WO2017050542A1

WO2017050542A1 - Cooling device comprising a coolant evaporator assembly

Info

Publication number: WO2017050542A1
Application number: PCT/EP2016/070768
Authority: WO
Inventors: Markus Arbogast; Frank Cifrodelli; Marcus WEHLAUCH; Felix Wiedenmann
Original assignee: BSH Hausgeräte GmbH
Priority date: 2015-09-25
Filing date: 2016-09-02
Publication date: 2017-03-30
Also published as: DE102015218453A1

Abstract

The invention relates to a cooling device (100) comprising a coolant evaporator assembly (115), wherein the coolant evaporator assembly (115) has a first assembly region (117) with a coolant evaporator (123) for cooling air and a second assembly region (119) with a fan (127) for conveying air, wherein the first and second assembly region (117, 119) are fluidically connected via an air channel (143), the fan (127) is fluidically connected to the air channel (143), in order to supply air from the first assembly region (117) to the second assembly region (119), and a heating element (141) for heating the coolant evaporator (123) is arranged in the first assembly region (117). The heating element (141) is designed to heat the coolant evaporator (123) during a defrosting process, in order to melt ice accumulated on the coolant evaporator (123). The first assembly region (117) has a receiving region (135), arranged above the coolant evaporator (123), wherein the receiving region (135) is designed to receive the water vapour generated by the heating element (141) during the melting process.

Description

Refrigerating appliance with a refrigerant evaporator unit

The present invention relates to a refrigeration device with a refrigerant evaporator unit.

During operation of the refrigerant circuit of a refrigeration device, the cooling area of the refrigeration device is cooled. Among other things, the refrigerant circuit comprises a refrigerant evaporator, on the cooled surface of which ice can accumulate. In order to remove the ice from the surface of the refrigerant evaporator, heating elements for heating the refrigerant evaporator are used. However, the water vapor generated during the melting process can condense and freeze on the cold surfaces of a fan of the refrigeration device, whereby ice accumulation can form on the fan.

In DE 10 201 1 1 17 930 A1, a refrigerator with a refrigerant circuit is described, wherein the refrigeration device has a cooling air passage, in which a refrigerant evaporator and a fan is arranged, wherein the fan is spatially spaced from the refrigerant evaporator.

In JP 2015 000 303 A, a refrigerator with a fan is disclosed, which supplies an air flow to a refrigerant evaporator, wherein the cooled air is supplied through an air passage of a cooling chamber. The refrigeration device further has a heater, which is designed to heat the air surrounding the refrigerant evaporator.

It is the object of the present invention to provide a refrigeration device with a refrigerant evaporator unit with a fan, with Eisanlagerungen be reduced to the fan.

This object is achieved by an article having the features according to the independent claims. Advantageous embodiments are the subject of the dependent claims, the description and the drawings.

According to one aspect, the object of the invention is achieved by a refrigeration device with a refrigerant evaporator unit, wherein the refrigerant evaporator unit a first aggregate portion having a refrigerant evaporator for cooling air and a second aggregate portion having a fan for conveying air, wherein the first and second unit region are fluidly connected by an air duct, wherein the fan is fluidly connected to the air duct to supply air from the first In the first unit area, a heating element for heating the refrigerant evaporator is arranged, wherein the heating element is configured to heat the refrigerant evaporator during a defrosting operation to melt attached to the refrigerant evaporator ice, and wherein the first aggregate portion Receiving area, which is arranged above the refrigerant evaporator, wherein the receiving area is adapted to receive the water vapor generated by the heating element during melting.

Thereby, for example, the technical advantage is achieved that can be melted by the heating element attached to the refrigerant evaporator ice, and the resulting during the melting of water vapor can be absorbed in the receiving area of the first unit area. The absorption of the water vapor in the receiving region prevents the water vapor from the first aggregate region from being conveyed through the air channel into the second aggregate region and condensing and freezing on the fan, as a result of which ice formation on the fan can be reduced.

In conventional refrigerant evaporator units, the fan is located above the refrigerant evaporator, with the fan drawing in the air through the refrigerant evaporator. In a defrost cycle, the refrigerant evaporator is heated, allowing water vapor to rise and condense and freeze on the fan. As a result, ice deposits can form, whereby the operation of the fan can be disturbed.

In the refrigerant evaporator unit according to the invention, the refrigerant evaporator and the fan are arranged in spatially separate unit regions, which are fluidly connected to each other by an air duct. In the first unit area, a heating element, such as a radiant heater or an electrical contact heater, is further arranged to the To heat the refrigerant evaporator during defrosting. During the defrosting process, both water and water vapor are formed, wherein in particular the resulting water in the first unit region flows down from the refrigerant evaporator. The water vapor generated during the defrosting process rises in the first unit region and collects in the receiving region arranged above the refrigerant evaporator. Upon reactivation of the refrigerant evaporator after defrosting, the water vapor bypasses the refrigerant evaporator and freezes on the cold surface of the refrigerant evaporator, thereby significantly reducing the moisture in the conveyed air. Thus, the absorption of water vapor in the receiving area arranged above the refrigerant evaporator prevents the steam from being transferred from the first unit area through the air duct into the second unit area after the end of the defrosting phase, where it may optionally condense and freeze there on the fan. 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 refrigerator, the receiving area is designed as a U-shaped bent siphon for receiving water vapor, wherein the U-shaped bent siphon is arranged in particular on an upper side of the first unit area.

As a result, the technical advantage is achieved that a particularly effective absorption of water vapor is achieved during the defrosting by the U-shaped siphon. In particular, the U-shaped siphon has an inverted U-shape. In particular, the U-shaped bent siphon is arranged on an upper side of the first aggregate region. This allows the water vapor to collect at the top of the siphon without escaping from the siphon. In a further advantageous embodiment of the refrigeration device, the first aggregate region is separated from the second aggregate region by a dividing wall, wherein the dividing wall is designed in particular as a thermally conductive dividing wall. Thereby, the technical advantage is achieved that is prevented by the partition wall between the first unit area and the second unit area, that during the activation of the heating element of the refrigerant evaporator evaporated steam can pass from the first unit area in the second unit area. Through a thermally conductive partition, among other things, the available area for heat exchange of the refrigerant evaporator can be increased.

In a further advantageous embodiment of the refrigeration device, the heating element is arranged below the refrigerant evaporator in the first unit region. Thereby, the technical advantage is achieved that can be effectively heated by said arrangement of the heating element in the first unit area of the refrigerant evaporator and the resulting water vapor can rise unhindered in the first unit area upwards to be received in the receiving area.

In a further advantageous embodiment of the refrigeration device, the first unit region has a Wasserableitoffnung for discharging water from the first unit region, wherein the Wasserableitoffnung is arranged in particular on a lower side of the first unit region.

Thereby, the technical advantage is achieved that can be derived by the Wasserableitoffnung from the first unit area by the arrangement of the Wasserableitoffnung at the bottom of the first unit region in the heating of the refrigerant evaporator resulting and in the first unit area down flowing water.

In a further advantageous embodiment of the refrigeration device, the refrigerant evaporator unit has a supply line for supplying air into the first Aggregate, wherein the supply line is fluidly connected to the first unit region through an input port, and wherein the input port is arranged in particular on an upper side of the first unit region.

This achieves the technical advantage that air can be efficiently supplied to the refrigerant evaporator in the first unit section through the supply line and through the input port, whereby effective cooling of the air can be ensured. The arrangement of the inlet opening at the top of the first unit area ensures, in particular, that air in the first unit area flows from the top of the first unit area to an underside of the first unit area, so that water vapor rising during the defrosting operation in the first unit area does not flow into the second unit area Can reach aggregate area.

In a further advantageous embodiment of the refrigeration device, the first unit region is fluidly connected to the air channel through an outlet opening, wherein the outlet opening is arranged in particular on a lower side of the first unit region.

Thereby, the technical advantage is achieved that the cooled by the refrigerant evaporator air from the first unit region can be promoted through the outlet opening and through the air duct effectively into the second unit area. The arrangement of the outlet opening on the underside of the first unit area ensures, in particular, that air in the first unit area flows from an upper side of the first unit area to the lower side of the first unit area, so that steam arising during the defrosting process can not get into the second unit area.

In a further advantageous embodiment of the refrigeration device, the refrigerant evaporator has a front side which faces a cooling region of the refrigeration device, wherein the air channel is arranged on the front side of the refrigerant evaporator in order to fluidly connect the first aggregate region and the second aggregate region. Thereby, the technical advantage is achieved that is increased by the arrangement of the air channel at the front of the refrigerant evaporator, the area available for heat exchange of the refrigerant evaporator, thereby increasing the efficiency of the refrigerant circuit. In addition, the arrangement of the air duct on the cooling region of the refrigeration appliance facing front side of the refrigerant evaporator results in an advantageous isolation of the cooling area relative to the refrigerant evaporator.

In a further advantageous embodiment of the refrigeration device, the refrigerant evaporator has a rear side which faces a rear wall of the refrigeration device, the air channel being arranged on the rear side of the refrigerant evaporator in order to fluidly connect the first aggregate region and the second aggregate region.

Thereby, the technical advantage is achieved that is increased by the arrangement of the air duct at the back of the refrigerant evaporator, the area available for heat exchange of the refrigerant evaporator and the air duct can be arranged in a particularly space-optimized in the refrigerant evaporator unit.

In a further advantageous embodiment of the refrigeration device, the refrigerant evaporator unit has a further air channel, which fluidly connects the first unit region and the second aggregate region, wherein the further air channel is arranged on the front side or on the rear side of the refrigerant evaporator. As a result, the technical advantage is achieved that, in addition to the air duct, a particularly effective conduction of air from the first unit region into the second unit region is ensured by the further air duct.

In a further advantageous embodiment of the refrigeration appliance, the refrigerant evaporator unit has a partition, which is arranged between the refrigerant evaporator and the air duct, wherein the separation consists in particular of a thermally conductive material. As a result, the technical advantage is achieved that an effective spatial separation between the refrigerant evaporator and the air duct is ensured by the separation. In addition, when the partition is made of a thermally conductive material, the area of the refrigerant evaporator available for heat exchange is increased.

In a further advantageous embodiment of the refrigeration device, the refrigeration device has a number of ventilation channels, which fluidly connect the second unit area with a cooling area of the refrigeration device. As a result, the technical advantage is achieved that the air sucked in by the fan can be conveyed from the second unit region through the ventilation channels into the cooling region of the refrigeration device. In particular, the refrigeration device may have a ventilation channel or a plurality of ventilation channels in order to supply the conveyed air to different cooling compartments of the cooling area.

In a further advantageous embodiment of the refrigeration device, the refrigerant evaporator has fins to allow an efficient heat exchange between the refrigerant evaporator and the air. As a result, the technical advantage is achieved that a particularly effective heat exchange between the refrigerant evaporator and the air is made possible by the fins.

According to a second aspect of the invention, the object is achieved by a method for removing ice in a refrigerant evaporator unit of a refrigerator, wherein the refrigerant evaporator unit comprises a first unit area with a refrigerant evaporator for cooling air and a second unit area with a fan for conveying air the first and second unit regions are fluidly connected by an air duct, the fan fluidly connected to the air duct to supply air from the first aggregate region to the second aggregate region, wherein in the first aggregate region a heating element for heating the refrigerant evaporator is arranged, the heating element is configured to heat the refrigerant evaporator during a defrosting operation to the Wherein the first aggregate region has a receiving region which is arranged above the refrigerant evaporator, and wherein the receiving region is adapted to receive the water vapor generated by the heating element during the melting, the process comprising the following steps; Deactivating the refrigerant evaporator; Deactivate the fan; and activating the heating element to heat the refrigerant evaporator during the defrosting operation to melt ice attached to the refrigerant evaporator, wherein the water vapor generated by the heating element during melting is received in the receiving area.

Thereby, the technical advantage is achieved that can be effectively melted by the inventive method during the defrosting on the refrigerant evaporator ice and the water vapor generated thereby can be effectively absorbed in the receiving area. Thus, the water vapor can not get into the second unit area and it can not accumulate ice on the fan.

In a further advantageous embodiment of the method, the method further comprises the following steps, which follow the activation of the heating element; Activating the refrigerant evaporator; and activating the fan, wherein the fan is activated after a time interval after activation of the refrigerant evaporator.

Thereby, the technical advantage is achieved that was effectively cooled by the time-delayed activation of the fan after activating the refrigerant evaporator, the refrigerant evaporator. Thus, after activating the fan, the conveyed air is first passed over the cooled surface of the refrigerant evaporator, whereby the water vapor contained in the air is deposited on the cooled surface of the refrigerant evaporator as ice and thus a dry air flow is supplied to the fan in the second unit area.

Further embodiments will be explained with reference to the accompanying drawings. Show it: Fig. 1 is a schematic representation of a refrigerator;

FIG. 2 is a schematic representation of a refrigerant evaporator unit; FIG.

3a is a schematic representation of a refrigerant evaporator assembly according to a first embodiment in a side sectional view;

3b is a schematic representation of a refrigerant evaporator assembly according to a second embodiment in a side sectional view; 4 shows a schematic representation of a refrigerant evaporator unit; and

Fig. 5 is a schematic representation of a method for removing ice in a refrigerant evaporator unit of a refrigeration device.

Fig. 1 shows a refrigerator representative of a general refrigeration device 100 with a refrigerator door 101 and with a device outer wall 103. The device outer wall 103 includes a top wall 105, a rear wall 107, longitudinal walls 109 and a bottom wall 1 10 of the refrigerator 100, which the cooling area 1 1 1 complete. On the front side 1 13 of the refrigerator 100, the refrigerator door 101 is arranged. The refrigeration device 100 includes one or more refrigerant circuits, each with a refrigerant evaporator, refrigerant compressor, refrigerant condenser and throttle body. The refrigerant evaporator is a heat exchanger in which the liquid refrigerant is evaporated by absorbing heat from the medium to be cooled, for example air. The refrigerant compressor is a mechanically operated component that draws refrigerant vapor from the refrigerant evaporator and expels at a higher pressure to the refrigerant condenser. The refrigerant 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 refrigeration device 100 includes a fan which is designed to supply an air flow to the refrigerant evaporator. The air flow leads to an effective supply of heat to the refrigerant evaporator. 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 refrigerant cycle, which is low in temperature and low in temperature Pressure of the fluid absorbs heat and at higher temperature and higher pressure of the fluid gives off heat, which usually includes changes in the state of the fluid are included.

Fig. 2 shows a schematic representation of a refrigerant evaporator unit. The refrigerant evaporator unit 1 15 arranged in the refrigeration device 100 has a first aggregate region 11 and a second aggregate region 11, which are spatially separated from each other by a dividing wall 121. In the first unit region 1 17, a refrigerant evaporator 123 is arranged, which is connected to a refrigerant circuit, not shown in Fig. 2, and which is adapted to cool the supplied air. At the refrigerant evaporator 123, fins 125 are arranged to allow efficient heat exchange between the refrigerant evaporator 123 and the supplied air.

The first unit region 1 17 and the second unit region 1 19 are fluidly interconnected by an air duct, wherein the air duct in Fig. 2 is not shown. In the second unit region 1 19, a fan 127 is arranged for conveying air, which is designed to generate an air flow to promote air from the first unit region 1 17 through the air channel, not shown in Fig. 2 in the second unit region 1 19 , For this purpose, air is conveyed in a flow direction 131 from supply lines 129 through inlet openings 130 into the upper area of the first unit area 17 of the refrigerant evaporator unit 15. On a top side 133 of the first unit region 1 17, receiving areas 135 are arranged above the refrigerant evaporator 123, through which the conveyed air is conducted into the first unit area 17. The air led into the first unit region 17 is conducted from the upper side 133 of the first aggregate region 117 to an underside 137 of the first aggregate region 11, the air flowing past the refrigerant evaporator 123 and giving off heat to the refrigerant evaporator 123. The air supplied to the first unit region 1 17 exits through an exit opening 139, which is arranged on the underside 137 of the first unit region 17, in a flow direction 131 out of the first unit region 11. The exiting from the first unit region 1 17 through the exit port 139 air is sucked by means of the fan 127 through an air duct, not shown in Fig. 2 in the second unit region 1 19. By ventilation ducts, which are also not shown in Fig. 2, the cooled by the fan 127 cooled air can be passed into the cooling area 1 1 1 of the refrigerator 100.

Furthermore, below the refrigerant evaporator 123, a heating element 141 is arranged, which is designed to heat the refrigerant evaporator 123. The heating element 141 may in particular comprise a radiant heater or an electrical contact heater. Due to the cooling effect caused by the refrigerant evaporator 123, the air moisture present in the air may be accumulated as ice on the refrigerant evaporator 123 and thereby affect the performance of the refrigerant evaporator 123. For this reason, the refrigerant evaporator 123 is defrosted at regular intervals during a defrosting operation. By means of the heating element 141, the refrigerant evaporator 123 can be heated, as a result of which the ice attached to the refrigerant evaporator 123 melts, and that water produced as a result can be diverted from the first aggregate region 17 by a water drain, not shown in FIG. 2. By heating the refrigerant evaporator 123 by the heating element 141, part of the ice at the refrigerant evaporator 123 is evaporated due to the effective heating power of the heating element 141. The resulting water vapor rises in the first unit region 1 17 upwards and collects in the receiving areas 135 above the refrigerant evaporator 123. The receiving areas 135 are in particular formed as U-shaped bent siphons, which are arranged on the upper side 133 of the first unit region 1 17 , The rising water vapor collects at the top of the siphons.

After the end of defrosting and subsequent re-activation of the refrigerant cycle, first, the refrigerant evaporator 123 is activated and cooled down before the fan 127 is activated after a time interval. As a result, water vapor present in the receiving regions 135 is first guided past the cooled refrigerant evaporator 123 by the air flow generated by the fan 127, as a result of which the water vapor is conveyed to the cold surface of the cold water Condensed refrigerant evaporator 123 and accumulates as ice. As a result, the air discharged through the outlet opening 139 from the first unit region 17 only has a low level of air humidity when it is subsequently supplied to the second unit region 19 by the air duct, not shown in FIG. By supplying the dry air to the fan 127 arranged in the second unit region 11 19, condensation of water vapor on a fan wheel or on a fan inlet nozzle and subsequent ice accumulation on the fan 127 can be prevented. By preventing ice accumulation on the fan 127, the running property and the noise level of the fan 127 can be kept stable, and damage to the fan 127 can be prevented.

3a shows a schematic representation of a refrigerant evaporator unit according to a first embodiment in a lateral sectional view. The refrigerant evaporator unit 1 15 has a first unit region 1 17 with a refrigerant evaporator 123 for cooling air. Furthermore, FIG. 3 a shows a heating element 141 for heating the refrigerant evaporator 123, which is located through the outlet opening 139, through which air is discharged from the first unit region 11 in a flow direction 131. The first unit region 1 17 is fluidly connected through the outlet opening 139 with an air duct 143. The air channel 143 extends from an underside 137 of the first unit region 1 17 on the front side 145 of the refrigerant evaporator 123 along to the second unit region 19. The air channel 143 is fluidly connected to the second unit region 1 19. The fan 127 in the second unit region 1 19 sucks air from the first unit region 1 17, which is supplied in the flow direction 131 through the air duct 143 to the second unit region 1 19. The second unit region 1 19 is in turn fluidly connected to ventilation channels 147, wherein the ventilation channels 147 are in turn fluidly connected to cooling compartments of a cooling area 1 1 1 of the refrigeration device 100. As a result, the fan 127 can efficiently supply the conveyed air through the ventilation channels 147 in the flow direction 131 to the cooling region 11. By the partition disposed between the front side 145 of the refrigerant evaporator 123 and the air passage 143, the area of the refrigerant evaporator 123 available for heat exchange can be increased, thereby increasing the efficiency of the refrigerant evaporator 123. Furthermore, there is an advantage with respect to the isolation of the refrigerant evaporator 123 with respect to the cooling region 1 1 1. The fact that the air channel 143 is disposed between the refrigerant evaporator 123 and the cooling region 1 1 1, the refrigerant evaporator 123 and the cooling region 1 1 1 no longer has direct contact to each other. Thereby, the effect of the static cooling of the cooling area 1 1 1 can be reduced by the refrigerant evaporator 123. Depending on the temperature level of the refrigerant evaporator 123, it may be possible to dispense with further insulation.

3b shows a schematic representation of a refrigerant evaporator unit according to a second embodiment in a lateral sectional view. The refrigerant evaporator unit 1 15 has a first unit region 1 17 with a refrigerant evaporator 123 for cooling air, wherein the first unit region 1 17 is fluidly connected by an output port 139 with an air passage 143. The air channel 143 extends from the lower side 137 of the first unit region 1 17 on the rear side 147 of the refrigerant evaporator 123 to the second unit region 1 19 and is fluidly connected to the second unit region 1 19. The fan 127 draws in air from the first unit region 1 17, which is supplied in the flow direction 131 through the air channel 143 to the second unit region 1 19. The sucked air can be effectively supplied to a cooling area 1 1 1 of the refrigeration device 100 by connected to the second unit region 1 19 ventilation channels 147 in the flow direction 131.

4 shows a schematic representation of a refrigerant evaporator unit. The refrigerant evaporator unit 1 15 has a first unit region 1 17 with a refrigerant evaporator 123 for cooling air and a second unit region 1 19 with a fan 127 for conveying air. The first unit area 1 17 and the second unit area 1 19 are spatially separated from each other by a partition 121. The fan 127 sucks air through feed lines 129, through inlet openings 130 and through receiving areas 135, in particular siphons, into the upper area of the first unit area 1 17 of the refrigerant evaporator unit 15. The air fed into the first unit area 17 is discharged from the top 133 of the first Aggregate portion 1 17 to an underside 137 of the first unit region 1 17 passed to the refrigerant evaporator 123 past, wherein the air is cooled and discharged through an output port 139 from the first unit region 1 17.

Further, below the refrigerant evaporator 123, a heater 141 is disposed, and the heater 141 is configured to heat the refrigerant evaporator 123 to remove ice attached to the refrigerant evaporator 123. In this case, the attached ice is heated by the heating element 141, melted and partially evaporated. The resulting water vapor rises in the first unit region 1 17 upwards and collects in the receiving areas 135 above the refrigerant evaporator 123, which are in particular designed as U-shaped bent siphons.

After the end of the defrosting operation, first the refrigerant evaporator 123 is activated and after a time interval the fan 127 is then activated. The water vapor received in the receiving areas 135 is first bypassed the cooled refrigerant evaporator 123 by the air flow generated by the fan 127, whereby ice accumulates on the cold surface of the refrigerant evaporator 123, and thus supplies dry air to the fan 127 in the second unit area 1 19 becomes.

5 shows a schematic representation of a method for removing ice in a refrigerant evaporator unit of a refrigeration device. The method 200 includes the following steps. The first step includes deactivating 201 the refrigerant evaporator 123. The second step includes deactivating 203 the fan 127. Specifically, deactivating 203 the fan 127 may occur before or after deactivating 201 the refrigerant evaporator 123 or simultaneously. The third step includes activating 205 the heating element 141 to heat the refrigerant evaporator 123 during the defrosting operation to operate on the Refrigerant evaporator 123 annealed ice, wherein the simultaneously generated by the heating element 141 water vapor is received in the receiving area 135. The activating 205 of the heating element 141 is followed by the activating 207 of the refrigerant evaporator 123 as the fourth step after the defrosting operation and then activating 209 of the fan 127 as the fifth step, wherein the fan 127 is activated after a time interval after activation 207 of the refrigerant evaporator 123 , The staggered activation 209 of the fan 127 after activation 207 of the refrigerant evaporator 123 ensures that the refrigerant evaporator 123 has been cooled, so that the water vapor received in the receiving area 135 accumulates on the cooled surface of the refrigerant evaporator 123 and not in the second aggregate area 1 19 and can reach the fan 127.

All 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 description or shown in the figures.

LIST OF REFERENCE NUMBERS

100 refrigeration unit

101 refrigerator door

103 external device wall

105 upper wall

107 rear wall

109 longitudinal wall

1 10 subfloor

1 1 1 Cooling area

113 front side

1 15 refrigerant evaporator unit

1 17 First unit area

119 Second aggregate area

121 partition

123 refrigerant evaporator

125 fins

127 fans

129 feed line

130 entrance opening

131 flow direction of air

133 top of the first aggregate area

135 recording areas

137 Bottom of the first aggregate area

139 exit opening

141 heating element

143 air duct

145 Front of the refrigerant evaporator

147 ventilation duct

149 Rear of the refrigerant evaporator

200 Method for removing ice in a refrigerant evaporator unit

201 Deactivation of the refrigerant evaporator

203 Deactivating the fan Activate the heating element

Activating the refrigerant evaporator Activating the fan

Claims

Refrigeration appliance (100) with a refrigerant evaporator unit (1 15), wherein the refrigerant evaporator unit (1 15) has a first unit area (1 17) with a refrigerant evaporator (123) for cooling air and a second unit area (1 19) with a fan (127) for conveying air, wherein the first and second unit regions (1 17, 1 19) are fluidly connected by an air duct (143), the fan (127) being fluidly connected to the air duct (143) to remove air from the first Aggregate region (1 17) to the second unit region (1 19) to supply, and wherein in the first unit region (1 17) a heating element (141) for heating the refrigerant evaporator (123) is arranged, characterized in that the heating element (141) is formed to heat the refrigerant evaporator (123) during a defrosting operation to melt ice attached to the refrigerant evaporator (123), and that

the first aggregate region (17) has a receiving region (135) which is arranged above the refrigerant evaporator (123), wherein the receiving region (135) is designed to receive the water vapor generated by the heating element (141) during melting.

Refrigerating appliance (100) according to claim 1, characterized in that the

Receiving area (135) is designed as a U-shaped bent siphon for receiving water vapor, wherein the U-shaped siphon is arranged in particular on an upper side (133) of the first unit area (1 17).

Refrigeration appliance (100) according to claim 1 or 2, characterized in that the first unit area (1 17) from the second unit area (1 19) is separated by a partition wall (121), wherein the partition (121) in particular as a thermally conductive partition (121) is formed.

4. Refrigerating appliance (100) according to one of the preceding claims, characterized in that the heating element (141) below the refrigerant evaporator (123) in the first unit region (1 17) is arranged.

5. Refrigerating appliance (100) according to one of the preceding claims, characterized in that the first unit area (1 17) has a Wasserableitöffnung for discharging water from the first unit region (1 17), wherein the Wasserableitöffnung in particular at a bottom (137) of the first unit region (1 17) is arranged.

6. Refrigerating appliance (100) according to one of the preceding claims, characterized in that the refrigerant evaporator unit (1 15) a supply line

(129) for supplying air into the first unit section (1 17), wherein the supply line (129) to the first unit portion (1 17) through an input port (130) is fluidly connected, and wherein the input port

(130) is arranged in particular on an upper side (133) of the first unit region (1 17).

7. Refrigerating appliance (100) according to one of the preceding claims, characterized in that the first unit region (1 17) with the air channel (143) through an output port (139) is fluidly connected, wherein the output port (139) in particular at a bottom ( 137) of the first unit region (1 17) is arranged.

8. Refrigerating appliance (100) according to one of the preceding claims, characterized in that the refrigerant evaporator (123) has a front side (145) which faces a cooling area (1 1 1) of the refrigeration appliance (100), wherein the air duct (143) is arranged on the front side (145) of the refrigerant evaporator (123) to fluidly connect the first unit region (1 17) and the second unit region (1 19).

9. Refrigerating appliance (100) according to one of claims 1 to 7, characterized in that the refrigerant evaporator (123) has a rear side (149) which faces a rear wall (107) of the refrigerating appliance (100), wherein the air duct (143) at the rear side (149) of the refrigerant evaporator (123) is arranged to fluidly connect the first unit region (1 17) and the second unit region (1 19).

10. Refrigerating appliance (100) according to claim 8 or 9, characterized in that the refrigerant evaporator unit (1 15) has a further air duct (143) which fluidly connects the first unit area (1 17) and the second unit area (1 19), wherein the further air channel (143) is arranged on the front side (145) or on the rear side (149) of the refrigerant evaporator (123). 1 1. Refrigeration appliance (100) according to one of the preceding claims, characterized in that the refrigerant evaporator unit (1 15) has a partition, which is arranged between the refrigerant evaporator (123) and the air duct (143), wherein the separation consists in particular of a thermally conductive material ,

12. Refrigerating appliance (100) according to any one of the preceding claims, characterized in that the refrigeration device (100) has a number of ventilation channels (147) which the second unit area (1 19) with a cooling area (1 1 1) of the refrigeration device (100 ) fluidly connect.

13. Refrigerating appliance (100) according to any one of the preceding claims, characterized in that the refrigerant evaporator (123) fins (125) to allow an effective heat exchange between the refrigerant evaporator (123) and the air.

14. Method (200) for removing ice in a refrigerant evaporator unit (1 15) of a refrigeration device (100), wherein the refrigerant evaporator unit (1 15) has a first unit region (1 17) with a refrigerant evaporator (123) for cooling air and a second An aggregate region (1 19) having a fan (127) for conveying air, wherein the first and second unit region (1 17, 1 19) are fluidly connected by an air duct (143), wherein the fan (127) with the air duct ( 143) is fluidly connected to supply air from the first unit region (1 17) the second unit region (1 19), wherein in a heating element (141) for heating the refrigerant evaporator (123) is arranged in the first unit region (17), the heating element (141) being configured to heat the refrigerant evaporator (123) during a defrosting operation to be attached to the refrigerant evaporator (123) Melting ice, and wherein the first aggregate portion (17) has a receiving portion (135) disposed above the refrigerant evaporator (123), and wherein the receiving portion (135) is formed by the heating member (141) during melting received water vapor, characterized in that the method comprises the following steps:

Deactivating (201) the refrigerant evaporator (123);

Deactivating (203) the fan (127); and

Activating (205) the heating element (141) to heat the refrigerant evaporator (123) during the defrosting operation to melt ice attached to the refrigerant evaporator (123), the water vapor generated by the heating element (141) in the receiving area (135 ) is recorded.

The method (200) of claim 14, characterized in that the method (200) further comprises the following steps following the activation (205) of the heating element (141):

Activating (207) the refrigerant evaporator (123); and

Activating (209) the fan (127), wherein the fan (127) is activated after a time interval after activating (207) the refrigerant evaporator (123).