JP6941005B2 - Electrical equipment - Google Patents

Description

The present invention relates to a technique for cooling the inside of a housing in an electric device such as a power supply device.

Many electrical devices have electronic circuits built in the housing that require protection from foreign substances such as water and dust. Such an electric device has a structure for cooling an electronic circuit while protecting it from foreign matter (see, for example, Patent Document 1). Specifically, a first chamber and a second chamber are provided between the bottom wall and the top wall of the housing, and in the first chamber, air is provided along the top wall from the intake port to the exhaust port. A flow path is formed, and the second chamber is arranged adjacent to the first chamber via a partition wall. Then, an electronic circuit is installed in the second chamber, and fins for cooling the second chamber by heat exchange with the air flowing through the flow path are installed in the first chamber.

Japanese Unexamined Patent Publication No. 11-251499

However, the above-mentioned electric device has the following problems. That is, since the heat generated in the electronic circuit is transferred to the first chamber through the fins, a large amount of heat is collected. Therefore, although the heat transferred to the first chamber is discharged from the exhaust port by the air flowing through the first chamber, a large amount of heat is directly transferred to the top wall, and the top wall is excessively heated. Be done. If the top wall is overheated, heat will be released from an unintended location (that is, a location different from the exhaust port).

The environment in which electrical equipment is used varies from user to user. For example, electrical equipment may be used in an environment where other heat-sensitive devices are placed around it. When an electric device is used in such an environment, if the electric device releases a large amount of heat from the top wall, the electric device itself may become a heat source and affect another device. ..

Therefore, an object of the present invention is to provide an electric device in which excessive heat is prevented from being released from the top wall of the housing.

The electric device according to the present invention includes a first chamber having a bottom wall and a top wall, and a flow path for air flowing along the bottom wall is formed in the housing, and the first chamber is adjacent to the first chamber. The arranged second room and third room are provided. The housing further includes a first partition wall and a second partition wall. The first partition wall extends from the bottom wall to the top wall and partitions between the first chamber and the second chamber. The second partition wall includes a standing plate portion extending from the bottom wall toward the top wall and a horizontal plate portion extending laterally from the upper end of the standing plate portion to the first partition wall, whereby the first partition wall is formed. Along with partitioning the chamber from the third chamber, the first chamber is separated from the top wall by the horizontal plate portion.

According to the above-mentioned electric device, the ceiling of the first chamber is formed by the horizontal plate portion separated from the top wall, so that the first chamber is arranged apart from the top wall. As a result, a part of the third chamber is interposed between the first chamber and the top wall, and as a result, it becomes difficult for heat to be transferred from the first chamber to the top wall. Therefore, even if the horizontal plate portion is directly heated by the heat in the first chamber, the heat is not easily transferred from the horizontal plate portion to the top wall, and therefore the top wall is not excessively heated.

According to the present invention, excessive heat is prevented from being released from the top wall of the housing.

It is a perspective view which showed the power supply device which is an embodiment of this invention as seen from (a) front side and (b) back side respectively. It is a cross-sectional view which showed the internal structure of a power supply device. It is a vertical sectional view along the line III-III shown in FIG. It is a breaking perspective view which partially showed the internal structure of a housing. It is a cross-sectional view which showed the modification of the power supply device.

An embodiment in which the present invention is applied to a power supply device will be specifically described with reference to the drawings. 1A and 1B are perspective views showing the power supply device according to the embodiment of the present invention as viewed from the front side and the back side, respectively. As shown in FIGS. 1A and 1B, the power supply device includes a housing 1 having an intake port 1a and an exhaust port 1b. The housing 1 has a front wall 10A, a rear wall 10B, left and right side walls 10C and 10D, a top wall 10E, and a bottom wall 10F as outer walls having a box shape.

FIG. 2 is a cross-sectional view showing the internal configuration of the power supply device. FIG. 3 is a vertical cross-sectional view taken along the line III-III shown in FIG. Further, FIG. 4 is a broken perspective view partially showing the internal configuration of the housing 1. As shown in FIGS. 2 to 4, a first chamber 11, a second chamber 12, and a third chamber 13 are provided in the housing 1. Specifically, the housing 1 has a first partition wall 14A that separates the first chamber 11 and the second chamber 12, and a second partition wall 14B that partitions the first chamber 11 and the third chamber 13. The first chamber 11 to the third chamber 13 are formed by these partition walls and the outer wall, and the second chamber 12 and the third chamber 13 are arranged adjacent to the first chamber 11. .. More specifically, it is as follows.

The first partition wall 14A extends perpendicularly to the bottom wall 10F from the bottom wall 10F to the top wall 10E (see FIG. 3), and extends from the front wall 10A to the rear wall 10B (see FIG. 2). The first partition wall 14A is screwed to each of the front wall 10A and the rear wall 10B (see FIG. 2).

The second partition wall 14B includes a vertical plate portion 141 and a horizontal plate portion 142 (see FIG. 3). The standing plate portion 141 is a portion extending from the bottom wall 10F toward the top wall 10E. Specifically, the standing plate portion 141 extends perpendicularly to the bottom wall 10F in a state of facing the first partition wall 14A. Further, the horizontal plate portion 142 is a portion extending in the lateral direction from the upper end of the vertical plate portion 141 to the first partition wall 14A. In the present embodiment, the second partition wall 14B is formed by bending and deforming a flat plate. Therefore, the second partition wall 14B has high strength against the assembly of various parts (fins, wiring, etc.) described later.

Further, both the standing plate portion 141 and the horizontal plate portion 142 extend from the front wall 10A to the rear wall 10B (see FIG. 2). Then, the standing plate portion 141 is screwed to each of the front wall 10A and the rear wall 10B (see FIG. 2), and the end portion 141a of the horizontal plate portion 142 opposite to the standing plate portion 141 is formed. It is screwed to the first partition wall 14A (see FIGS. 3 and 4).

The first chamber 11 is formed by being surrounded by a front wall 10A, a rear wall 10B, a bottom wall 10F, a first partition wall 14A, and a second partition wall 14B. Then, on the front wall 10A, an intake port 1a is formed at a position where the outside air can be directly sucked into the first chamber 11 (see FIG. 2). Further, on the rear wall 10B, an exhaust port 1b is formed at a position where the air in the first chamber 11 can be directly discharged to the outside (see FIG. 2). In the present embodiment, as shown in FIGS. 1A and 1B, a cover 8 having a plurality of slits is attached to the intake port 1a. Further, the exhaust port 1b is composed of a plurality of through holes formed in the rear wall 10B.

According to such a first chamber 11, a main flow path 21 is formed in the first chamber 11 to allow air sucked from the intake port 1a to flow along the bottom wall 10F to the exhaust port 1b (see FIG. 2). ). Further, according to the second partition wall 14B, the ceiling of the first chamber 11 is formed by the horizontal plate portion 142 separated from the top wall 10E, so that the first chamber 11 is arranged apart from the top wall 10E. (See Fig. 3). As a result, a part of the third chamber 13 is interposed between the first chamber 11 and the top wall 10E, and as a result, it becomes difficult for heat to be transferred from the first chamber 11 to the top wall 10E.

The second chamber 12 is formed by being surrounded by a wall excluding the side wall 10D of the outer walls constituting the housing 1 and a first partition wall 14A, and is sealed by these walls. .. Therefore, the second chamber 12 has dustproof performance. Further, the third chamber 13 is formed by being surrounded by a wall excluding the side wall 10C of the outer wall constituting the housing 1, a first partition wall 14A, and a second partition wall 14B. ..

As shown in FIGS. 2 and 3, the power supply device further includes a fan 3, a first fin 51, and a second fin 52, which are installed in the first chamber 11. The fan 3 is installed at a position in the first chamber 11 and in the vicinity of the intake port 1a, and sucks air from the intake port 1a into the first chamber 11 (see FIG. 2). The fan 3 may be installed at another position in the first chamber 11 or outside the housing 1 as long as air can be sucked into the first chamber 11 from the intake port 1a. It may be installed in a position.

The air sucked from the intake port 1a driven by the fan 3 passes through the first fin 51 and the second fin 52. Then, the first fin 51 cools the inside of the second chamber 12 by heat exchange with the air flowing through the main flow path 21. Further, the second fin 52 cools the inside of the third chamber 13 by heat exchange with the air flowing through the main flow path 21. By the air flowing in the first chamber 11 in this way, not only the parts and the like provided in the first chamber 11 are directly cooled by the air, but also the parts and the like provided in the first chamber 11 are cooled directly in the second chamber 12 and the third chamber 13. The provided circuits, components, and the like (main circuit 41, input / output circuit 42, etc., which will be described later) are indirectly cooled via the first fin 51 and the second fin 52.

Further, in the present embodiment, a part of the air sucked from the intake port 1a is guided to the third chamber 13. Specifically, the standing plate portion 141 of the second partition wall 14B is provided with the first vent 6a and the second vent 6b (see FIG. 2). The first vent 6a allows a part of the air sucked from the intake port 1a to flow into the third chamber 13 at a position close to the intake port 1a. Further, the second vent 6b causes the air in the third chamber 13 to flow out to the first chamber 11 at a position close to the exhaust port 1b. As a result, a sub-flow path 22 is formed in the third chamber 13 to allow a part of the air sucked from the intake port 1a to flow from the first ventilation port 6a to the second ventilation port 6b. Then, by flowing air into the third chamber 13 in this way, the circuits and parts provided in the third chamber 13 can be directly cooled by the air. By adjusting the opening area, shape, position, etc. of the first vent 6a and the second vent 6b, the amount of air flowing into the third chamber 13 can be adjusted.

As shown in FIG. 2, the power supply device further includes a power supply circuit constructed in the housing 1. The power supply circuit includes a first winding 40A, a second winding 40B, a main circuit 41, an input / output circuit 42, and a control circuit 43. In the present embodiment, the first winding 40A is arranged in the first chamber 11, the main circuit 41 and the control circuit 43 are arranged in the second chamber 12, and a part of the second winding 40B and the input / output circuit 42. (Mainly wiring 422) is arranged in the third room 13. In FIG. 2, the illustration of the parts constituting the various circuits is partially omitted.

The first winding 40A and the second winding 40B are parts that do not require protection from foreign matter such as dust and have corrosion resistance, and are accompanied by heat generation during operation. Since such a component can be cooled by directly blowing the air sucked from the intake port 1a, it is arranged in the first chamber 11 and the third chamber 13 through which the air flows.

The main circuit 41 includes a smoothing circuit, a converter circuit, and the like, and these circuits include many precision parts such as switch elements that require protection from foreign matter such as dust. Further, the control circuit 43 also includes many precision parts such as an IC (Integrated Circuit) chip that require protection from foreign matter such as dust. Therefore, the main circuit 41 and the control circuit 43 are arranged in the closed second chamber 12. Further, since the main circuit 41 and the control circuit 43 include many heat-generating parts, cooling is required during operation. Therefore, the power supply device has the following configuration for cooling the inside of the second chamber 12.

As shown in FIGS. 2 and 3, a first opening 71 is formed in the first partition wall 14A, and the first fin 51 sets the flat surface thereof in order to close the first opening 71 without a gap. 1 It is installed in the first chamber 11 in a state of being in close contact with the partition wall 14A. That is, the first fin 51 is closely fixed to the surface of the first partition wall 14A on the first chamber 11 side. As described above, the first fin 51 bears a part of the structure for sealing the second chamber 12, so that the second chamber 12 is maintained in a state of being shielded from the outside air. The first fin 51 is not limited to the case where the first fin 51 is closely fixed in direct contact with the first partition wall 14A, and may be closely fixed to the first partition wall 14A via an insulating material or the like.

The main circuit 41 is directly fixed to a portion of the flat surface of the first fin 51 (the surface in close contact with the first partition wall 14A) exposed from the first opening 71. Therefore, the main circuit 41 is indirectly cooled via the first fin 51 by the air flowing in the first chamber 11. When the first partition wall 14A has thermal conductivity, it is possible to cool the inside of the second chamber 12 through the first partition wall 14A even without the first opening 71. In this case, the first fin 51 is brought into close contact with the surface of the first partition wall 14A on the first chamber 11 side, and the precision parts constituting the main circuit 41 are placed on the surface of the first partition wall 14A on the second chamber 12 side. It is preferable that the substrate and the like are brought into close contact with each other.

In the present embodiment, as described above, the main circuit 41 is attached to the flat surface of the first fin 51 or the first partition wall 14A, so that the main circuit 41 is attached to the second chamber with respect to the first partition wall 14A. It is possible to assemble from the 12 side (that is, one direction perpendicular to the first partition wall 14A).

Further, in the present embodiment, the third partition wall 14C is arranged substantially parallel to the first partition wall 14A in the second chamber 12 (see FIG. 3). A control circuit 43 is arranged on the side opposite to the first partition wall 14A with respect to the third partition wall 14C. Specifically, the third partition wall 14C is screwed to the rear wall 10B, and the control circuit 43 is attached to the surface of the third partition wall 14C opposite to the first partition wall 14A (). (See FIG. 2). On the other hand, due to the presence of the third partition wall 14C, the main circuit 41 is arranged between the first partition wall 14A and the third partition wall 14C. That is, the third partition wall 14C is interposed between the main circuit 41 and the control circuit 43. Therefore, the third partition wall 14C prevents the main circuit 41 and the control circuit 43 from exerting thermal influences on each other.

Further, since the third partition wall 14C is provided in the second chamber 12, the heat remaining in the second chamber 12 without being transferred to the first chamber 11 among the heat from the main circuit 41 is transferred to the top wall. It can be raised toward 10E and discharged to the outside through the top wall 10E. At this time, the amount of heat transferred from the second chamber 12 to the top wall 10E is directly transferred from the first chamber 11 to the top wall 10E if there is no horizontal plate portion 142 of the second partition wall 14B. It is significantly smaller than the amount of brazing heat.

The input / output circuit 42 includes an input / output terminal 421, wiring 422 in the power supply circuit, and the like. The input / output terminal 421 is pulled out from the portion of the rear wall 10B that constitutes the third chamber 13 (see FIG. 2). The wiring 422 is responsible for the components necessary for constructing the power supply circuit and the connection between the circuits. Such an input / output circuit 42 does not require as much protection from foreign matter such as dust as the main circuit 41, but requires appropriate cooling. Therefore, by arranging the input / output circuit 42 in the third chamber 13, the input / output circuit 42 is directly cooled by the air flowing along the auxiliary flow path 22, and the second chamber 11 is cooled by the air flowing in the first chamber 11. It is indirectly cooled via the fins 52. Specifically, the power supply device has the following configuration for cooling the inside of the third chamber 13.

As shown in FIGS. 2 and 3, a second opening 72 is formed in the standing plate portion 141 of the second partition wall 14B, and the second opening 72 is closed (even if a gap is partially generated). Good), the second fin 52 is installed in the first chamber 11 with its flat surface in close contact with the standing plate portion 141. That is, the second fin 52 is closely fixed to the surface of the standing plate portion 141 on the first chamber 11 side.

Then, the connection terminals and the like included in the wiring 422 are directly fixed to the portion of the flat surface of the second fin 52 (the surface in close contact with the second partition wall 14B) exposed from the second opening 72. Therefore, the wiring 422 is indirectly cooled via the second fin 52 by the air flowing in the first chamber 11. When the second partition wall 14B has thermal conductivity, the inside of the third chamber 13 can be cooled through the second partition wall 14B even without the second opening 72. In this case, the second fin 52 is brought into close contact with the surface of the second partition wall 14B on the first chamber 11 side, and the connection terminal or the like included in the wiring 422 is provided on the surface of the second partition wall 14B on the third chamber 13 side. It is preferable to bring them into close contact with each other.

In the present embodiment, as described above, the input / output circuit 42 (connection terminal or the like) is attached to the flat surface of the second fin 52 or the second partition wall 14B, so that the input / output circuit 42 is attached to the second partition wall. It is possible to assemble the 14B from the third chamber 13 side (that is, one direction perpendicular to the second partition wall 14B).

In this way, the first fin 51 and the second fin 52 exchange heat with the air flowing along the main flow path 21 in the first chamber 11, so that the second chamber 12 and the third chamber 13 are cooled, respectively. Will be done. That is, the heat in the second chamber 12 is transferred to the first chamber 11 through the first fin 51, and the heat in the third chamber 13 is transferred through the second fin 52. Therefore, a large amount of heat is collected in the first chamber 11 through the first fin 51 and the second fin 52. Therefore, although the heat transferred to the first chamber 11 is discharged from the exhaust port 1b by the air flowing in the first chamber 11, a large amount of heat is directly transferred to the horizontal plate portion 142. The horizontal plate portion 142 is heated.

In the power supply device of the present embodiment, as described above, since the first chamber 11 is arranged apart from the top wall 10E, it is difficult for heat to be transferred from the first chamber 11 to the top wall 10E. Therefore, even if the horizontal plate portion 142 is heated by the heat in the first chamber 11, it is difficult for the heat to be transferred from the horizontal plate portion 142 to the top wall 10E. Therefore, the top wall 10E is not excessively heated, and therefore, excessive heat is prevented from being excessively released from the top wall 10E of the housing 1.

Further, in the power supply device of the present embodiment, as described above, the main circuit 41 is assembled with respect to the first partition wall 14A from the second chamber 12 side (that is, one direction perpendicular to the first partition wall 14A). Is possible. Further, the input / output circuit 42 can be assembled to the second partition wall 14B from the third chamber 13 side (that is, one direction perpendicular to the second partition wall 14B). Further, the control circuit 43 can be attached to the third partition wall 14C. The first partition wall 14A and the second partition wall 14B are both screwed to the front wall 10A and the rear wall 10B, respectively, and the third partition wall 14C is screwed to the rear wall 10B.

Therefore, it is not necessary to provide a partition wall or screw holes for attaching various circuits on the top wall 10E and the bottom wall 10F, and therefore, foreign matter such as water and dust is unlikely to enter the housing 1. Further, various circuits are attached to a partition wall or the like in a state of floating from the bottom wall 10F in the housing 1. Therefore, even if water should enter the housing 1, it is difficult for the various circuits to be immersed in the water collected at the bottom of the housing 1, and therefore, it is possible to avoid failures of the various circuits due to the inundation. ..

Further, in the power supply device of the present embodiment, since the first chamber 11 is arranged apart from the top wall 10E by the horizontal plate portion 142, the horizontal plate portion 142 and the top wall 10E are arranged as shown in FIG. A gap is formed between them. Therefore, in order to pass the lead wire W from the second chamber 12 to the third chamber 13 at various positions between the front wall 10A and the rear wall 10B in the portion of the first partition wall 14A exposed to the gap. Through hole 15 can be provided. Therefore, the degree of freedom of wiring for connecting the various circuits in the second chamber 12 (for example, the main circuit 41) and the various circuits in the third chamber 13 (for example, the input / output circuit 42) is increased, and the degree of freedom of wiring is increased. As a result, it becomes possible to connect the circuits between the second chamber 12 and the third chamber 13 with short wiring.

FIG. 5 is a cross-sectional view showing a modified example of the power supply device. In the second chamber 12, when the main circuit 41 and the control circuit 43 do not exert thermal influences on each other, or when such thermal influences can be tolerated, the power supply device is used as shown in FIG. , The second chamber 12 may have a configuration in which the third partition wall 14C is not provided.

The description of the embodiments described above should be considered exemplary in all respects and not restrictive. The scope of the present invention is shown not by the above-described embodiment but by the scope of claims. Furthermore, the scope of the present invention is intended to include all modifications within the meaning and scope equivalent to the claims.

For example, the power supply device may have a configuration that does not have the second fin 52. In this case, it is preferable that the second partition wall 14B is used as a heat exchange portion instead of the second fin 52 by giving the second partition wall 14B thermal conductivity. By providing thermal conductivity not only to the second partition wall 14B but also to the first partition wall 14A, the first partition wall 14A and the second partition wall 14B replace the first fin 51 and the second fin 52, respectively. It may be used as a heat exchange unit.

Further, each part configuration of the cooling structure constructed in the power supply device can be applied not only to the power supply device but also to various electric devices.

1 Housing 1a Intake port 1b Exhaust port 3 Fan 6a First vent 6b Second vent 8 Cover 10A Front wall 10B Rear wall 10C, 10D Side wall 10E Top wall 10F Bottom wall 11 First room 12 Second room 13 Third Room 14A 1st partition wall 14B 2nd partition wall 14C 3rd partition wall 15 Through hole 21 Main flow path 22 Sub flow path 40A 1st winding 40B 2nd winding 41 Main circuit 42 Input / output circuit 43 Control circuit 51 1st fin 52 2nd fin 71 1st opening 72 2nd opening 141 Standing plate 141a End 142 Horizontal plate 421 Input / output terminal 422 Wiring W Lead wire

Claims (5)

A first chamber having a housing having a bottom wall and a top wall and having a flow path for air flowing along the bottom wall is formed in the housing, and a second chamber arranged adjacent to the first chamber and the like. It is an electric device provided with a third room,
The housing is
A first partition wall extending from the bottom wall to the top wall and partitioning between the first chamber and the second chamber.
A standing plate portion extending from the bottom wall toward the top wall and a horizontal plate portion extending laterally from the upper end of the standing plate portion to the first partition wall are included, thereby forming the first chamber. A second partition wall that partitions the third chamber and separates the first chamber from the top wall by the horizontal plate portion.
Further, electrical equipment. The electrical device according to claim 1, wherein the second partition wall is formed by bending and deforming a flat plate. The housing further has a third partition wall arranged substantially parallel to the first partition wall in the second chamber.
A power supply circuit including a first circuit and a second circuit is constructed in the housing, and the first circuit is arranged between the first partition wall and the third partition wall, and the third circuit is arranged. The electric device according to claim 1 or 2, wherein the second circuit is arranged on the side opposite to the first partition wall with respect to the partition wall. The first circuit is assembled to the first partition wall from the second chamber side.
A third circuit, which is a part of the power supply circuit, is arranged in the third chamber, and the third circuit is assembled from the third chamber side to the standing plate portion of the second partition wall. Item 3. The electrical device according to item 3. The first fin, which is installed in the first chamber and cools the second chamber by heat exchange with the air flowing through the flow path,
The second fin, which is installed in the first chamber and cools the third chamber by heat exchange with the air flowing through the flow path,
The electric device according to any one of claims 1 to 4, further comprising.

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