 ) of the liquefier ( 3 ) set free. Refrigerating appliance according to claim 8, characterized in that between the two edge-side heat storage elements ( 15 ) the front and / or rear cooling structure ( 7 . 9 ) of the liquefier ( 3 ) is trained. Refrigerating appliance according to claim 7, 8 or 9, characterized in that the heat storage element ( 15 ) approximately at right angles to the pipe sections ( 5 ) meandering through the pipe sections ( 5 ) is threaded. Refrigerating appliance according to one of claims 7 to 10, characterized in that the heat storage element ( 15 ) has at least one recess into which a pipe bend ( 6 ) of the liquefier ( 3 ) protrudes. Refrigerating appliance according to one of claims 7 to 11, characterized in that the heat storage element ( 15 ) is an approximately U-shaped hollow profile part, in whose cavity the pipe bends ( 6 ) of the liquefier ( 3 ) protrude. Refrigerating appliance, in particular according to one of the preceding claims, with a liquefier connected in a refrigeration circuit ( 3 ), which by means of a fan ( 27 ), which condenser ( 3 ) in a cooling air channel ( 30 ), characterized in that the cooling air duct ( 30 ) at least partially of at least one heat storage element ( 15 ) is limited. Refrigerating appliance according to claim 13, characterized in that the heat storage elements ( 15 ) are formed as cooling air channel side walls, between which the condenser ( 3 ) is arranged. Refrigerating appliance according to one of the preceding claims, characterized in that the heat storage element ( 15 ) has a material which, when taken up in the refrigeration process by the liquefier ( 3 ) emitted heat changes its state of aggregation.