WO2016078894A1 - Refrigeration appliance comprising a cold air duct - Google Patents

Abstract

The invention relates to a refrigeration appliance (100) comprising a cold air feeding element (113) which includes a cold air duct (115) for delivering cold air into an interior (103) of the refrigeration appliance (100) and which is located on a side (105, 107, 109, 111) of the interior (103) of the refrigeration appliance that further comprises a closure element (121) for closing the cold air duct (115). The refrigeration appliance (100) also comprises a sealing element (131) which is integrally bonded in a sealing manner to the cold air feeding element (113) and to the closure element (121).

Description

 Refrigerating appliance with a cold air duct

The present invention relates to a refrigeration device with a cold air duct.

During operation of a refrigerating appliance, the cold air generated by the refrigeration circuit of the refrigerating appliance is fed through a cold air duct to a refrigerating appliance interior of the refrigerating appliance. In order to regulate the supply of cold air, the cold air duct has a closure element, which is designed to close or release the cold air duct. If the closure element and the cold air duct are not adequately sealed, cold air can escape from the cold air duct during operation of the refrigeration device on the closure element.

It is the object of the present invention to provide a refrigeration device, in which an effective supply of cold air through a cold air duct is ensured in a refrigerator interior of the refrigerator.

This object is achieved by an article having the features according to the independent claim. Advantageous embodiments are the subject of the dependent claims, the description and the drawings. According to one aspect, the object of the invention by a refrigeration device with a cold air supply element, wherein the cold air supply element comprises a cold air duct for supplying cold air into a refrigerator interior of the refrigerator, wherein the cold air supply element is disposed on one side of the refrigerator interior, and solved with a closure element for closing the cold air duct wherein the refrigeration device comprises a sealing element, and wherein the sealing element is positively sealingly connected to the cold air supply element and with the closure element.

As a result, the technical advantage is achieved, for example, that the positive sealing connection of the sealing element with the cold air supply element and with the closure element is achieved in that the sealing element fills a positive connection, whereby any gaps between the Cold air supply element and the closure element are filled. As a result, the cold air duct can be sealed airtight.

Due to the positive sealing connection, an effective airtight closure of the cold air duct and the closure element can be ensured. Due to the airtight sealing by the sealing element, it is avoided that the cold air from the cold air duct is split by a gap in a space in the interior of the refrigerating appliance, such as e.g. the space between an outer wall of the refrigerator and the cold air supply element, escape and then can penetrate into the refrigerator interior. Thus, can be achieved by the positive sealing connection, that the cold air is supplied to the refrigeration device interior through the closure element exclusively by the cold air channel upon release of the cold air duct.

The positive sealing connection can also be achieved by closing the cold air duct through the closure element that no cold air flows past the closure element, whereby further effective interruption of the cold air flow in the cold air duct can be achieved. In addition, it is avoided by the positive sealing connection that moisture from the outside of the refrigerator can penetrate to the cold air duct and the closure member, and can condense on the cold surface of said elements, whereby the amount of condensation formed on the cold air duct and on the closure element can be reduced.

In conventional refrigeration devices, a sealing of the cold air duct is often carried out by the use of a plurality of sealing strips, wherein the sealing stiffeners are fixed by a cover to the cold air duct. The closure element arranged in the cold air duct can often not be completely sealed, since the geometry of the closure element often does not permit satisfactory closure. Thus, in conventional refrigerators escape by a not completely effective seal, cold air from the cold air duct by gaps between the closure element and the cold air duct in a space in the interior of the refrigerator. Thus, by using the sealing element according to the invention in the assembly of the refrigerator in a simple and advantageous manner, a positive sealing connection between the sealing element, cold air duct and closure element can be realized. This avoids that the cold air can escape from the cold air duct and penetrate into the interior of the refrigerator. As a result, an effective supply of cold air through the cold air duct into the refrigerator interior can be ensured during operation of the refrigerator.

A refrigeration appliance is understood in particular to mean a domestic refrigeration appliance, that is to say a refrigeration appliance that is used for household management or in the gastronomy sector, and in particular for storing food and / or drinks at specific temperatures, such as, for example, a refrigerator, a freezer, a refrigerated freezer combination, a freezer or a wine fridge.

In an advantageous embodiment of the refrigeration device, the cold air duct has a rounded channel limiting area for conducting the cold air.

As a result, the technical advantage is achieved that the rounded channel boundary region of the cold air duct ensures advantageous flow properties of the cold air guided through the cold air duct. In conventional refrigeration devices elements are introduced into the cold air duct when inserting the closure element into the cold air duct, which have, for example, surfaces, edges or hard transitions, and which are responsible for a high flow resistance of the guided through the cold air duct cold air. This can lead to the formation of air vortices in the region of the elements, whereby a strong local cooling of the surface of the cold air duct can be caused, whereby the amount of condensation at the locally cooled point of the surface of the cold air duct can be increased.

By arranging a rounded channel boundary region in the cold air duct, a geometrically advantageously shaped surface is introduced into the cold air duct, at which the cold air can advantageously be conducted past without the formation of strong swirling of the air. As a result, a strong cooling of the corresponding surface area of the cold air duct is avoided, and the amount of condensed water formed on the surface of the cold air duct can be reduced. In a further advantageous embodiment of the refrigeration device, the sealing element has a sealing surface with a smooth surface which can be pressed against the cold air feed element and against the closure element. This achieves the technical advantage that by using the sealing element with the sealing surface, which has a smooth surface, by pressing the sealing element against the cold air supply element and against the closure element, an advantageously formed positive connection between said elements can be produced. The form-fitting sealing connection is characterized in particular in that there are no gaps or cavities between the elements, through which cold air can escape from the cold air duct and penetrate into the interior of the refrigeration device, whereby a complete sealing can be achieved. As a result, an effective supply of cold air through the cold air duct to the refrigerator interior during operation of the refrigerator can be ensured.

In a further advantageous embodiment of the refrigeration device, the sealing surface has an elevation or a depression on the smooth surface, in particular a rib or a groove.

Thereby, the technical advantage is achieved that by the arrangement of the increase or the depression on the smooth surface of the sealing surface, when pressing the sealing surface to the cold air supply element and the closure element, the increase, such as the rib, or the recess, such as the groove is effectively compressible with the surface of the cold air supply member and the shutter member. Due to the strong pressure that arises when pressing the sealing surface, the increase or depression can be deformed and thereby advantageously a positive sealing connection can be made. For example, an increase in the surface area of the cold air supply element or the closure element may be introduced into the depression on the surface of the sealing surface. Or the increase in the sealing surface can be introduced into a depression on the surface of the cold air supply element or the closure element in order to produce an advantageously positive sealing connection. In a further advantageous embodiment of the refrigeration device, the cold air feed element has a receiving region for receiving the sealing element, wherein the sealing element has an insertion region, and wherein the insertion region is insertable into the receiving region.

As a result, the technical advantage is achieved that an effective and advantageous form-fitting sealing connection between the sealing element, the cold air supply element and the closure element can be produced by introducing the insertion of the sealing element in the receiving area of the cold air supply element. The advantageous compound formed can have a particular stability by pressing the elements.

In a further advantageous embodiment of the refrigeration device, the refrigeration device comprises a fixing element on an outer wall of the refrigeration device in order to fix the cold air feed element to the outer wall of the refrigeration device.

As a result, the technical advantage is achieved that an effective fixation of the cold air supply element is achieved on the outer wall of the refrigerator by the fixing. For example, the outer wall of the refrigerator is a rear wall of the refrigerator. The fixing element may comprise a fastening clip which can be snapped into a projection on one side of the cold air supply element to ensure effective fixation of the cold air supply element to the outer wall of the refrigeration device. In a further advantageous embodiment of the refrigeration device, the cold air supply element is arranged on the rear side of the refrigerator interior.

As a result, the technical advantage is achieved that an effective supply of cold air is achieved by the cold air duct in the refrigeration device interior by the arrangement of the cold air supply element at the back of the refrigeration device interior, since the cold air supply element can be particularly advantageous connected to the back of the refrigerator interior with the refrigeration cycle of the refrigerator without restricting access to the refrigerator interior for the user. In particular at the back of the refrigerator, which is usually located near a wall, there is sufficient space to attach the cold air supply element to the refrigerator.

In a further advantageous embodiment of the refrigeration device, the cold air feed element or the sealing element made of plastic, preferably made of expanded polystyrene (EPS) or expanded polypropylene (EPP).

As a result, the technical advantage is achieved that an effective sealing of the cold air supply element or closure element can be achieved by the sealing materials by the said materials. The use of plastics is particularly advantageous, since plastics are simple and easy to process, and thereby the said elements can be brought into the desired shape, which is required to produce a positive sealing connection between the cold air supply element, the closure element and the sealing element. In particular, plastic is resistant to water and oxidation and can thus ensure an airtight seal of the cold air duct during the service life of the refrigerator. The plastic preferably consists of expanded polystyrene (EPS).

In a further advantageous embodiment of the refrigeration device, the closure element comprises a closure flap for closing the cold air channel.

As a result, the technical advantage is achieved that an effective control of the supply of cold air through the cold air duct can be ensured by the closure flap of the closure element. The closure flap is fastened to the closure element on one side and can be moved between two positions. In a first position, the closure flap is in an open state and thereby releases the cold air channel, as a result of which cold air can flow through the cold air channel and can then be supplied to the refrigerator interior. If the closure flap is moved from the first position to a second position, the closure flap closes the cold air channel, whereby the cold air flow in the cold air channel is stopped and thus the supply of cold air into the refrigerator interior can be interrupted. Thus, the closure flap can be used to effectively control the supply of cold air into the refrigeration device interior. In a further advantageous embodiment of the refrigeration device, the closure element has a closure base, wherein the closure base is arranged in the cold air channel, wherein the closure flap has a closure seal, and wherein the closure seal against the closure base can be pressed to close the cold air channel.

As a result, the technical advantage is achieved that an effective closing of the cold air duct can be realized by pressing the closure seal of the closure flap to the closure base. The closure flap has a closure seal, e.g. may be made of plastic or foam, and which is designed to effect on contact with the closure base effective closure of the cold air duct. The closure base may comprise, for example, a frame, a plate with openings or a bar which is mounted in the closure element. The closure base is designed such that in the first position of the closure flap when it releases the cold air channel, it does not significantly hinder the supply of cold air through the cold air channel. When the closure flap is moved to the second position, the closure base contacts the closure flap, particularly the closure seal, to ensure effective closure of the cold air channel.

In a further advantageous embodiment of the refrigeration device, the refrigeration device comprises a control connection for controlling the closure element, wherein the control connection between the cold air supply element and the sealing element is arranged.

Thereby, the technical advantage is achieved that electrical energy can be passed through the control connection to the closure element in order to ensure the function of the closure element. In particular, electric current is supplied through the control connection to the shutter member to operate a shutter operation of the shutter member or a release operation of the shutter member. In order to avoid the ingress of condensed water into the control connection, which could lead to a short circuit, it is also crucial for the control connection to realize an effective seal. An effective Sealing of the control connection is achieved by arranging the control connection between the cold air supply element and the sealing element. Due to the positive sealing connection of the sealing element, cold air supply element and closure element, an effective sealing of the control connection is also achieved.

In a further advantageous embodiment of the refrigeration device, the cold air feed element comprises at least one fastening element and a fastening region in order to achieve an effective attachment of the cold air feed element to the refrigeration device.

This achieves the technical advantage that the at least one fastening element can be accommodated in at least one recess of a receiving region of the refrigeration device, and that the fastening region can come into contact with a further receiving region of the refrigeration device, whereby an effective attachment of the cold air supply element to the refrigeration device is achieved ,

In a further advantageous embodiment of the refrigeration device includes the

Cold air supply element is a water drainage channel, wherein the water drainage channel is arranged within the cold air supply element to divert condensed water from the cold air supply element.

This achieves the technical advantage that condensation water condensed within the cold air supply element can be taken up by the water drainage channel and can be discharged through the water drainage channel from the cold air supply element. This prevents that large amounts of condensation accumulate within the cold air supply element, which can penetrate through the cold air duct, for example, to the closure element. The water drainage channel may exit through an opening from the cold air supply element to drain condensed water from the cold air supply element.

In a further advantageous embodiment of the refrigeration device, the sealing element comprises a further water drainage channel, wherein the wide water drainage channel on one side of the sealing member is arranged to remove condensed water from the sealing member.

As a result, the technical advantage is achieved that condensed condensation water can be absorbed by the further water drainage channel on the side of the sealing element, and can be derived from the sealing element by the further water drainage channel. By discharging larger amounts of condensed water from the side of the sealing member, large amounts of condensed water are prevented from accumulating on the side of the sealing member. Thus, the further water drainage channel is particularly advantageous to prevent the positive sealing connection between sealing element, cold air supply element and the closure element is impaired by the ingress of water, and thus the air-tight seal can not be guaranteed. In particular, the further drainage channel is arranged on the rear side of the sealing element. Thus, the penetration of condensed water can be effectively prevented by the use of the further water drainage channel.

In a further advantageous embodiment of the refrigeration device, the refrigeration device comprises a heating element for heating the closure element or the cold air feed element.

Thereby, the technical advantage is achieved that can be heated by the use of the heating element in the unlikely ingress of condensation, the closure element or the cold air supply element by the heating element. The heat generated by the heating element can potentially quickly evaporate condensed water. The heating element may comprise an electrical heating element which is arranged on the cold air supply element, on the closure element or on the sealing element. The heating element may comprise a heating element disposed on one or more of said elements and configured to dissipate heat from another component of the refrigeration device, such as from a condenser, and the heat dissipated to the closure element or to the cold air supply element to heat the closure member or the cold air supply member. Further embodiments will be explained with reference to the accompanying drawings. Show it:

Fig. 1 is a schematic representation of a refrigerator; Figure 2 is a schematic representation of a cold air supply element in a refrigeration device.

Fig. 3 is a schematic representation of a cold air supply element in side view; 4 is a schematic representation of a cold air supply element in front view; and

Fig. 5 is a schematic representation of a cold air supply element in rear view. Fig. 1 shows a refrigerator representative of a general refrigeration device 100 with a refrigerator door 101 for closing a refrigeration device interior 103 of the refrigerator 100. The refrigerator interior 103 has two longitudinal sides 105, a bottom 107, a top 109 and a back 1 1 1 on. The refrigeration device 100 includes a refrigeration cycle with an evaporator, compressor, condenser and throttle body. The evaporator is a heat exchanger in which, after expansion, the liquid refrigerant is vaporized by absorbing heat from the medium to be cooled, eg air. The compressor is a mechanically operated component that draws refrigerant vapor from the evaporator and expels it at a higher pressure to the condenser. The condenser is a heat exchanger in which, after compression, the vaporized refrigerant is liquefied by dissipating heat to an external cooling medium, eg air. The throttle body is a device for the continuous reduction of the pressure by cross-sectional constriction. The refrigerant is a fluid used for heat transfer in the cryogenic system which absorbs heat at low temperatures and low pressure of the fluid and releases heat at higher temperature and higher pressure of the fluid, usually including changes in state of the fluid. Fig. 2 shows a schematic representation of a cold air supply element in a refrigeration device. In the selected view of the refrigeration device 100, the upper side 109, the front side and one of the longitudinal sides 105 of the refrigerator interior 103 are not shown. The refrigeration device interior 103 shown in FIG. 2 has a longitudinal side 105, a lower side 107, and a rear side 1 1 1. The cold air feed element 1 13 is arranged on the rear side 1 1 1 of the refrigeration device interior 103 and comprises a cold air duct 1 15, which is designed to supply cold air from the refrigeration appliance circuit of the refrigeration device 100 to the refrigeration device interior 103 of the refrigeration device 100.

Fig. 3 shows a schematic representation of a cold air supply element in side view. The cold air supply element 1 13 has a rear side 1 17 which is in communication with an outer wall of the refrigeration device 100 and has a front side 1 19, which communicates with the rear side 1 1 1 of the refrigerator interior 103.

The cold air supply member 1 13 includes a cold air duct 1 15 extending from an upper portion of the cold air supply member 1 13 to a lower portion of the cold air supply member 1 13 through the cold air supply member 1 13 and which is adapted to direct cold air, then the refrigeration unit interior

103 of the refrigeration device 100 supply.

The refrigeration device 100 further includes a closure element 121, which is inserted into the cold air supply element 1 13 and into the cold air duct 1 15. The closure element 121 is designed to close the cold air duct 1 15 in order to stop the cold air flow in the cold air duct 15, and thereby prevent the supply of cold air into the refrigeration appliance interior 103 of the refrigeration appliance 100. The closure element 121 comprises a closure flap 123, which is fastened on one side to the closure element 121 and which is pivotable into the cold air channel 15, thereby closing the cold air channel 15 in a closed position in order to reduce the flow of cold air in the cold air channel 1 15 to stop. In Fig. 3, the closure flap 123 is shown in a release position in which it does not close the cold air duct 1 15, but releases. The closure flap 123 comprises a closure seal 125, which is arranged on one side of the closure flap 123. When closing the cold air duct 15, the closure seal 125 of the closure flap 123 can be pressed against a closure base 127 in order to close the cold air channel 15. The closure base 127 may, for example, a Bar or a plate with openings, and is arranged in the cold air duct 1 15 that the closure base 127, the cold air flow in the cold air duct 1 15 without the closure flap 123 does not significantly hindered.

The cold air duct 15 further comprises a rounded channel limiting area 129. The rounded channel limiting area 129 has a rounded surface and a flow-optimized shape. As a result, the guided past the rounded channel boundary region 129 cold air is advantageously deflected, whereby no air vortex in the cold air duct 1 15 form, whereby a strong local cooling of the surface of the cold air duct 1 15 can be prevented.

The refrigeration device 100 further comprises a sealing element 131, which is attached to the rear side 17 of the cold air feed element 1 13 and which is positively sealingly connected to the cold air feed element 1 13 and the closure element 121. The sealing element 131 comprises, in particular, a sealing surface 133 which can be pressed against the surface of the closure element 121 and against the surface of the cold air supply element 13 in order to seal the cold air channel 15 in airtight manner. Thus, in the area of the closure element 121 next to the sealing element 131, no further sealing measures are necessarily necessary. In addition, the cold air supply element 1 13 by a fixing element, such as. be fixed by a mounting clip on the rear wall of the refrigerator 100.

The sealing member 131 further includes an insertion portion 135 which can be inserted into a receiving portion 137 of the cold air supply member 1 13 to achieve a particularly effective airtight sealing of the cold air duct 1 15.

4 shows a schematic representation of a cold air feed element according to FIG. 3 in front view, so that the front side 19 of the cold air feed element 13 is visible. The refrigeration device 100 further comprises a control connection 139, which is designed to conduct electrical energy to the closure element 121 in order to enable a closure or opening process of the closure flap 123. The control connection 139 is arranged between the cold air supply element 13 and the sealing element 131, wherein the sealing element 131 is not visible in the selected view. By the arrangement of the control connection 139 between the Cold air supply element 13 and the sealing element 131 ensure effective sealing of the control connection 139, and it is prevented that condensation water can penetrate the control connection 139 and possibly cause a short circuit. The refrigeration device 100 further comprises a fastening element 141 and a further fastening element 143, as well as a fastening region 145 in order to fix the cold air feed element 1 13 to corresponding further receiving regions of the refrigeration device 100. Fig. 5 shows a schematic representation of a cold air supply element according to FIG. 3 in rear view, so that the back 1 17 of the cold air supply element 1 13 is visible. The sealing member 131 is positively sealingly connected to the cold air supply element 1 13 and the closure member 121, wherein the closure member 121 can not be shown in the selected view, since it is located in the plane behind the sealing member 131. The cold air feed element 1 13 comprises a control connection 139, comprises a fastening element 141 and a further fastening element 143, and a fastening region 145 for fastening the cold air feed element 1 13 to corresponding further receiving regions of the refrigeration device 100.

The cold air supply element 1 13 further comprises a water drainage channel 147, which is designed to remove condensed water from the cold air supply element 1 13. The water drainage channel 147 is disposed within the cold air supply element 1 13. The sealing element 131 further comprises a further water drainage channel 149, which is designed to remove condensed water from the sealing element 131. The further water drainage channel 149 is attached to one side of the sealing element 131, preferably on the rear side. The water drainage channel 147 and the further water drainage channel 149 are arranged obliquely in order to allow the drainage of condensed water due to gravity, and to discharge the draining condensation water into a non-critical region of the refrigeration device 100.

Due to the compact arrangement of cold air supply element 1 13, closure member 121 and sealing member 131 is an effective seal of the cold air duct 1 15 and the Closing element 121 without additional foam parts possible. In addition, a noise reduction of the refrigeration device 100 is achieved. By pressing the fastening element 141, the further fastening element 143 and the fastening region 145 to corresponding further receiving regions of the refrigeration device 100, a stable attachment of the cold air feed element 1 13 is achieved. The water gutter 147 and the further water gutter 149 serve to dissipate potentially occurring condensation, whereby the cold air duct 1 15, an existing in the cold air duct 1 15 fan and the closure member 121 are protected against the ingress of condensation. By the control connection 139, which is arranged between the cold air supply element 1 13 and the sealing element 131, the cold air supply element 1 13 can be advantageously installed during assembly of the refrigeration device 100, and the control connection 139 can be easily connected to the power supply of the refrigeration device 100.

Due to the effective sealing, the separate heating of the closure element 121 by a heating element is no longer absolutely necessary, whereby costs in the refrigeration device 100 can be saved, and the installation of the refrigeration device 100 is simpler and less expensive.

All of the features explained and shown in connection with individual embodiments of the invention may be provided in different combinations in the article according to the invention in order to simultaneously realize their advantageous effects.

The scope of the present invention is given by the claims and is not limited by the features illustrated in the specification or shown in the figures. LIST OF REFERENCE NUMBERS

100 refrigeration unit

 101 refrigerator door

 103 refrigerator interior

 105 Longitudinal side of the refrigerator interior

 107 Bottom of the refrigeration unit interior

 109 top of refrigeration unit interior

 1 1 1 Rear of the refrigeration unit interior

 1 13 cold air supply element

 1 15 cold air duct

 117 Rear side of the cold air supply element

1 19 Front side of the cold air supply element

121 closure element

 123 flap

 125 sealing seal

 127 lock socket

 129 Rounded channel limitation area

 131 sealing element

 133 sealing surface

 135 insertion area

 137 Recording area

 139 control connection

 141 fastening element

 143 Another fastening element

 145 mounting area

 47 water drainage channel

 149 Further water drainage channel

Claims

Refrigerating appliance (100) with a cold air supply element (1 13), wherein the cold air supply element (1 13) comprises a cold air duct (1 15) for supplying cold air into a refrigerator interior (103) of the refrigeration device (100), wherein the cold air supply element (1 13) a side (105, 107, 109, 1 1 1) of the refrigeration device interior (103) is arranged, and with a closure element (121) for closing the cold air duct (1 15), characterized in that

the refrigeration device (100) comprises a sealing element (131), wherein the sealing element

(131) with the cold air supply element (1 13) and with the closure element (121) is positively sealingly connected

Refrigeration appliance (100) according to claim 1, characterized in that the cold air duct (1 15) has a rounded channel boundary region (129) for conducting the cold air.

Refrigeration appliance (100) according to claim 1 or 2, characterized in that the sealing element (131) has a sealing surface (133) with a smooth surface which against the cold air feed element (1 13) and against the closure element (121) can be pressed.

Refrigeration appliance (100) according to claim 3, characterized in that the sealing surface (133) has an elevation or a depression on the smooth surface, in particular a rib or a groove.

Refrigeration appliance (100) according to one of the preceding claims, characterized in that the cold air feed element (1 13) has a receiving area (137) for receiving the sealing element (131), that the sealing element (131) has an insertion region (135), and that Insertion region (135) in the receiving area (137) is insertable.

Refrigeration appliance (100) according to one of the preceding claims, characterized in that the refrigeration device (100) comprises a fixing element on an outer wall of the refrigeration device (100) to fix the cold air supply element (1 13) on the outer wall of the refrigeration device (100).

Refrigeration appliance (100) according to one of the preceding claims, characterized in that the cold air feed element (1 13) on the back (1 1 1) of the refrigerator interior (103) is arranged.

Refrigerating appliance (100) according to one of the preceding claims, characterized in that the cold air feed element (1 13) or the sealing element (131) consists of plastic, preferably expanded polystyrene (EPS) or expanded polypropylene (EPP).

Refrigeration appliance (100) according to one of the preceding claims, characterized in that the closure element (121) comprises a closure flap (123) for closing the cold air duct (1 15).

10. Refrigerating appliance (100) according to claim 9, characterized in that the closure element (121) has a closure base (127), wherein the

Closure base (127) is arranged in the cold air duct (15), in that the closure flap (123) has a closure seal (125), and in that the closure seal (125) can be pressed against the closure base (127) to form the cold air channel (11) to close.

1 1. Refrigeration appliance (100) according to one of the preceding claims, characterized in that the refrigeration device (100) comprises a control connection (139) for controlling the closure element (121), wherein the control connection (139) between the cold air feed element (1 13) and the sealing element ( 131) is arranged.

12. Refrigerating appliance (100) according to one of the preceding claims, characterized in that the cold air feed element (1 13) at least one Attachment (141, 143) and a mounting portion (145) to achieve an effective attachment of the cold air supply element (1 13) to the refrigeration device (100).

13. Refrigerating appliance (100) according to one of the preceding claims, characterized in that the cold air supply element (1 13) a water drainage channel

(147), and that the water drainage channel (147) is disposed inside the cold air supply element (1 13) to discharge condensed water from the cold air supply element (1 13).

14. Refrigerating appliance (100) according to one of the preceding claims, characterized in that the sealing element (131) comprises a further water drainage channel (149), and that the further water drainage channel (149) is arranged on one side of the sealing element (131) to condensation from the sealing element (131) dissipate.

15. Refrigerating appliance (100) according to one of the preceding claims, characterized in that the refrigeration device (100) comprises a heating element for heating the closure element (121) or the cold air supply element (1 13).