DE102021202695A1 - Refrigeration device and heat exchanger assembly for a refrigeration device - Google Patents

Abstract

A heat exchanger assembly for a refrigeration appliance comprises a housing formed from a plastic foam material, which housing defines an accommodating space extending along a longitudinal axis and has a first opening and a second opening which is arranged opposite to the first opening with respect to the longitudinal axis, a heat exchanger which is in the accommodating space of the casing and held by the casing, and a fan accommodated in the accommodating space of the casing and held by the casing, the fan being adapted to suck a gaseous fluid through the first opening of the casing, over the heat exchanger direct and blow out through the second opening of the housing.

Description

TECHNICAL AREA

The present invention relates to a heat exchanger assembly for a refrigeration device and a refrigeration device, in particular a domestic refrigeration device such as a refrigerator, a freezer or a chest freezer or a fridge-freezer combination.

STATE OF THE ART

In household refrigeration appliances, a heat exchanger assembly can be provided for dissipating heat to the environment, which has a heat exchanger or a line arrangement and a fan or ventilator for transporting air via the line arrangement. Such heat exchanger assemblies are typically located in the engine room.

In the DE 10 2015 221 659 A1 a heat exchanger assembly is disclosed which is arranged in a machine room of a refrigerator and has an MPE condenser and a fan. "MPE" is an abbreviation for the expression "multiport extruded" and describes a profile that has a large number of extruded lines.

Also describes the DE 10 2017 213 972 A1 a heat exchanger assembly arranged in a machine room of a refrigeration device with a condenser and a fan which transports air over the condenser, the condenser and the fan being arranged in a common pipe or surrounded by the pipe. The condenser comprises a multi-chamber MPE profile through which refrigerant flows. The inner diameter of the tube is adapted to the outer diameter of the condenser and fan. Within the machine room, the heat exchanger assembly is separated by a partition, one end of the tube being located in a recess in the partition and a sealing lip being provided between the tube and the partition.

With such heat exchanger assemblies with a heat exchanger and a fan that are integrated into a housing or pipe, it can happen that the housing is set in motion by the operation of the fan, which can lead to noise emissions.

SUMMARY OF THE INVENTION

It is one of the objects of the present invention to provide improved solutions for heat exchanger assemblies of refrigeration devices, in particular such solutions in which noise emissions are reduced and which enable simple assembly.

According to the invention, this object is achieved by a heat exchanger assembly having the features of claim 1 and by a refrigeration device having the features of claim 14 .

According to a first aspect of the invention, a heat exchanger assembly for a refrigeration device is provided. The heat exchanger assembly includes a housing formed from a plastic foam material which defines a receiving space extending along a longitudinal axis and has a first opening and a second opening arranged opposite the first opening with respect to the longitudinal axis, a heat exchanger which is received in the receiving space of the housing and held by the housing, and a fan accommodated in the accommodation space of the housing and held by the housing, the fan being adapted to draw a gaseous fluid through the first opening of the housing, pass over the heat exchanger and through blow out the second opening of the housing.

According to a second aspect of the invention, a refrigeration device, in particular a household refrigeration device such as a refrigerator, a freezer or a chest freezer or a fridge-freezer combination is provided. The refrigeration device comprises at least one refrigeration compartment for accommodating refrigerated goods, a machine room separate from the refrigeration compartment and a refrigerant circuit for dissipating heat from the refrigeration compartment to the environment, the refrigerant circuit having a heat exchanger assembly according to the first aspect of the invention, which is arranged in the machine room.

One idea on which the invention is based consists in accommodating a heat exchanger, for example a condenser, and a ventilator in a common housing which is made of a foam material, in particular an expanded plastic material. The housing defines an accommodation space, in particular in the form of a flow channel which extends along a longitudinal axis between opposite openings and in which the heat exchanger and the fan are arranged one behind the other. The receiving space is defined or bounded by an inner surface of the housing with respect to a radial direction that extends perpendicularly to the longitudinal axis. For example, the fan can be arranged in the area of the first opening and the heat exchanger in the area of the second opening. fan and heat exchanger shear are held by the housing itself or connected to the housing. The heat exchanger can be integrated in particular as a condenser in the refrigerant circuit of the refrigeration device and can be realized, for example, as an MCHE condenser or MPE condenser. "MCHE" is an abbreviation for the English expression "micro channel heat exchanger". Such condensers can in particular be equipped with a "multi port extrusion pipe" (MPE), ie an extruded pipe which has a large number of channels in its interior. The unit consisting of the heat exchanger, fan and housing is housed in the machine room of the refrigeration device, for example in addition to a compressor in the refrigerant circuit.

The foam material from which the housing is formed has a certain resilience or elastic deformability. As a result, heat exchangers and condensers can easily be fitted into the housing with relatively large tolerances. A further advantage lies in the fact that the foam material has excellent damping properties due to its elasticity and porosity, as a result of which the noise emissions from the heat exchanger assembly are advantageously reduced.

Advantageous refinements and developments result from the dependent claims referring back to the independent claims in connection with the description.

According to some embodiments, it can be provided that the heat exchanger and/or the fan rests against an inner surface that delimits the receiving space. In particular, the heat exchanger and/or fan can be oversized relative to the inner diameter of the receiving space defined by the inner surface. This achieves an at least partially frictional fixing of the fan and/or the heat exchanger in the housing. An advantage of this design is that vibrations of the heat exchanger or the fan are even better dampened by the material of the housing and the noise emission is thus even further reduced. Furthermore, this advantageously improves a seal between the inner surface of the housing and the fan or between the inner surface of the housing and the heat exchanger, as a result of which leakage flows are also reduced.

According to some embodiments, it can be provided that a first receiving groove is formed on the inner surface of the housing, in which an edge region of the heat exchanger is received. The receiving groove can in particular have a cross-sectional shape which is designed to correspond to or complement the cross-sectional shape of the edge region of the heat exchanger. The receiving groove offers the advantage that the heat exchanger is fixed even more reliably in its position along the longitudinal axis, in particular is fixed in a form-fitting manner. Furthermore, the assembly of the heat exchanger is further simplified since the axial position of the compressor is clearly defined by the receiving groove.

According to some embodiments, it can be provided that the edge area of the heat exchanger is clamped in the first receiving groove. The first receiving groove can, for example, have a width or extent along the longitudinal axis that is reduced compared to the width of the heat exchanger, so that the heat exchanger is clamped between opposite side walls of the groove. This achieves a reliable seal between the inner surface of the housing and the heat exchanger in a simple manner. Furthermore, the damping of vibrations is further improved.

According to some embodiments, it can be provided that a second receiving groove is formed on the inner surface of the housing, in which an edge region of the fan is received. The second receiving groove can in particular have a cross-sectional shape which is designed to correspond to or complement the cross-sectional shape of the edge region of the fan. The second receiving groove offers the advantage that the heat exchanger is fixed even more reliably in its position along the longitudinal axis, in particular is fixed in a form-fitting manner. Furthermore, the assembly of the fan is further simplified since the axial position of the compressor is clearly defined by the receiving groove.

According to some embodiments, it can be provided that the edge area of the fan is clamped in the second receiving groove. The second receiving groove can, for example, have a width or extension along the longitudinal axis that is reduced compared to the width of the fan, so that the latter is clamped between opposite side walls of the groove. A reliable seal between the inner surface of the housing and the fan is thereby achieved in a simple manner. Furthermore, the damping of vibrations is further improved.

According to some embodiments, it can be provided that the housing has a side opening which extends transversely to the longitudinal axis and through which the fan can be introduced into the accommodation space of the housing. For example, the side opening can open into the second receiving groove. Generally, a central axis defined by the side opening extends transverse to the longitudinal The axis or the side opening extends between the inner surface of the housing and an outer peripheral surface of the housing which is oriented opposite to the inner surface. The side opening advantageously further simplifies the assembly of the fan.

According to some embodiments, it can be provided that the housing has at least one longitudinal slot, which extends from the first opening or the second opening parallel to the longitudinal axis, with a line connection of the heat exchanger extending from the receiving space of the housing through the longitudinal slot to an outside of the housing . The heat exchanger can thus be inserted through the first or the second opening into the receiving space of the housing, with its line connection or optionally its line connections being inserted along the longitudinal axis into the respective longitudinal slot. This further facilitates the assembly of the heat exchanger.

According to some embodiments, it can be provided that the housing is composed of a first housing half-shell and a second housing half-shell, each housing half-shell forming a peripheral section of the housing. The housing can thus be divided along a plane which extends parallel to the longitudinal axis. This further facilitates the assembly of the heat exchanger and fan in the housing.

According to some embodiments, it can be provided that the first housing half-shell has first engagement structures, that the second housing half-shell has second engagement structures, and that the first and the second engagement structures are designed to be complementary to one another and engage in one another. For example, each half-shell can have an engagement or latching structure at its peripheral ends. In particular, provision can be made for the first engagement structures to be designed for latching, in particular for form-fitting latching, with the second engagement structures. Optionally, the first housing half-shell has first engagement structures that differ from one another at its two circumferential ends, and the second housing half-shell also has first engagement structures that differ from one another at its two circumferential ends and are designed to be complementary to the first engagement structures. As a result, the half-shells can only be fixed to one another in one position relative to one another, which prevents incorrect assembly.

According to some embodiments, it can be provided that the housing has an outer peripheral surface which encloses the longitudinal axis and which defines a wedge-shaped outer periphery of the housing. For example, the outer peripheral surface can have two opposite, essentially parallel side surface sections, a bottom surface section connecting the side surface sections in a first end area and a top surface section arranged opposite the bottom surface section, which connects the side surface sections in a second end area, the bottom surface section and the top surface section forming an acute angle lock in. The advantage of the wedge shape is that the installation position of the heat exchanger assembly is clearly defined, which further facilitates installation in the machine room.

According to some embodiments it can be provided that the plastic foam material of the housing has a compression set which is less than or equal to 15%, preferably less than or equal to 11.5%. The compression set can be determined according to DIN ISO 815 or ASTM D 395, for example. Particularly good vibration damping properties are achieved in this size range of the compression set.

According to some embodiments it can be provided that the plastic foam material is expanded polypropylene, EPP, or expanded polyethylene, EPE. These materials offer the advantage that they are mechanically robust, so that damage to the housing when installing the heat exchanger and fan is reliably avoided. Furthermore, these materials have good damping and thermal insulation properties and are waterproof or impermeable to water, as a result of which any condensation water that may occur does not collect in the walls of the housing.

According to some embodiments, it can be provided that the housing of the heat exchanger assembly is clamped in relation to a direction transverse to the longitudinal axis between a first boundary, in particular a floor, and a second boundary, in particular a ceiling, of the machine room. For example, the housing can be arranged in the machine room in such a way that the first and second housing half-shells are pressed against one another by the boundaries of the machine room. Due to the elastic deformability of the foam material of the housing, the fan and the heat exchanger are fixed even more reliably in the accommodation space as a result of the clamping force exerted by the limitations of the machine space, which further reduces noise emissions. Since the housing is thus at least on two sides of the Outside circumference, for example on the bottom surface section and the top surface section, rests against the machine room, a flow short-circuit between the first and second openings of the housing is further prevented.

Optionally, the housing can have one or more machine room connection structures on its outer circumference, e.g. in the form of depressions, grooves and/or projections, which are designed to accommodate complementarily designed parts of the machine room, such as support rails or the like.

character list

• 1 eine vereinfachte, schematische Schnittansicht eines Kältegeräts gemäß einem Ausführungsbeispiel der Erfindung;
• 2 eine perspektivische Ansicht einer Wärmetauscherbaugruppe gemäß einem Ausführungsbeispiel der Erfindung;
• 3 eine Schnittansicht der in 2 gezeigten Wärmetauscherbaugruppe; und
• 4 eine der in den 2 und 3 gezeigten Wärmetauscherbaugruppe in einem Zustand, in dem diese in einen Maschinenraum eines Kältegeräts eingebaut ist.

The invention is explained below with reference to the figures of the drawings. From the figures show:

• 1 a simplified, schematic sectional view of a refrigerator according to an embodiment of the invention;
• 2 a perspective view of a heat exchanger assembly according to an embodiment of the invention;
• 3 a sectional view of the 2 shown heat exchanger assembly; and
• 4 one of the in the 2 and 3 shown heat exchanger assembly in a state in which it is installed in a machine room of a refrigerator.

In the figures, the same reference symbols designate identical or functionally identical components, unless otherwise stated.

DETAILED DESCRIPTION OF EXEMPLARY EMBODIMENTS

1 shows a refrigeration device 200, for example in the form of a refrigerator, by way of example and in a schematic manner. In general, the refrigeration device 200 can be a household refrigeration device, for example a refrigerator, a freezer, a fridge-freezer combination or the like. As in 1 shown by way of example, the refrigeration device 1 can have at least one refrigeration compartment 210 , a machine room 220 and a refrigerant circuit 230 .

The refrigeration compartment 210 is in 1 only represented symbolically by dashed lines as a rectangle and is used to hold refrigerated goods. For example, the cold compartment 210 can be defined by a container that is accommodated in a body 205 .

The engine room 220 is in 1 shown only schematically and is a separate from the refrigeration compartment 210 receiving space for accommodating components of the refrigerant circuit 230. As in 1 shown by way of example, the machine room 220 can be arranged, for example, in an area of the body 205 close to the floor. In general, the machine room is delimited by at least two opposing delimiting structures, e.g. as in 1 shown schematically by a floor 221 and by a ceiling 222 opposite thereto. Also optionally, side walls 224, 225 may be provided extending at opposite ends of floor 221 and ceiling 222 between them and transversely to rear wall 223, such as this 1 is shown schematically.

In 4 A sectional view of the machine room 220 is shown by way of example. As in 4 shown purely by way of example, the floor 221 can be trough-shaped, with the floor 221 having an essentially plate-shaped section 221A, a first profile section 221B extending from the plate-shaped section 221A and a second profile section 221C extending from the plate-shaped section 221A, which extends parallel to the first profile section 221B. The first profile section 221B can define, for example, a groove and a projection, as is shown in 4 is shown as an example. The second profile section 221C can, for example, define a slope, as is shown in 4 is shown as an example. However, the floor 221 is not limited to this configuration and may generally define a floor surface, for example in the form of a plate-shaped section 221A, which preferably extends transversely or perpendicularly to the rear wall 223. The ceiling 222 can be plate-shaped, for example, as in 4 shown by way of example, and optionally encloses an obtuse angle with the rear wall 223 . Thus, an acute angle can be included between the ceiling 222 and the plate-shaped portion 221A of the floor 221 . As in 4 is further shown, the engine room 220 can optionally be closed by a cover 226, which extends between the ceiling 222 and the floor 221, in particular opposite to the rear wall 223.

The refrigerant circuit 230 is in 1 shown only schematically and is designed to circulate a refrigerant in order to dissipate heat from the refrigeration compartment 210 and release it to the environment. The refrigerant circuit 230 can in particular have a compressor 231 for circulating refrigerant, an evaporator 232 connected to a pressure connection of the compressor 231 for Have absorption of heat from the cold compartment 210 and a heat exchanger assembly 100 with a condenser for dissipating heat to the environment.

As in 1 shown schematically, the heat exchanger assembly 100 is arranged in the machine room 220 . As 1 12, the compressor 231 can also be accommodated in the machine room 220. FIG. Optionally, a condensation water tray 234 can also be arranged in the machine room 220, for example on the compressor as in FIG 1 shown as an example, in which the refrigeration compartment 210 resulting condensate is introduced.

In 1 the heat exchanger assembly 100 is shown only schematically in section. 2 shows an example perspective view of the heat exchanger assembly 100. 3 shows a sectional view of in 2 shown heat exchanger assembly 100.Wie in particular in the 1 and 3 As can be seen, the heat exchanger assembly 100 has a housing 1 , a heat exchanger 2 and a fan 3 .

As in the 1 and 3 As shown by way of example, the housing 1 defines a receiving space 10 which is delimited by an inner surface 1a of the housing 1 . The receiving space 10 extends along a longitudinal axis L1 between a first opening 11 and a second opening 12. The housing 1 thus forms a channel extending along the longitudinal axis L1 between the first opening 11 and the second opening 12. As in the 1 and 3 shown by way of example, a flow cross section of the channel defined by the inner surface 1a of the housing 1 can widen from the first opening 11 to the second opening 12 . An outer surface 1b of the housing, which is located opposite to the inner surface 1a with respect to a radial direction R1 extending perpendicularly to the longitudinal axis L1, defines an outer periphery of the housing 1. As shown in particular in FIGS 2 and 4 is shown as an example, it can optionally be provided that the outer peripheral surface 1 b defines a wedge-shaped outer periphery of the housing 1 . For example, the outer peripheral surface 1a can have two opposite, essentially parallel side surface sections 18A, 18B, a bottom surface section 18C connecting the side surface sections 18A, 18B in a first end region, and a top surface section 18D arranged opposite the bottom surface section 18C, which combines the side surface sections 18A, 18B in one connects the second end area, wherein the bottom surface section 18C and the top surface section 18D enclose an acute angle, as is the case in particular in 4 is shown as an example.
As in the 2 and 4 is shown schematically, it can optionally be provided that the housing 1 is composed of a first housing half-shell 1A and a second housing half-shell 1B. Each housing half-shell 1A, 1B forms a peripheral section of the housing 1. For example, the first housing half-shell 1A can have the bottom surface section 18C and part of the side wall sections 18A, 18B and part of the inner surface 1a, while the second housing half-shell 1B has the top surface section 18A and the remaining part of the side wall sections 18A, 18B and the remaining part of the inner surface 1a. The housing 1 can thus be divided along a plane running along or parallel to the longitudinal axis L1.

The housing half-shells 1A, 1B rest against one another at their ends in relation to the circumferential direction. For example, the first housing half-shell 1A can have first engagement structures 17A, e.g. in the form of grooves extending along the longitudinal axis L1, as is shown in 2 is shown as an example. As in 2 As can be seen, it can be provided that the groove provided at one peripheral end or, in general, the engagement structures 17A have a cross-sectional shape that is different from the cross-sectional shape of the groove or engagement structures 17A provided at the other peripheral end. The second housing half-shell 1B has second engagement structures 17B, for example in the form of projections or strips extending along the longitudinal axis L1, as is shown in 2 is shown schematically. In general, the first and second engagement structures 17A, 17B are complementary to each other and engage one another. For example, the housing half-shells 1A, 1B can be fastened to one another by the engagement structures 17A, 17B. In general, the housing half-shells 1A, 1B are connected to one another.

The housing 1, e.g., the housing half-shells 1A, 1B, is formed from a plastic foam material. The plastic foam material can, for example, be expanded polypropylene, EPP for short, or expanded polyethylene, EPE for short. However, other foam materials are also conceivable from which the housing 1 can be formed. In particular, it can be provided that the plastic foam material of the housing 1 has a compression set which is less than or equal to 15%, preferably less than or equal to 11.5%. The housing 1 is thus relatively highly elastically deformable and porous overall, with the foam material preferably having closed pores.

The heat exchanger 2 can be integrated into the refrigerant circuit 230 of the refrigeration device 200, for example as a condenser. In 1 is the heat exchanger 2 only shown symbolically as a block. As in the 3 and 4 shown by way of example, the heat exchanger 2 can have a line arrangement 20 extending over a surface area for conducting the refrigerant. Furthermore, fins or other cooling structures (without reference numbers) can be connected to the line arrangement 20 in order to increase the heat-conducting surface of the heat exchanger 2 . Furthermore, the heat exchanger 2 can have line connections 21 through which the refrigerant can be fed to and removed from the line arrangement 20 . In 4 it can be seen that the line connections 21 can protrude laterally from the line arrangement 20, for example. In the 3 and 4 a heat exchanger 2 implemented as an MCHE condenser is shown purely by way of example.

The heat exchanger 2 is accommodated in the accommodation space 10 of the housing 1 . For example, the heat exchanger 2 can be arranged in the area or adjacent to the second opening 12, as is shown in FIGS 1 and 3 is shown as an example. Optionally, the heat exchanger 2 can rest against the inner surface 1a. As in 3 shown schematically and purely by way of example, a first receiving groove 13 can be formed on the inner surface 1a of the housing 1, for example in the area of the second opening 12, in which an edge area 23 of the heat exchanger 2 is received. Thus, the side walls of the receiving groove 13 overlap the edge area 23 of the heat exchanger 2 with respect to the radial direction R1. Optionally, the edge area 23 of the heat exchanger 2 can be clamped in the first receiving groove 13 . As an alternative or in addition to fixing the heat exchanger 2 in the first receiving groove 13, it would also be conceivable for an outer circumference of the heat exchanger 2 to rest on the inner surface 1a of the housing 1, for example on the base of the receiving groove 13 or on a flat area of the inner surface 1a. In general, the heat exchanger 2 is held in position by the housing 1 itself. This is easily possible due to the fact that the housing 1 is made of a foam material. The line arrangements 21 of the heat exchanger 2 can extend, for example, through longitudinal slots 16 from the receiving space 10 to an outside of the housing 1, as is shown in FIG 4 is shown as an example. As in the 2 and 4 As can be seen, the respective longitudinal slot 16 can extend in particular from the second opening 12 parallel to the longitudinal axis L1. The heat exchanger 2 can thus be inserted through the second opening 12 into the receiving space 10 , with the line arrangement 20 being pushed through the second opening 12 along the longitudinal axis L1 and the line connections 21 being inserted into the respective longitudinal slot 16 .

The fan 3 is in 1 also shown only schematically and can have, for example, a 30 and a blade arrangement 31 rotatably mounted in this, as in FIGS 2 and 3 shown with more details. The fan 30 is designed to transport a gaseous fluid, in particular air, or to generate an air flow. The fan 3 is arranged in the accommodation space 10 together with the heat exchanger 2 . As in the 1 until 3 shown, the fan 3 can be arranged, for example, in the area of or adjacent to the first opening 11 of the housing 1 . Alternatively, it would also be conceivable to arrange the fan 3 in the area of the second opening 12 and the heat exchanger 2 in the area of the first opening 11 . The optional longitudinal slots 16 would then extend from the first opening 11 parallel to the longitudinal axis L1. In general, the fan 3 is designed to suck in a gaseous fluid through the first opening 11 of the housing 1 , to conduct it via the heat exchanger 2 and to blow it out through the second opening 12 of the housing 1 .

Optionally, the fan 3 can rest against the inner surface 1a. As in 3 shown schematically and purely by way of example, a second receiving groove 14 can be formed on the inner surface 1a of the housing 1, for example in the region of the first opening 11, in which an edge region 34 of the fan 3 is received. For example, the frame 30 of the fan 30 can be received in the second receiving groove 14, as shown in FIG 3 is shown as an example. Thus, the side walls of the second receiving groove 14 overlap the edge area 34 of the fan 3 with respect to the radial direction R1. Optionally, the edge area 34 of the fan 3 can be clamped in the second receiving groove 14 . As an alternative or in addition to fixing the fan 3 in the second receiving groove 14, it would also be conceivable for an outer circumference of the fan 3 to rest on the inner surface 1a of the housing 1, for example on the base of the receiving groove 14 or on a flat area of the inner surface 1a. In general, the fan 3 is held in position by the casing 1 itself. This is easily possible due to the fact that the housing 1 is made of a foam material.

As in 2 shown by way of example, the housing 1 can have a side opening 15 . The side opening 15 extends between the inner surface 1a and the outer surface 1b of the housing 1 and thus transversely to the longitudinal axis L1. For example, the side opening can be arranged in one of the side surface sections 18A, 18B of the outer surface 1b, as is shown in 2 is shown as an example. Optionally, the side opening 15 opens into the second receiving groove 14. The side opening 15 is dimensioned so that the fan 3 through the side opening 15 into the receiving space 10 of the housing ses 1 is insertable. This also includes that the fan 3 can have a certain oversize compared to the side opening 15, the housing 1 being deformable in the area of the side opening 15 in such a way that the fan 3 can be inserted through the side opening 15 into the receiving space 10 of the housing 1 .

As in the 1 and 4 shown schematically, the heat exchanger assembly 100 is accommodated or arranged in the machine room 220 . In particular, the heat exchanger assembly 100 can be positioned in the machine room 220 in such a way that the longitudinal axis L1 extends parallel to the floor 221 or to the ceiling 222 or transversely to the side walls 224, 225. The second opening 21 of the housing 1 can be located facing the compressor 231, for example. This offers the advantage that warm air blown out of the second opening 21 promotes the evaporation of the condensed water from the optional condensed water tray 234 . Optionally, the housing 1 can be clamped in the machine space 220 with respect to the radial direction R1 between a first boundary and a second boundary, in particular in such a way that the first and the second half-shells 1A, 1B of the housing are pressed against one another. As in the 1 and 4 shown by way of example, the housing 1 can be clamped between the floor 221 and the ceiling 222 of the machine room 220, for example. For example, the ceiling 222 can abut the ceiling surface portion 18D of the outer surface 1b, and the floor 221, particularly the plate-shaped portion 221A of the floor 221, can abut the bottom surface portion 18C of the outer surface 1b. As in 4 is shown symbolically, the boundaries, in this case the bottom 221 and the top 222, exert a clamping force F on the housing 1, as is shown in 4 is symbolized by arrows. This clamping force F presses the housing 1 together or compresses it. This also leads to an increase in the contact force between heat exchanger 2 and housing 1 or fan 3 and housing 1. The close contact between the boundaries and housing 1 and between heat exchanger 2 and housing 1 and fan 3 and housing 1 also reduces noise emissions of the heat exchanger assembly 100 is reduced. As in 4 As further shown, the side surface sections 18A, 18B of the outer surface 1b of the housing 1 can optionally rest against the rear wall 223 and the cover 226.

As in the 2 and 4 shown by way of example, one or more machine room connection structures 19 can be formed on the outer surface 1b, for example in the form of grooves or groove profiles extending along the longitudinal axis L1. For example, the machine room connection structures 19 can be designed to be complementary to and engage with the first and second profile sections 221B, 221C of the floor 221 when the heat exchanger assembly 100 is arranged in the machine room 220, as is shown in FIG 4 is shown as an example.

Although the present invention has been explained above by way of example using exemplary embodiments, it is not limited thereto but can be modified in many different ways. In particular, combinations of the above exemplary embodiments are also conceivable.

Reference List

1

Housing

1A

first half shell

1a

inner surface of the housing

1B

second half shell

1b

outer surface of the housing

2

heat exchanger

3

fan

10

Recording space / interior of the housing

11

first opening

12

second opening

13

first receiving groove

14

second receiving groove

15

side opening

16

longitudinal slit

18A

side surface section

18B

side surface section

18C

bottom surface section

18D

ceiling surface section

17A

first engagement structure

17B

second engagement structure

23

edge area of the heat exchanger

34

edge area of the fan

100

heat exchanger assembly

200

refrigeration device

210

refrigeration compartment

220

engine room

221

floor

221A

slab-like section

221B

first profile section

221C

second profile section

222

ceiling

223

back panel

224

Side wall

225

Side wall

226

cover

230

Refrigerant circulation

231

compressor

232

Evaporator

234

condensation tray

L1

longitudinal axis

R1

radial direction

QUOTES INCLUDED IN DESCRIPTION

This list of documents cited by the applicant was generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Patent Literature Cited

• DE 102015221659 A1 [0003]
• DE 102017213972 A1 [0004]

Claims (15)

Heat exchanger assembly (100) for a refrigeration device (200), comprising: a housing (1) formed from a plastic foam material, which defines a receiving space (10) extending along a longitudinal axis (L1) and a first opening (11) and one with respect to the longitudinal axis (L1) opposite to the first opening (11) arranged second opening (12); a heat exchanger (2) accommodated in the accommodating space (10) of the casing (1) and held by the casing (1); and a fan (3) which is accommodated in the receiving space (10) of the housing (1) and held by the housing (1), the fan (3) being designed to draw a gaseous fluid through the first opening (11) of the To suck in the housing (1), to conduct it via the heat exchanger (2) and to blow it out through the second opening (12) of the housing (1). Heat exchanger assembly (100) according to claim 1 , wherein the heat exchanger (2) and/or the fan (3) bears against an inner surface (1a) delimiting the receiving space (10). Heat exchanger assembly (100) according to claim 2 , wherein on the inner surface (1a) of the housing (1) a first receiving groove (13) is formed, in which an edge region (23) of the heat exchanger (2) is received. Heat exchanger assembly (100) according to claim 3 , The edge region (23) of the heat exchanger (2) being clamped in the first receiving groove (13). Heat exchanger assembly (100) according to any one of claims 2 until 4 , wherein on the inner surface (1a) of the housing (1) a second receiving groove (14) is formed, in which an edge region (34) of the fan (3) is received. Heat exchanger assembly (100) according to claim 5 , The edge region (34) of the fan (3) being clamped in the second receiving groove (14). Heat exchanger assembly (100) according to one of the preceding claims, wherein the housing (1) has a side opening (15) extending transversely to the longitudinal axis (L1), through which the fan (3) enters the receiving space (10) of the housing (1). is insertable. Heat exchanger assembly (100) according to any one of the preceding claims, wherein the housing (1) has at least one longitudinal slot (16) which extends from the first opening (11) or the second opening (12) parallel to the longitudinal axis (L1), wherein a line connection (21) of the heat exchanger (2) extends from the receiving space (10) of the housing (1) through the longitudinal slot (16) to an outside of the housing (1). Heat exchanger assembly (100) according to one of the preceding claims, wherein the housing (1) is composed of a first housing half-shell (1A) and a second housing half-shell (1B), each housing half-shell (1A, 1B) forming a peripheral section of the housing (1). Heat exchanger assembly (100) according to claim 9 , wherein the first housing half-shell (1A) has first engagement structures (17A), the second housing half-shell (1B) has second engagement structures (17B), and the first and second engagement structures (17A, 17B) are designed to be complementary to one another and engage in one another. Heat exchanger assembly (100) according to one of the preceding claims, wherein the housing (1) has an outer peripheral surface (1b) which encloses the longitudinal axis (L1) and which defines a wedge-shaped outer periphery of the housing (1). Heat exchanger assembly (100) according to one of the preceding claims, wherein the plastic foam material of the housing (1) has a compression set which is less than or equal to 15%, preferably less than or equal to 11.5%. A heat exchanger assembly (100) according to any one of the preceding claims, wherein the plastic foam material is expanded polypropylene, EPP, or expanded polyethylene, EPE. Refrigeration device (200), in particular domestic refrigeration device, with: at least one refrigeration compartment (210) for accommodating refrigerated goods; a machine room (220) separate from the refrigeration compartment (210); and a refrigerant circuit (230) for heat dissipation from the cold compartment (210) to the environment, wherein the refrigerant circuit (230) has a heat exchanger assembly (100) according to any one of the preceding claims, which is arranged in the machine room (220). Refrigeration device (200) after Claim 14 , wherein the housing (1) of the heat exchanger assembly (100) with respect to a direction transverse to the longitudinal Axis (L1) is clamped between a first boundary, in particular a floor (221), and a second boundary, in particular a ceiling (222) of the machine room (220).

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