DE202022101010U1 - Radiator and cooled electrical equipment assembly - Google Patents

Abstract

Radiator comprising:
a body portion (92) of the radiator;
a plurality of cooling fins (94) extending from the body portion (92) of the cooler and each having a leading edge (95) having a first end (96) and a second end (97) spaced from the first end (96), and a trailing edge (98) having a first end (99) and a second end (100) spaced from the first end (99), the direction between the first end (96) of the leading edge (95) and the first end ( 99) of the trailing edge (98) is the fin direction, and in which at least part of the edge between the first end (96) of the leading edge (95) and the first end (99) of the trailing edge (98) of each cooling fin (94) is in contact with the body part (92),
characterized in that in each cooling fin (94) the second end (97) of the leading edge (95) in the fin direction is closer to the first end (99) of the trailing edge (98) than the first end (96) of the leading edge (95), and the second end (100) of the trailing edge (98) is further from the first end (96) of the leading edge (95) in the rib direction than the first end (99) of the trailing edge (98).

Description

field of invention

The invention relates to a cooler and a cooled electrical device assembly.

Background of the Invention

It is known to provide a radiator that includes a body portion and a plurality of cooling fins extending from the body portion of the radiator. Each cooling fin has a leading edge having a first end and a second end spaced from the first end, and a trailing edge having a first end and a second end spaced from the first end. The direction between the first end of the leading edge and the first end of the trailing edge is the rib direction. The problem with known coolers is that cooling the body part of the cooler is not effective.

Brief description of the invention

The aim of the invention is to introduce a cooler in which the cooling of the body part is more effective than before. The object of the invention is provided with a cooler characterized by what is disclosed in the independent claim. Preferred embodiments of the invention are disclosed in the dependent claims.

The invention is based on the fact that in each cooling fin the second end of the leading edge in the fin direction is closer to the first end of the trailing edge than the first end of the leading edge, and the second end of the trailing edge in the fin direction is further from the first end of the leading edge away than the first end of the trailing edge.

The advantage of the radiator according to the invention is that due to the shape of the cooling fins, the cooling of the body part of the radiator is more effective than before.

character list

• 1 eine direkte Seitenansicht eines Kühlers gemäß einer Ausführungsform der Erfindung zeigt;
• 2 eine Prinzipansicht eines Querschnitts einer gekühlten elektrischen Geräteanordnung gemäß einer Ausführungsform der Erfindung zeigt;
• 3 eine direkte Draufsicht einer gekühlten elektrischen Geräteanordnung gemäß einer Ausführungsform der Erfindung zeigt; und
• 4 einen Querschnitt der gekühlten elektrischen Geräteanordnung von 3 zeigt.

The invention will now be described in more detail in connection with preferred embodiments and with reference to the accompanying drawings, in which:

• 1 Figure 12 shows a direct side view of a cooler according to an embodiment of the invention;
• 2 Figure 12 shows a schematic view of a cross-section of a cooled electrical equipment assembly according to an embodiment of the invention;
• 3 Figure 12 shows a direct plan view of a cooled electrical equipment assembly according to an embodiment of the invention; and
• 4 a cross section of the cooled electrical equipment assembly of FIG 3 indicates.

Detailed description of the invention

In accordance with one embodiment of the invention, the radiator includes a radiator body portion 92 and a plurality of cooling fins 94 extending from the radiator body portion 92 . It is possible to use e.g. air or another gaseous coolant as coolant in the radiator.

1 Figure 12 shows a side view of a cooler according to an embodiment of the invention. Due to the viewing angle, the figure shows only one of the multiple cooling fins 94. As in 1 As can be seen, each cooling fin 94 has a leading edge 95 having a first end 96 and a second end 97 spaced from the first end 96, and a trailing edge 98 having a first end 99 and a second end 100 spaced from the first End 99. The direction between the first end 96 of the leading edge 95 and the first end 99 of the trailing edge 98 is the rib direction. In the example of 1 the edge between the first end 96 of the leading edge 95 and the first end 99 of the trailing edge 98 of each cooling fin 94 is fully in contact with the body portion 92 of the radiator. Thus, the second end 97 of the leading edge 95 and the second end 100 of the trailing edge 98 of each cooling fin 94 extend a distance from the body portion 92 of the radiator.

In alternative embodiments, only a portion of the edge between the first end 96 of the leading edge 95 and the first end 99 of the trailing edge 98 of each cooling fin 94 is in contact with the body portion 92 of the radiator.

As in 1 As can be seen, the second end 97 of the leading edge 95 of each cooling fin 94 is closer in the fin direction to the first end 99 of the trailing edge 98 than the first end 96 of the leading edge 95. Therefore, the leading edge 95 of each cooling fin 94 lies in one of the perpendicular direction in Relative to the rib direction divergent direction.

In other words, fin material has been removed from the leading edge 95 of each fin 94 of the inventive radiator compared to an assembly including a fin 94 rectangular in shape. The solution according to the invention can provide savings in material usage in the manufacture of the cooler without significantly weakening the heat transfer performance of the chiller.

As in 1 As can further be seen, the second end 100 of the trailing edge 98 of each cooling fin 94 is further from the first end 96 of the leading edge 95 in the fin direction than the first end 99 of the trailing edge 98. Then the trailing edge 98 of each cooling fin 94 is not perpendicular with respect to the fin direction, but fin material was added at the trailing edge 98 of the fin 94 compared to the fin arrangement of the prior art cooler in which the trailing edge of each fin is perpendicular with respect to the fin direction. The arrangement according to the invention can increase the heat transfer performance of a cooler compared to the known cooler.

Overall, due to the shape of the cooling fins 94, the cooling of the body portion 92 of the radiator of the present invention is more effective than before when there is no fin material at the leading edge 95 of each cooling fin 94 that does not effectively cool the body portion 92 of the radiator and at the trailing edge 98 of each Cooling fin 94 is more fin material to increase the cooling capacity of the radiator compared to the cooling fin 94 with a rectangular shape.

Each cooling fin 94 of a radiator according to an in 1 The illustrated embodiment of the invention is planar such that a plane of cooling fin 94 extending from body portion 92, which plane is bounded by leading edge 95 and trailing edge 98, and which plane defines the cooling fin plane is flat. The thickness dimension of each fin 94 is in the direction normal to the fin plane. In other words, the thickness dimension of each cooling fin 94 is small relative to the other dimensions of the cooling fin 94.

The shape of each cooling fin 94 of the radiator according to an in 1 The embodiment of the invention shown is polygonal, more precisely rectangular, so that the leading edge 95 and the trailing edge 98 are parallel to one another. In the example of 1 For example, the shape of each cooling fin 94 is that of a parallelogram, more specifically, a diagonal parallelogram. The edge between the first end 96 of the leading edge 95 and the first end 99 of the trailing edge 98, and the edge between the second end 97 of the leading edge 95 and the second end 100 of the trailing edge 98 are parallel to each other. The angles between the edges of the diagonal parallelogram, the interior angles of the parallelogram, deviate from right angles.

In alternative embodiments, the shape of the cooling fins 94 of the cooler deviates from that in FIG 1 shown, e.g. B. so that the leading edge 95 and / or the trailing edge 98 of the cooling fins 94 are not straight or so that the position of the second end 97 of the leading edge 95 and / or the second end 100 of the trailing edge 98 deviates from that shown in the figure . Therefore, the cooling fins 94 of the cooler can then be, for example, of pentagonal or hexagonal shape or trapezium or deviate from flat.

The surface of the radiator body portion 92 along an in 1 The illustrated embodiment of the invention to which the cooling fins 94 are attached is planar in shape and defines a body part plane with respect to which the cooling fin plane of each cooling fin 94 is in the direction normal. In alternative embodiments, the direction of each cooling fin 94 relative to the body portion 92 of the radiator differs from that in FIG 1 example shown, eg such that the plane of the cooling fins is at an angle of 70° with respect to the plane of the body part.

In accordance with one embodiment of the invention, the cooling fins 94 extend from the body portion 92 of the radiator in a substantially parallel manner. In other words, the planes of the cooling fins are parallel to one another. In alternative embodiments, the cooling fin planes are divergent from each other.

3 and 4 12 show a cooled electrical equipment assembly according to an embodiment of the invention. All elements shown in the figures are not necessarily essential to the invention. The cooled electrical equipment assembly comprises a housing 2 enclosing a cooling duct 4 adapted for the flow of a coolant such as air or other gaseous coolant. The cooling duct 4 has an inlet end 41 for introducing cooling air into the cooling duct 4 and an outlet end 42 for removing cooling air from the cooling duct 4 . The direction of flow of the cooling air is from the inlet end 41 to the outlet end 42 of the cooling channel 4 .

In the 3 and 4 The cooled electrical device arrangement shown comprises a cooler according to an embodiment described above. The plurality of cooling fins 94 of the radiator form a plurality of fin passages therebetween, which define a fin portion 49 of the cooling passage 4 . Each fin channel has an inlet end 301 for introducing cooling air into the fin channel and an outlet end 302 for removing cooling air from the fin channel.

2 12 is a schematic view of a vertical cross section of a cooled electrical equipment assembly according to an embodiment of the invention at a point where a cooling fin 94 is located closest to the inlet end of the cooling duct 4. FIG. As in 2 you can see, the shape of the cooling fin 94 of the radiator according to the invention allows the cooling channel 4 to be more spacious at the location of the inlet of the fin portion 49 than before. In other words, the flow of cooling air has more space in the cooling duct 4 before the flow of cooling air merges into the rib section 49 via the inlet end 301 of each rib duct. Then, the flow of cooling air into the fin portion 49 is facilitated.

According to a 3 and 4 shown embodiment of the invention, the cooling duct 4 comprises a first cooling duct segment 401, a second cooling duct segment 402 and a third cooling duct segment 403, which are parallel cooling duct segments z. B. can be ducts separated by walls or equivalent structures so that each of them is arranged to direct a parallel partial flow of the cooling air flow through them. In alternative embodiments, the cooling channel 4 does not include any cooling channel segments 401, 402, 403.

A cooled electrical equipment assembly according to an embodiment of the invention includes at least one coolable electrical component that is attached to the body portion 92 of the cooler in a thermally conductive manner. The at least one coolable electrical component may be attached directly to the radiator body portion 92 in a thermally conductive manner or indirectly attached to the radiator body portion 92 in a thermally conductive manner such that one or more thermally conductive elements are located therebetween. According to one embodiment of the invention, the at least one coolable electrical component includes at least one semiconductor module that has at least one controllable semiconductor switch.

According to a 3 In the embodiment of the invention shown, at least one coolable electrical component comprises a first semiconductor module 11, a second semiconductor module 12 and a third semiconductor module 13, each of which is attached in a thermally conductive manner to the body part 92 of the cooler. in the in 3 In the example shown, the first semiconductor module 11, the second semiconductor module 12 and the third semiconductor module 13 further include two semiconductor elements each.

The cooling channel 4 of the cooled electrical device arrangement according to an in 3 and 4 The embodiment of the invention shown in FIG is arranged. In the 3 and 4 The cooled electrical device arrangement shown comprises capacitors 6, which are arranged in the capacitor section 46 of the cooling channel 4, and impedance coils 7, which are arranged in the impedance coil section 47 of the cooling channel 4.

The cooling fin section 49 of the cooling channel 4 of a cooled electrical device arrangement according to an in 3 and 4 The embodiment of the invention shown comprises a first rib channel segment 31, a second rib channel segment 32 and a third rib channel segment 33, which are parallel rib channel segments of the rib portion 49 such that the first rib channel segment 31 is arranged to cool a first semiconductor module 31, the second rib channel segment 32 is arranged to cool a second semiconductor module 32, and the third fin channel segment 33 is arranged to cool a third semiconductor module 33. In addition, the cooling air flow is arranged to run in cooling duct segments 401, 402, 403 from the inlet end 41 of the cooling duct 4 to the inlet end 301 of each rib duct, so that the first cooling duct segment 401 is in flow communication with the first rib duct segment 31, the second cooling duct segment 402 in is in flow communication with the second fin channel segment 32 , and the third cooling channel segment 403 is in flow communication with the third fin channel segment 33 .

It is obvious to a person skilled in the art that the basic idea of the invention can be implemented in many different ways. The invention and its embodiments are therefore not limited to the examples described above, but may vary within the scope of the claims.

Claims (9)

A radiator comprising: a radiator body portion (92); a plurality of cooling fins (94) extending from the body portion (92) of the cooler and each having a leading edge (95) having a first end (96) and a second end (97) spaced from the first end (96), and a trailing edge (98) having a first end (99) and a second end (100) spaced from the first end (99), the direction between the first end (96) of the leading edge (95) and the first end ( 99) of the trailing edge (98) is the fin direction, and in which at least part of the edge between the first end (96) of the leading edge (95) and the first end (99) of the trailing edge (98) of each cooling fin (94) is in contact with the body portion (92), characterized in that in each cooling fin (94) the second end (97) of the leading edge (95) is closer to the first end (99) of the trailing edge (98) in the rib direction than the first end (96) of the leading edge (95), and the second end (100) the trailing edge (98) is further from the first end (96) of the leading edge (95) in the rib direction than the first end (99) of the trailing edge (98). cooler after claim 1 , each cooling fin (94) being substantially planar. cooler after claim 1 or 2 wherein a plurality of cooling fins (94) extend substantially parallel from the body portion (92) of the radiator. cooler after claim 1 , 2 or 3 wherein each cooling fin (94) is polygonal in shape. cooler after claim 4 wherein each cooling fin (94) is rectangular in shape. cooler after claim 4 or 5 wherein the leading edge (95) and the trailing edge (98) of each cooling fin (94) are parallel to each other. cooler after claim 6 wherein each cooling fin (94) is of parallelogram shape. A cooled electrical equipment assembly comprising: a housing (2) including a cooling duct (4) arranged for the flow of cooling air such that the cooling duct (4) has an inlet end (41) for introducing cooling air into the cooling duct (4 ) and an outlet end (42) for removing cooling air from the cooling duct (4), the direction of flow of cooling air being from the inlet end (41) towards the outlet end (42) of the cooling duct (4); at least one coolable electrical component, characterized in that the cooled electrical equipment assembly comprises a cooler as in any one of Claims 1 - 7 as claimed, wherein a plurality of cooling fins (94) form between them a plurality of fin channels which define a fin portion (49) of the cooling channel (4) of the electrical equipment assembly, each fin channel having an inlet end (301) and an outlet end (302), and wherein the at least one coolable electrical component is attached to the body portion (92) of the cooler in a thermally conductive manner. Cooled electrical equipment assembly after claim 8 , wherein the at least one coolable electrical component comprises at least one semiconductor module comprising at least one controllable semiconductor switch.

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