CH711098B1 - Cooling device with asymmetrically designed cold side. - Google Patents

Abstract

A cooling device comprises a cooling duct (16, 17, 18) and a heat pump with a first evaporator section (51). The first evaporator section (51) is arranged in the cooling channel (16, 17, 18). There is also a fan (13) which promotes a flow of cooling air in the cooling duct (16, 17, 18). The fan (13) is arranged downstream of the first evaporator section (51) and in a curved section (17) of the cooling channel (16, 17, 18).

Description

Field of invention

The invention relates to a cooling device, in particular a built-in refrigerator, according to the preamble of claim 1. This comprises a cooling duct, a heat pump with a first evaporator section and a fan for promoting a flow of cooling air.

background

There are cooling devices known, in which air flows past an evaporator for cooling and is distributed via cooling channels by air conveying means in the individual cooling compartments. The fact that the cooling air is cooled centrally in one place and then distributed to the cooling compartments enables more targeted cooling of the individual cooling compartments. On the other hand, it has the disadvantage that the cooling air has to be conveyed back and forth between the evaporator and the cooling compartments. The operation of the air conveyor requires energy.

Presentation of the invention

The object is to reduce the energy consumption of a cooling device of the type mentioned.

This object is achieved by the cooling device according to claim 1. Accordingly, the cooling device includes: <tb> - <SEP> at least one cooling channel, <tb> - <SEP> a heat pump with a first evaporator section which is arranged in a first cooling duct section of the at least one cooling duct, <tb> - <SEP> a fan for conveying a flow of cooling air in the at least one cooling channel, the fan being arranged in the at least one cooling channel downstream of the first evaporator section.

The fan is arranged in a curved section of the cooling channel.

[0006] A cooling channel is to be understood as any device which guides a flow of cooling air in its direction of flow.

The concept of the fan is also to be understood broadly in that it includes any type of air conveying means.

[0008] A curved section of the cooling channel means that it is a deviation from a straight course of the cooling channel. The direction of the cooling air flow should be changed by the curvature.

The arrangement of the fan in a curved section has the advantage that a change in direction of the cooling air flow is caused by the fan and the cooling air flow does not have to be deflected by an additional deflection device. This reduces the overall flow resistance and thus also the energy consumption of the fan.

The curved section of the cooling channel is advantageously designed to deflect the cooling air flow by at least 75 °, in particular at least 160 °, in particular approximately 180 °.

With a deflection of approximately 180 ° it is meant that the flow is deflected in an essentially opposite direction, but it does not depend on a change of direction of exactly 180 °.

The larger the angle of deflection, the more effectively the advantage of the arrangement of the fan in a curved section can be used.

Furthermore, downstream of the fan, a second evaporator section can be arranged in a second cooling duct section of the at least one cooling duct.

[0014] The second evaporator section can advantageously have a smaller flow cross-section and / or a smaller length than the first evaporator section.

The length is to be understood as the extent of the evaporator section in the direction of flow.

A smaller flow cross-section and / or a smaller length of the second evaporator section have the advantage that the cooling air flow is cooled more when flowing through the first evaporator section than when flowing through the second evaporator section. As a result, the cooling air flow condenses for the most part as it flows through the first evaporator section, so that the risk of condensation forming on the fan arranged between the first and the second evaporator section can be reduced.

[0017] The first and / or the second evaporator section can advantageously each extend over the entire flow cross-sectional area of the at least one cooling channel.

As a result, the cooling air flow necessarily flows through the first and / or through the second evaporator section and there is an optimal heat exchange between the evaporator and the cooling air flow.

[0019] The curved section of the cooling channel advantageously has a change in direction of approximately 180 °. The first and the second cooling duct section are arranged in such a way that they adjoin one another on adjacent side surfaces and the cooling air flow can flow through them in the opposite direction.

This arrangement of the two evaporator sections and the fan leads to a compact design of the cooling device.

In particular, the air supply and the air discharge channels, which lead the cooling air from the evaporator to the individual cooling compartments and back to the evaporator, are arranged in the rear region of the cooling device. The cooling air exits the air discharge duct, flows in the cooling device from the back to the front through the first evaporator section, then through the deflecting fan and then in the opposite direction back through the second evaporator section to the air supply duct, via which the cooling air is fed to the cooling compartments.

With this arrangement, the cooling air flow can be passed through the evaporator of the cooling device in a compact and energy-saving manner.

A partition is advantageously arranged between the first and the second evaporator section to separate the cooling air flow in the first evaporator section from the cooling air flow in the second evaporator section.

It can thereby be ensured that the cooling air flow is guided through both evaporator sections and through the fan and the cooling air flow does not shorten the path.

In addition, the first and the second cooling channel section each have an outer side surface which is opposite the adjacent side surfaces. A drive axis of the fan is arranged closer to a plane of the outer side surface of the second cooling channel section than to a plane of the outer side surface of the first cooling channel section.

"Arranged closer" means that the distance of the drive axis to one plane is smaller than to the other plane. The distance is the shortest possible distance between any point on the drive axis and a plane. However, the drive axis is not the mathematically infinitely long axis, but only the designed axis of the fan, which is limited to the height of the fan.

While, as mentioned above, the flow cross-sectional areas of the two evaporator sections can be designed asymmetrically in order to condense the majority of the cooling air before it flows through the fan, it can also be provided that the fan is not symmetrical in the middle of the planes of the outer side surfaces, but to be arranged asymmetrically, ie closer to one plane than to the other plane of the outer side surfaces, so that the arrangement of the fan in the curved section is coordinated with the asymmetrical configuration of the flow cross-sectional areas of the evaporator sections.

The drive axis is advantageously arranged between the plane of the outer side surface of the first cooling channel section, in particular a plane of the adjacent side surface of the first cooling channel section, and a plane of the adjacent side surface of the second cooling channel section.

In addition, the fan can be designed as a radial fan.

Since the design of the centrifugal fan already provides for a deflection of the air flow, it is particularly suitable for installation between the two evaporator sections.

The radial fan is advantageously arranged such that its axis of rotation is arranged at an angle of less than 87 °, in particular less than 85 °, in particular less than 80 °, to a flow direction of the cooling air flow through the first evaporator section.

This means that the cooling air flow only has to be deflected by the corresponding angle in order to flow into the radial fan. This enables an arrangement of the radial fan with the lowest possible flow resistance.

The at least one cooling duct is advantageously arranged in such a way that the cooling air flows through the first evaporator section from the rear to the front.

“Front” is to be understood as that side of the refrigerator on which a user door is arranged, through the opening of which a user gains access to the refrigerator and / or freezer compartments.

In addition, the first evaporator section can be arranged between a freezer compartment and a cooling compartment of the refrigerator.

Brief description of the drawings

[0036] Further embodiments, advantages and applications of the invention emerge from the dependent claims and from the description that follows with reference to the figures. Show: <tb> Fig. 1 <SEP> the cooling unit in full view, <tb> Fig. 2 <SEP> a detailed view of section A from FIG. 1 with the evaporator and fan, <tb> Fig. 3 <SEP> a section through the two evaporator sections and through the fan, and <tb> Fig. 4 <SEP> a detailed view from above of the cold area with fan.

Ways of Carrying Out the Invention

1 shows a refrigerator designed as a built-in refrigerator with a refrigerator compartment 1 and a freezer compartment 2. Between the refrigerator compartment 1 and the freezer compartment 2 there is a cold area 3 and below the freezer compartment 2 a warm area 4 is arranged. An evaporator 5 for cooling the cooling compartment 1 and the freezer compartment 2 is arranged in the cold area 3. In the warm area 4, a heat-emitting compressor 6 and a heat-emitting capacitor 7 are arranged. The arrangement of the cold area 3 between the refrigeration compartment 1 and the freezer compartment 2 is advantageous because the cold area 3 and the warm area 4 are thereby thermally separated from one another by the freezer compartment. The cold area 3 and the warm area 4 are connected by refrigerant lines so that the refrigerant can circulate in the heat pump circuit. The more detailed configuration of the cold area is illustrated in more detail by FIGS. 2 to 4.

In Fig. 2, the cold area 3 is shown, the front of the refrigerator, on which a user door 8 is arranged, on the right side of FIG. 2 and the rear of the refrigerator, on which a rear wall 9 and a rear insulation element 10 are shown on the left-hand side of FIG.

The cooling air flow from the cooling compartment 1 is guided from above through a first air discharge duct 11 and the cooling air flow from the freezer compartment 2 from below through a second air discharge duct 12 into the cold area. After entering the cold area, the cooling air flows in the given order through a first evaporator section of the evaporator 5, through a fan 13 which conveys the cooling air flow back in the opposite direction, through a second evaporator section of the evaporator 5 and then via air supply ducts 14 and 15 to the cooling compartment 1 and to the freezer compartment 2.

In Fig. 3 is a section through the cold area 3 is shown with a view from above. The front side with the user door 8 is shown at the bottom in FIG. 3 and the rear side of the cooling device is at the top of FIG. 3.

The cooling air flow enters the cold area 3 through the air discharge ducts 11 and 12. The cooling air flow then flows (direction of flow shown by arrows) <tb> - <SEP> through a first cooling channel section 16 in which the first evaporator section 51 is arranged, <tb> - <SEP> through a curved cooling duct section 17 in which the radial fan 13 is arranged, <tb> - <SEP> back in the opposite direction through a second cooling channel section 18 in which the second evaporator section 52 is arranged.

The radial fan 13 deflects the cooling air flow by approximately 180 °.

The first evaporator section 51 and the second evaporator section 52 are arranged adjacent to one another and separated from one another by a partition 19. Although the two evaporator sections 51 and 52 have the same length 20 in the direction of flow, they have different flow cross-sectional areas. The width of the flow cross-sectional area of the first evaporator section 51 is shown in FIG. 3 with a double arrow 21. Due to the larger cross-sectional area of the first evaporator section 51, the cooling air flow is cooled significantly more before it flows through the fan 13 than when it flows through the second evaporator section 52. As a result, the cooling air flow condenses for the most part before the fan 13, so there is a risk of condensation precipitates on the rotor blades of the fan 13, reduced.

In order to optimize the deflection of the cooling air flow in the curved section 17 of the cooling channel, the fan 13 is not arranged centrally in the cold area 3. The drive axis 131 of the fan 13 is arranged closer to a plane 32 of the outer side surface of the second cooling channel section 18 than to a plane 31 of the outer side surface of the first cooling channel section 16. Furthermore, the drive axis 131 is between the plane 31 of the outer side surface of the first cooling channel section 16 and a plane 34 of the adjacent side of the second cooling channel section.

The adjacent side surfaces 33, 34 are the side surfaces adjoining the partition 19.

4 shows the cold area in an external view from above.

Claims (10)

1. Cooling device, in particular a built-in refrigerator, comprising - at least one cooling channel (16,17,18), - A heat pump with a first evaporator section (51) which is arranged in a first cooling channel section (16) of the at least one cooling channel (16, 17, 18), - A fan (13) for conveying a flow of cooling air in the at least one cooling duct (16, 17, 18), the fan (13) being arranged in the at least one cooling duct (16, 17, 18) downstream of the first evaporator section (51) is characterized in that the fan (13) is arranged in a curved section (17) of the cooling channel (16,17,18). 2. Cooling device according to claim 1, wherein the curved section (17) of the cooling channel (16,17,18) is designed to deflect the cooling air flow by at least 75 °, in particular at least 160 °, in particular approximately 180 °. 3. Cooling device according to one of the preceding claims, wherein downstream of the fan (13) a second evaporator section (52) is arranged in a second cooling channel section (18) of the at least one cooling channel (16, 17, 18). 4. Cooling device according to claim 3, wherein the second evaporator section (18) has a smaller flow cross-sectional area and / or a smaller length in the flow direction than the first evaporator section (51), in particular wherein the first (51) and / or the second (52) evaporator section each extend over the entire flow cross-sectional area of the at least one cooling channel (16, 17, 18). 5. Cooling device according to one of claims 3 or 4, wherein the curved section (17) of the cooling channel (16,17,18) has a change in direction of approximately 180 °, the first (16) and the second cooling channel section (18) are arranged in this way that they border one another on adjacent side surfaces and that the cooling air flow can flow through them in the opposite direction, in particular wherein a partition (19) is arranged between the first (51) and the second (52) evaporator section to separate the cooling air flow in the first evaporator section (51) from the cooling air flow in the second evaporator section (52). 6. Cooling device according to claim 5, wherein the first (16) and the second (18) cooling channel section each have an outer side surface which is opposite the adjacent side surfaces, and wherein a drive axis (131) of the fan (13) closer to a plane of the outer Side surface (32) of the second cooling channel section (18) is arranged than to a plane of the outer side surface (31) of the first cooling channel section (16), In particular, the drive axis (131) between the plane of the outer side surface (31) of the first cooling channel section (16), in particular a plane of the adjacent side surface (33) of the first cooling channel section (16), and a plane of the adjacent side surface (34) of the second Cooling channel section (18) is arranged. 7. Cooling device according to one of the preceding claims, wherein the fan (13) is designed as a radial fan. 8. Cooling device according to claim 7, wherein the radial fan (13) is arranged such that its axis of rotation (131) at an angle of less than 87 °, in particular less than 85 °, in particular less than 80 °, to a flow direction of the cooling air flow through the first evaporator section (51) is arranged. 9. Cooling device according to one of the preceding claims, wherein the at least one cooling channel (16, 17, 18) is arranged such that the cooling air flows through the first evaporator section (51) from the rear to the front. 10. Cooling device according to one of the preceding claims, wherein the first evaporator section (51) is arranged between a freezer compartment (2) and a cooling compartment (2) of the cooling device.