JP7122680B2 - Case of power conversion device, power conversion device, case, and electrical equipment - Google Patents

Description

TECHNICAL FIELD The present disclosure relates generally to power converter housings, power converters, housings, and electrical equipment, and more particularly to power converter housings, power converters, housings, and electrical equipment that include a power conversion unit. Regarding.

Patent Literature 1 describes a power converter. This power conversion device includes a die-cast housing. The rear surface of the housing is composed of a surface on one side and a surface on the other side, and the surface on one side is higher than the surface on the other side. A group of fins are integrally formed on one side surface and the other side surface, respectively, and stand up. Also, on the back surface, a plurality of component storage portions are integrally formed by biting into a part of the fin group and protruding from the inside of the housing to the back surface side.

JP 2015-126590 A

In the power conversion device configured as described above, a housing in which a group of fins is integrally formed and a plurality of component storage sections are integrally formed is used, so the overall shape of the housing is relatively complicated. shape.

The present disclosure has been made in view of the above reasons, and an object thereof is to provide a housing for a power conversion device, a power conversion device, a housing, and an electric device that can adopt a relatively simple shape.

A housing of a power conversion device according to an aspect of the present disclosure is a housing that includes a plurality of switching elements and reactors and houses a power conversion unit that converts power. The housing includes a heat sink, a second case, and a first case. The heat sink is thermally coupled to the plurality of switching elements to dissipate heat from the plurality of switching elements. The second case has an opening formed by an edge and accommodates the reactor. The first case accommodates the plurality of switching elements, and is attached with the heat sink and the second case. The second case includes a wall extending from the edge and surrounding the reactor, and a wall for fixing the second case to the first case with the edge of the second case facing the first case. and a fixed portion. The fixing part is located in an area surrounded by the outer surface of the wall.

A power conversion device according to an aspect of the present disclosure includes a housing of the power conversion device and a power conversion unit housed in the housing.

A housing according to an aspect of the present disclosure includes a first case that accommodates a first heating element inside, and a second case that accommodates a second heating element inside. The first case has a first portion on the outer surface thereof, on which a heat sink for releasing heat generated by the first heating element is arranged, and the second case is arranged at a position different from the first portion. a second portion, respectively. The second case has a second opening at a position facing the first opening in the second part in a state of being fixed to the second part. The second case has a fixing portion inside the outer surface of the wall surrounding the second opening. The second case is fixed to the second part via the fixing part so as to cover the first opening.

An electrical device according to one aspect of the present disclosure includes the housing.

Advantageously, the present disclosure may employ relatively simple geometries.

FIG. 1 is a perspective view showing a power converter according to one embodiment of the present disclosure. FIG. 2 is a perspective view showing a state in which the back cover of the power converter is removed. FIG. 3 is a partially broken side view of the power conversion device of the same. FIG. 4 is a perspective view showing a first case of the same power converter. FIG. 5 is a perspective view showing a second case of the same power converter. FIG. 6 is a perspective view showing an arrangement state of the second case and the first case of the power conversion device same as the above. 7 is a cross-sectional view taken along the line XX in FIG. 6. FIG. FIG. 8 is a partially cutaway perspective view showing the fixation of the first case and the fixing portion of the second case of the power conversion device. FIG. 9A is a cross-sectional view showing a modification of the second case of the power converter same as the above. FIG. 9B is a front view showing a second case used in the power converter according to the modified example of the embodiment of the present disclosure; FIG. 9C is a front view showing a second case used in the power converter according to one embodiment of the present disclosure;

(embodiment)
The housing of the power converter according to this embodiment will be described below. In addition, the front-rear, left-right, and up-down directions in the following description are used for the sake of convenience, and are not meant to define the direction of use of the power conversion device, the electrical equipment, and the housing. Forward, backward, leftward, rightward, upward and backward directions are indicated by arrows in each figure.

FIG. 1 is a perspective view showing the appearance of a power converter (power conditioner) 1 according to this embodiment. The power conversion device 1 is an example of the electrical equipment 1X according to this embodiment. The power conversion device 1 converts, for example, DC power obtained from a power source such as a solar power generation facility into AC power, and outputs the AC power to an electrical device (including a distribution board, etc.) or a load such as a power system. . The power source may be any device that outputs DC power, and may be a storage battery facility, a fuel cell facility, or the like. Moreover, if the load is storage battery equipment, the power supply may be a system power supply. In this case, the power conversion device 1 converts AC power obtained from a power supply (system power supply) into DC power and outputs the DC power to a load (storage battery equipment). In addition, the power conversion device 1 may convert the voltage of DC power input from the power supply and output DC power to the load, or may convert the voltage of AC power input from the power supply and output the AC power to the load. may be output.

A power conversion device 1 according to the present embodiment includes a housing 70 and a power conversion section 14 . The power converter 1 according to the present embodiment further includes a lid 15 and a cover 16 in addition to the housing 70 and the power converter 14 .

The housing 70 includes a first case 11 , a second case 12 and a heat sink 13 . As shown in FIG. 2 , the second case 12 and heat sink 13 are attached to the first case 11 . In the power conversion device 1 according to the present embodiment, the second case 12 and the heat sink 13 are arranged behind the rear surface of the first case 11 , that is, behind the back surface (rear surface) 116 . The second case 12 and the heat sink 13 are arranged side by side in the left-right direction.

The power conversion unit 14 includes, for example, a power conversion circuit that converts input DC power into AC power and outputs the AC power. A power conversion circuit includes a plurality of electrical components (including electronic components). The electrical parts are, for example, circuit boards, input terminals, output terminals, input/output terminals, rectifying elements, noise filters, switching elements, reactors, and the like. In the power conversion device 1 according to the present embodiment, some of the electrical components that make up the power conversion unit 14 are housed in the first case 11, and some of the other electrical components are housed in the second case 12. housed (see FIG. 3).

The lid 15 is attached to the front side of the first case 11 . The lid 15 closes the front opening 110 of the first case 11 . The lid 15 is made of various metal materials, such as iron or its alloy. The lid body 15 is formed by molding a metal plate (sheet metal) by pressing and drawing, for example. The lid 15 closes the front opening 110 of the first case 11 to protect the power converter 14 housed in the first case 11 from dust, wind and rain, sunlight, and other natural environments.

The cover 16 is attached to the rear side of the first case 11 . The cover 16 covers the second case 12 and the heat sink 13 arranged on the rear surface 116 of the first case 11 . Like the lid 15, the cover 16 is made of various metal materials, such as iron or its alloy. The cover 16 is formed by pressing and drawing a metal plate (sheet metal), for example. Also, a plurality of slits 161 are formed in the cover 16 . Each slit 161 penetrates the cover 16 in the thickness direction. Each slit 161 is formed long in the front-rear direction. The cover 16 protects the second case 12 and the heat sink 13 from natural environment such as dust, wind, rain and sunlight. In addition, the cooling performance of the second case 12 and the heat sink 13 is less likely to be impaired by the plurality of slits 161 . In other words, air can pass from the outside to the inside of the cover 16 through the plurality of slits 161, the supply of air to the second case 12 and the heat sink 13 is less likely to be impaired, and the cooling performance of the second case 12 and the heat sink 13 is improved. Hard to damage.

As shown in FIG. 4, the first case 11 is a bottomed box having an opening on one side. That is, the first case 11 is a box having a front opening 110 and having an inner surface of a rear wall 111 facing the front opening 110 as a bottom surface. The first case 11 is made of metal, preferably metal having high thermal conductivity. Note that the first case 11 may have a lower thermal conductivity than the second case 12 . The first case 11 is made of various metal materials, such as iron or its alloy. The first case 11 is configured by forming a metal plate (sheet metal) by pressing and drawing, for example.

The first case 11 has a square shape when viewed from the front (when viewed from the front). That is, the front opening 110 and the rear wall 111 have a square shape when viewed from the front. The first case 11 has a top wall 112 , a right wall 113 , a left wall 114 and a bottom wall 115 . The upper wall 112 protrudes forward from the upper end of the rear wall 111 . The right wall 113 protrudes forward from the right end of the rear wall 111 . The left wall 114 protrudes forward from the left end of the rear wall 111 . The lower wall 115 protrudes forward from the lower end of the rear wall 111 . A front opening 110 is formed by being surrounded by front ends of a top wall 112 , a right wall 113 , a left wall 114 and a bottom wall 115 . A cover attachment piece 150 is formed around the front opening 110 . The lid attachment piece 150 is a portion for attaching the lid 15 to the first case 11 . The lid mounting piece 150 protrudes outward (opposite to the front opening 110) from the front ends of the upper wall 112, the right wall 113, the left wall 114 and the lower wall 115. As shown in FIG.

A plurality of holes 2 are formed in the rear wall 111 of the first case 11 . Each hole 2 penetrates the rear wall 111 in the thickness direction. That is, each hole 2 penetrates the rear wall 111 in the front-rear direction. Some of the plurality of holes 2 are formed as first openings 21 . The first opening 21 faces a second opening 120 formed in the second case 12, which will be described later. Some of the plurality of holes 2 are formed as third openings 23 . In the third opening 23, among the components housed in the first case 11, the components that come into contact with the heat sink 13 are arranged. That is, the first case 11 accommodates a heat transfer plate that comes into contact with an electrical component that generates heat. By thermally coupling the heat transfer plate exposed on the rear surface 116 and the heat sink 13 , heat is transferred from the heat-generating electrical component to the heat sink 13 through the heat transfer plate. The thermal connection between the two includes a mode in which the two are connected by contact, a mode in which the two are opposed to each other with a gap, and a mode in which a member having thermal conductivity is interposed between the two. The electrical components that generate heat include a plurality of switching elements 141 that constitute the power converter 14 . The switching element 141 is a semiconductor element (MOSFET, IGBT, etc.), and is an electrical component that generates heat when the power converter 1 operates. Further, among the plurality of holes 2, the fourth opening 24 is an opening for passing wiring connected to a solar cell, an electric power system, a storage battery, and the like.

The first opening 21 is elongated in the vertical direction. The edge of the first opening 21 is formed in a substantially square shape when viewed from the front. A plurality of fixing pieces 212 are formed on the edge 211 of the first opening 21 . A plurality of fixed pieces 212 are arranged at intervals so as to surround the periphery of the first opening 21 . Each fixing piece 212 is made up of a part of the metal plate forming the rear wall 111 . Each fixed piece 212 has an arcuate tip when viewed from the front. Each fixed piece 212 is formed with a through hole 213 penetrating in the thickness direction. A protruding piece 214 is provided on the edge 211 of the first opening 21 . The protruding piece 214 is formed over the entire length of the edge portion 211 including the fixed piece 212 . That is, the protruding piece 214 is formed so as to surround the entire circumference of the first opening 21 . The protruding piece 214 is formed to protrude forward from the edge 211 . In other words, the protruding piece 214 protrudes inside the first case 11 . The projecting piece 214 can be formed by bending a part of the metal plate forming the rear wall 111 . The protruding piece 214 can reinforce the edge 211 of the first opening 21 . Therefore, when the second case 12 is attached to the edge 211 of the first opening 21, the rear wall 111 is less likely to be deformed.

As shown in FIG. 5, the second case 12 has an opening formed by the edge 127 . That is, of the second case 12 , the edge portion 127 is the portion forming the opening, that is, the portion positioned around the opening. In the housing 70 of the power converter 1 according to this embodiment, the opening of the second case 12 is the second opening 120 . Therefore, a portion of the second case 12 located around the second opening 120 serves as an edge portion 127 .

Here, the second case 12 is a bottomed box having an opening on one side. That is, the second case 12 is a box having a second opening 120 and having a bottom portion 121 facing the second opening 120 as a bottom. The second case 12 is made of metal, preferably metal having high thermal conductivity. The second case 12 preferably has higher thermal conductivity than the first case 11 . The second case 12 is made of various metal materials, such as aluminum or an aluminum alloy. The second case 12 is formed by die casting, for example. That is, the second case 12 is preferably a casting obtained by press-fitting molten metal into a mold. The second case 12 is preferably a die-cast product made of aluminum or an aluminum alloy.

Comparing the volumes of the first case 11 and the second case 12 , the first case 11 has a larger volume than the second case 12 . In other words, the first case 11 can accommodate more electrical components constituting the power converter 14 than the second case 12, and the second case 12 constitutes the power converter 14 more than the first case 11. Small capacity for electrical components. Therefore, the second case 12 accommodates, among the electrical components that make up the power converter 14, electrical components that particularly require heat dissipation. The power converter 1 according to the present embodiment includes a reactor 142 as an electrical component housed in the second case 12 . When the second case 12 is made of die casting, it may be more expensive than when it is formed by bending a metal plate (formed by sheet metal processing). However, in the power conversion device 1 according to the present embodiment, the second case 12 has a smaller volume than the first case 11, so it is cheaper than making both the second case 12 and the first case 11 die-cast. can be realized.

The second case 12 has a wall 122 extending from an edge 127 . That is, wall 122 extends rearwardly from edge 127 surrounding second opening 120 . The wall 122 is formed to surround the bottom 121 over its entire length. A wall 122 protrudes forward from the bottom portion 121 . That is, the wall 122 is formed to protrude forward from the peripheral edge of the bottom portion 121 . Wall 122 is integrally formed with bottom 121 . An internal space surrounded by the bottom portion 121 and the wall 122 is a space for housing electrical components. The internal space of the second case 12 is open to the front surface of the second case 12 through the second opening 120 . A partition portion 123 is provided inside the second case 12 . The partition part 123 divides the internal space of the second case 12 into upper and lower parts. Partition 123 is formed integrally with wall 122 and bottom 121 . A bottom surface 128 of the second case 12 is a portion of the surface (front surface) of the bottom portion 121 that faces the second opening 120 .

The second case 12 has a fixing portion 30 . The fixing portion 30 is a portion for fixing the second case to the first case 11 with the edge portion 127 side of the second case 12 facing the first case 11 . That is, the second case 12 is fixed to the first case 11 by the fixing portion 30 . Fixed portion 30 is located in a region surrounded by outer surface 124 on the opposite side of reactor 142 in the thickness direction of wall 122 . In other words, the fixed part 30 may be formed inside the outer surface 124 of the wall 122 , for example, the fixed part 30 may be formed on the edge 127 . That is, the fixing portion 30 may be formed on the edge portion 127 that is the end portion of the second case 12 . In this case, the fixing portion 30 is formed on the edge portion 127 surrounding the second opening portion 12 . Here, the thickness direction of the wall 122 is a direction perpendicular to the outer surface 124 of the wall 122 at a position rearward of the second opening 120 and forward of the bottom surface 128 . For example, the direction orthogonal to the outer surface 124 at the center of the second case 12 in the front-rear direction (excluding the position of the partition 123 ) is the thickness direction of the wall 122 .

In the power converter 1 according to the present embodiment, the fixing portion 30 protrudes from the inner surface 125 on the reactor 142 side in the thickness direction of the wall 122 . That is, the fixing portion 30 is formed so as to protrude from the outer surface 124 into the inner space of the second case 12 . As a result, the fixing portion 30 does not protrude from the outer surface 124 of the second case 12, and when the second case 12 is attached to the back surface 116 of the first case 11, the area occupied by the second case 12 on the back surface 116 is reduced. .

That is, if the fixing portion 30 protrudes from the outer surface 124 of the second case 12, the area (the area of the cross section) of the fixing portion 30 is increased to the outside of the second case 12 by the amount of protrusion. The area occupied by the second case 12 on the rear surface 116 is increased. On the other hand, in the power conversion device 1 according to the present embodiment, since the fixed portion 30 is located inside the outer surface 124 of the second case 12 , there is no space occupied by the fixed portion 30 on the outer surface 124 of the second case 12 . Therefore, the area occupied by the second case 12 on the back surface 116 is reduced. As a result, interference between the second case 12 and the heat sink 13 is less likely to occur, and for example, it is possible to increase the size of the heat sink 13 while avoiding interference with the second case 12 .

The second case 12 has a protruding portion 35 protruding toward the inner surface 125 of the wall 122 on the edge portion 127 , and the fixing portion 30 is provided on the protruding portion 35 . That is, the projecting portion 35 projects from the edge portion 127 into the second opening portion 120 , and the fixing portion 30 is formed on the projecting portion 35 . That is, the second case 12 has the fixing portion 30 on the edge portion 127 . Here, the fixed portion 30 is a portion including at least the screw hole 31 .

The fixed portion 30 is formed long in the front-rear direction. That is, the fixed portion 30 is continuous from the second opening 120 of the second case 12 to the bottom surface 128 surrounded by the wall 122 of the second case 12 . As a result, the heat of the edge portion 127 can be easily conducted to the bottom portion 121 through the fixing portion 30, and the heat dissipation of the second case 12 can be improved. In other words, when the fixed part 30 is fixed to the first case 11, the fixed part 30 and the first case 11 come into contact with each other to improve the heat transfer performance, and the heat dissipation performance of the second case 12 is improved.

Further, the wall 122 of the second case 12 can be reinforced by the fixing portion 30, and the strength of the second case 12 is improved. That is, the fixing portion 30 functions as a rib that reinforces the wall 122, increasing the strength of the second case 12. As shown in FIG. The fixed portion 30 is formed in a truncated cone shape elongated in the front-rear direction. Therefore, the surface of the fixed portion 30 exposed to the internal space of the second case 12 is a curved surface. In addition, the fixed portion 30 is formed so as to become wider as it approaches the bottom portion 121 . Therefore, the fixing portion 30 becomes thicker especially on the side closer to the bottom 121 than the second opening 120 , and the strength of the side closer to the bottom 121 of the second case 12 is improved than the side closer to the second opening 120 .

A screw hole 31 is formed in the fixed portion 30 . The screw hole 31 is open to the front surface 32 of the fixed part 30 . The screw hole 31 is a female screw having a thread formed on its inner peripheral surface, and is a cap screw with one end closed. The front surface 32 of the fixed portion 30 is at the same position as the front surface 126 of the edge portion 127 in the longitudinal direction. That is, the front surface 32 of the fixing portion 30 is at the same position as the edge portion 127 surrounding the second opening 120 in the front-rear direction. A raised portion 33 is provided on the front surface 32 of the fixed portion 30 . The raised portion 33 protrudes forward from the front surface 32 . Also, the rising portion 33 is formed along the edge portion 127 surrounding the second opening portion 120 . The raised portion 33 is formed over the entire circumference of the second opening 120 along the edge 127 surrounding the second opening 120 .

A plurality of fixing portions 30 are formed in the second case 12 . The plurality of fixing parts 30 are arranged at intervals so as to surround the second opening 120 . Each fixing part 30 can be formed in the same number as the plurality of fixing pieces 212 provided on the edge 211 of the first opening 21 . Also, one fixing piece 212 may be formed to correspond to each fixing part 30 .

The second case 12 has a plurality of fins 129 on its rear surface. Each fin 129 is long in the vertical direction. Also, the plurality of fins 129 are arranged side by side in the left-right direction at predetermined intervals. The heat dissipation of the second case 12 is enhanced by the plurality of fins 129 .

The second case 12 is fixed to the first case 11 by the fixing portion 30 . That is, the second case 12 is fixed to the first case 11 at the fixing portion 30 with the edge portion 127 side facing. The second case 12 is fixed to the rear wall 111 of the first case 11 . That is, the second case 12 is arranged along the rear surface 116 of the first case 11 and fixed to the rear wall 111 . When the second case 12 is arranged behind the rear surface 116, the second opening 120 of the second case 12 and the first opening 21 of the first case 11 are substantially at the same position in the front-rear direction. That is, as shown in FIG. 6, the first opening 21 of the first case 11 and the second opening 120 of the second case 12 are positioned so as to substantially overlap in the front-rear direction. 12 are arranged. Also, each of the plurality of fixing portions 30 is arranged corresponding to one fixing piece 212 . That is, one fixing portion 30 is aligned with each of the plurality of fixing pieces 212 .

The second case 12 is arranged to block the first opening 21 which is the hole 2 of the first case 11 and fixed to the first case 11 . That is, the first opening 21 is closed by being covered with the second case 12 . Also, the rising portion 33 of the second case 12 is arranged inside the first opening portion 21 . That is, as shown in FIGS. 7 and 8, the outer surface of the raised portion 33 is arranged along the inner surface of the projecting piece 214 of the first opening 21 . By doing so, positioning on the rear surface 116 of the second case 12 can be easily performed. In other words, the raised portion 33 of the second case 12 is fitted into the first opening 21 and positioned along the edge 211 of the first opening 21 . And the raised portion 33 abuts on the projecting piece 214 . Therefore, the position of the second case 12 is restricted by the edge portion 211 and the projecting piece 214, and the second case 12 is positioned.

A sealing material 40 is arranged between the front surface 126 and the rear surface 116 of the edge 127 of the second case 12 . The sealing material 40 closes the gap between the first case 11 and the second case 12 to improve the waterproofness of the internal spaces of the first case 11 and the second case 12 . The sealing material 40 is arranged so as to surround the first opening 21 and the second opening 120 . That is, it is formed corresponding to the shape of the edge 211 of the first opening 21 and the edge 127 surrounding the second opening 120 . The sealing material 40 can be made of synthetic resin. Examples of synthetic resins that can be used include silicone resins, modified silicone resins, urethane resins, acrylic resins, and butyl resins. The sealing material 40 may be a molded product, or may be formed by applying a liquid resin material and then curing it. Also, the sealing material 40 can be provided on one or both of the rear surface 116 and the front surface 126 of the edge 127 of the second case 12 .

When the second case 12 is arranged on the rear surface 116, the front surface 32 of the fixed portion 30 and the rear surface of the fixed piece 212 of the first case 11 are arranged to face each other with the sealing material 40 interposed therebetween, as shown in FIG. In this case, the screw hole 31 of the fixing portion 30 and the through hole 213 of the fixing piece 212 are aligned. That is, the opening of the screw hole 31 and the opening of the through hole 213 are arranged to face each other in the front-rear direction. Then, as shown in FIG. 8 , a fastener 50 such as a screw (including screws and bolts) is brought close to the through hole 213 from the front and inserted into the through hole 213 . That is, the fixture 50 is inserted into the through hole 213 from the space inside the first case 11 . After this, the fixture 50 is tightened and coupled to the screw hole 31 . That is, the fixing of the second case 12 to the first case 11 by the fixture 50 is performed from the space inside the first case 11 . Then, by tightening the fixtures 50 through the through holes 213 in the same manner as described above, the plurality of fixing pieces 212 and the plurality of fixing portions 30 are fixed by the fixtures 50 respectively. be done. A bolt may be provided in place of the screw hole 31, a nut may be used in place of the fixture 50, and the bolt and nut may be tightened.

Inside the second case 12 attached to the first case 11, some of the electrical components that constitute the power converter 14 are accommodated. In the power conversion device 1 according to the present embodiment, as described above, the reactor 142 among the electrical components forming the power conversion section 14 is accommodated in the second case 12 (see FIG. 3). The reactor 142 protrudes rearward from the first opening 21 of the first case 11 . That is, the reactor 142 is positioned rearward of the back surface 116 of the first case 11 and accommodated in the internal space of the second case 12 . The power converter 14 includes two types of reactors 142, one of which is a direct current reactor (DCL) and the other of which is an alternating current reactor (ACL). The power converter 14 includes a plurality of DC reactors and a plurality of AC reactors. The DC reactor and the AC reactor can be arranged in two spaces inside the second case 12 partitioned by the partition portion 123 .

As shown in FIG. 3, the internal space of the second case 12 is filled with a resin material 55 . The resin material 55 fills the space inside the second case 12 other than the space occupied by the reactor 142 . Therefore, the resin material 55 comes into contact with both the reactor 142 and the inner surface 125 of the second case 12 , and heat generated in the reactor 142 can be easily transferred to the second case 12 via the resin material 55 . Therefore, the heat generated by the reactor 142 can be efficiently dissipated in the second case 12 . The resin material 55 has electrical insulation and thermal conductivity (thermal conductivity higher than the heat transfer coefficient of air), and a liquid resin can be used. After being injected into the second case 12, the liquid resin material 55 is cured by heat or light. The resin material 55 may be epoxy resin, for example. However, it is not necessary for the resin material 55 to completely fill the space other than the space occupied by the reactor 142 in the internal space of the second case 12, and at least part of the gap between the second case 12 and the reactor 142 is filled. All you have to do is fill it in.

In addition, in the power conversion device 1 according to the present embodiment, since the fixing portion 30 protrudes into the internal space of the second case 12, compared to the case where the fixing portion 30 does not protrude into the internal space of the second case 12, the fixing The filling amount of the resin material 55 can be reduced by the volume of the portion 30 . Therefore, it is possible to reduce the cost and weight by reducing the amount of the resin material 55 to be filled.

In the power conversion device 1 according to this embodiment, the heat sink 13 is arranged on the side (left side) of the second case 12 on the rear surface 116 of the first case 11 . The heat sink 13 is made of a material with high thermal conductivity. For example, the heat sink 13 can be made of a metallic material such as aluminum. The heat sink 13 has a substrate 131 and a plurality of fins 132 . Each fin 132 protrudes rearward from the substrate 131 . Further, each fin 132 is formed elongated in the vertical direction. The plurality of fins 132 are arranged in the left-right direction at intervals.

The front surface of the substrate 131 of the heat sink 13 is fixed to the rear surface 116 of the first case 11 . The substrate 131 is attached so as to close the third opening 23 of the first case 11 . The front surface of the substrate 131 is in contact with the heat transfer plate exposed through the third opening 23 . Therefore, heat can be transferred from the heat transfer plate to the substrate 131 and dissipated by the heat sink 13 .

In the power converter 1 according to the present embodiment, since the fixing portion 30 does not protrude from the outer surface 124 of the second case 12 , the second case 12 is less likely to interfere with the heat sink 13 . Further, since the fixing portion 30 does not protrude from the outer surface 124 of the second case 12, the area of the second case 12 occupying the rear surface 116 can be reduced. Therefore, even if the heat sink 13 and the fourth opening 24 in which the wiring is arranged are not made smaller, the layout of the arrangement of the heat sink 13 and the fourth opening 24 can have a margin. Therefore, the size of the first case 11 can be reduced.

That is, if the fixing portion 30 protrudes from the outer surface 124 of the second case 12, the area of the second case 12 on the rear surface 116 is increased. Therefore, if the heat sink 13 and the fourth opening 24 of a predetermined size are provided, the rear surface 116 must be enlarged, and the size of the first case 11 is increased. On the other hand, in the power conversion device 1 according to the present embodiment, since the fixing portion 30 for fixing to the first case 11 is provided inside the second case 12, the area of the second case 12 occupying the back surface 116 is small. Therefore, the size of the first case 11 can be reduced, and the power conversion device 1 as a whole can also be reduced in size.

(Modification)
The embodiment is but one of various embodiments of the present disclosure. The embodiments can be modified in various ways according to design and the like as long as the object of the present disclosure can be achieved.

Although the case of the power conversion device 1 has been described above as an example of the electric device 1X, the electric device 1X other than the power conversion device 1 may be used without being limited to this. Examples of the electrical equipment 1X other than the power conversion device 1 include, for example, storage battery equipment, power generation equipment, power measuring equipment, control panels, server devices, home electric appliances, and the like.

In this case, the electrical device 1X can be provided with a first case 60 equivalent to the first case 11 and a second case 61 equivalent to the second case 12 to form a housing 70 for the electrical device 1X.

The first case 60 can house the first heating elements 63 corresponding to the plurality of switching elements 141 . Further, the second case 61 can house a second heating element 64 corresponding to the reactor 142 . The first case 60 has a first portion 65 and a second portion 66 . The first portion 65 is a portion of the outer surface 67 corresponding to the rear surface 116 where the heat sink 13 for releasing heat generated by the first heating element 63 to the outside is arranged. The second portion 66 is a portion of the outer surface 67 where the second case 61 is arranged at a position different from that of the first portion 65 . The first case 60 has a first opening 21 and the second case 61 has a second opening 120, respectively. The openings 120 are opposed to each other. The second case 61 has a fixing portion 30 inside the outer surface 124 , and the second case 61 is fixed to the second portion 66 of the first case 60 via the fixing portion 30 .

The second case 61 and the first case 60 are separate bodies. That is, the second case 61 and the first case 60 are separate parts, which are manufactured separately and then assembled to form a housing. Therefore, the housing can be configured by combining the simply shaped second case 61 and the simply shaped first case 60 . Therefore, the manufacturing cost of the housing is less likely to increase than in the case of manufacturing a complicated-shaped housing without separating the second case 61 and the first case 60 . Further, if the second case 61 and the first case 60 are separate parts, the cost can be reduced by making the material of one part cheaper or by simplifying the manufacturing of the other part. Further, since the fixing portion 30 does not protrude from the outer surface 124 of the second case 61, the area occupied by the second portion 66 can be reduced. Therefore, even if the area occupied by the first portion 65 is not reduced, the layout of the arrangement of the heat sink 13 can have a margin. Therefore, it is possible to reduce the size of the housing.

Although the fixed part 30 is fixed to the fixed piece 212 of the first case 11 by screwing in the above description, the fixed part 30 may be fixed by an adhesive. Alternatively, the fixing portion 30 and the fixing piece 212 may be fixed by both screwing and adhesive.

FIG. 9A shows a modification in which the shape of the fixing portion 30 is different from that in FIG. The fixed portion 30 has a projecting dimension toward the inside of the second case 12 that gradually decreases from the front surface 32 toward the bottom portion 121 . That is, the fixed portion 30 has a projecting dimension toward the inside of the second case 12 that gradually decreases from the end on the second opening 120 side toward the bottom portion 121 . In this case, since the volume of the fixed portion 30 occupying the internal space of the second case 12 is reduced, the internal space of the second case 12 can be widened.

The second case 12 may also have fins inside. In this case, the heat conduction within the second case 12 can be improved, and the heat conduction to the outer surface of the second case 12 can be enhanced to improve heat dissipation.

The power converter 1 in this embodiment may be either wall-mounted or stationary (floor-mounted). That is, the power conversion device 1 may be attached to a wall such as an outer wall of a building, or may be installed on the floor of the building or on the ground around the building.

The power conversion device 1 according to the present embodiment is not limited to outdoor use, and may be indoor use. If the power conversion device 1 is for indoor use, high waterproofness is not required.

In the power conversion device 1 of the present embodiment, the heat sink 13 and the second case 12 may be arranged not only in the horizontal direction but also in the vertical direction. Also, the heat sink 13 may be on the right side, the left side, the upper side, or the lower side of the second case 12 .

In this embodiment, as shown in FIG. 9C, a sealing member 40 is arranged. That is, in the second case 12 , the sealing member 40 is arranged inside the fixed portion 30 when viewed from the second opening 120 side. The sealing material 40 is arranged so as to be positioned closer to the inner surface of the second case 12 than the screw hole 31 of the fixing portion 30 . In this case, the sealing material 40 is arranged on the front surface 32 of the fixed part 30 . Since such a sealing material 40 is positioned so as to surround the screw hole 31, even if water entering from the outside of the second case 12 reaches the screw hole 31, the sealing material 40 can easily block the water, thereby improving the waterproof performance. Get better.

On the other hand, FIG. 9B shows a modification. In the second case 12 , the fixing portion 30 is between the sealing material 40 and the edge portion 127 when viewed from the second opening 120 side. That is, the sealing material 40 is arranged so as to be positioned outside the fixed portion 30 . In other words, the sealing member 40 is arranged so as to be positioned closer to the outer surface of the second case 12 than the screw hole 31 of the fixing portion 30 . In this case, the sealing material 40 is not arranged on the front surface 32 of the fixed part 30 .

Such a sealing material 40 can be arranged along the edge 127 surrounding the second opening 120, so that the arrangement of the sealing material 40 can be simplified and workability is improved. In addition, since the screw hole 31 is located inside the sealing material 40, the water entering from the outside of the second case 12 is easily blocked by the sealing material 40 before reaching the screw hole 31, and waterproof performance is improved.

The water that enters from the outside of the second case 12 includes rain water, dew condensation water, melted snow water, and the like.

(summary)
As described above, the housing (70) of the power conversion device (1) according to the first aspect has a plurality of switching elements (141) and reactors (142), and the power conversion unit ( 14). A housing (70) comprises a heat sink (13), a second case (12) and a first case (11). A plurality of switching elements (141) are arranged on the heat sink (13), and heat is dissipated from the plurality of switching elements (141). The second case (12) has an opening (120) formed by a rim (127) and accommodates a reactor (142). A first case (11) accommodates a plurality of switching elements (141) and is attached with a heat sink (13) and a second case (12). The second case (12) has a wall (122) and a fixed part (30). A wall (122) extends from the edge (127) and surrounds the reactor (142). The fixing part (30) fixes the second case (12) to the first case (11) with the edge (127) side of the second case (12) facing the first case (11). The fixed part (30) is located in the area bounded by the outer surface (124) of the wall (122).

The housing (70) of the power converter (1) according to the first aspect can be formed separately from the second case (12), and the first case (11) and the second case (12) are There is an advantage that the manufacturing cost can be reduced compared to the case of integrally forming.

A housing (70) of a power conversion device (1) according to a second aspect is, in the first aspect, a first case (11) having a hole (2) and a second case (12) having: It is fixed to the first case (11) so as to block the hole (2).

In the case (70) of the power conversion device (1) according to the second aspect, the second case ( 12) can block the hole (2).

In the case (70) of the power converter (1) according to the third aspect, in the first or second aspect, the edge (127) protrudes toward the inner surface (125) of the wall (122) ( 35). The fixing part (30) is provided on the protruding part (35).

In the case (70) of the power conversion device (1) according to the third aspect, the fixed part (30) protrudes from the edge (127) toward the inner surface (125) of the wall (122). Therefore, it does not protrude to the outer surface (124) of the wall (122) of the second case (12). For this reason, the area occupied by the second case (12) in the first case (11) can be reduced, and the degree of freedom in the layout of the arrangement of the heat sink (13) and the like in the first case (11) is increased. There is an advantage that the conversion device (1) can be easily miniaturized.

A housing (70) of a power conversion device (1) according to a fourth aspect is, in any one of the first to third aspects, between the second case (12) and the first case (11), A sealant (40) is provided along the opening (120). The fixing part (30) is arranged between the sealing material (40) and the inner surface (125) of the wall (122) when viewed from the opening (120) side.

In the case (70) of the power conversion device (1) according to the fourth aspect, the sealing material (40) is arranged outside the fixing part (30), so the outside of the second case (12) There is an advantage that it is easier to block water entering from the outside than the fixed part (30), and waterproofness is improved.

A housing (70) of a power conversion device (1) according to a fifth aspect, in any one of the first to third aspects, between the second case (12) and the first case (11), A sealant (40) is provided along the opening (120). The sealing material (40) is arranged between the fixed part (30) and the inner surface (125) of the wall (122) when viewed from the opening (120) side.

In the case (70) of the power conversion device (1) according to the fifth aspect, the sealing material (40) is arranged so as to surround the fixed part (30), so that the sealing material (40) is There is an advantage that it becomes easier to block infiltrating water inside the fixed part (30), and waterproofness is improved.

A housing (70) of a power conversion device (1) according to a sixth aspect is, in any one of the first to fifth aspects, the second case (12) is fixed to the first case (11) with a screw. It is

The housing (70) of the power converter (1) according to the sixth aspect has the advantage that the second case (12) can be easily fixed to the first case (11).

In the case (70) of the power conversion device (1) according to the seventh aspect, in any one of the first to sixth aspects, a resin material is provided between the second case (12) and the reactor (142). (55) is injected.

In the case (70) of the power converter (1) according to the seventh aspect, the heat conduction in the second case (12) can be improved by the resin material (55), and the second case (12) There is an advantage that the heat dissipation is improved.

In any one of the first to seventh aspects, the housing (70) of the power conversion device (1) according to the eighth aspect has a fixing part (30) which is an opening (120) of the second case (12). to the bottom surface (128) surrounded by the walls (122) of the second case (12).

In the case (70) of the power conversion device (1) according to the eighth aspect, the fixed part (30) extends from the opening (120) of the second case (12) to the bottom (121) of the second case (12). There is an advantage that heat can be conducted and the heat dissipation of the second case (12) is improved.

A housing (70) of a power conversion device (1) according to a ninth aspect is, in any one of the first to eighth aspects, the second case (12) includes the reactor in the thickness direction of the wall (122). Fins are provided on the inner surface on the (142) side.

In the case (70) of the power conversion device (1) according to the ninth aspect, heat can be dissipated from the fins inside the second case (12), and the heat dissipation of the second case (12) is improved. There is an advantage.

A power conversion device (1) according to a tenth aspect includes a housing (70) of the power conversion device (1) according to any one of the first to ninth aspects, and a power converter housed in the housing (70) and a part (14).

In the power conversion device (1) according to the tenth aspect, the first case (11) and the second case (12) can be separately formed, and the first case (11) and the second case (12) There is an advantage that a relatively simple shape can be adopted as compared with the case of integrally forming the .

A housing (70) according to the eleventh aspect comprises a first case (60) that houses a first heating element (63) and a second case (61) that houses a second heating element (64). ). The first case (60) has, on its outer surface (67), a first portion (65) where a heat sink (13) for releasing heat generated by a first heating element (63) to the outside is arranged. The second case (61) has a second portion (66) on the outer surface (67) where the first case (60) is arranged at a position different from the first portion (65). The first case (60) has a second opening (120) at a position facing the first opening (21) in the second part (66) when fixed to the second part (66). . The first case (60) has a fixing part (30) inside the outer surface (124) of the wall (122) around the second opening (120). The first case (60) is fixed to the second part (66) via the fixing part (30) so as to cover the first opening (21).

In the case (70) according to the eleventh aspect, the second case (61) and the first case (60) can be formed separately, and the second case (61) and the first case (60) can be There is an advantage that a relatively simple shape can be adopted as compared with the case of integrally forming. Also, the fixing part (30) does not protrude to the outer surface (124) of the wall (122) of the first case (60). Therefore, the area occupied by the second case (61) on the outer surface (67) of the first case (60) can be reduced, and the degree of freedom in layout of the arrangement of the heat sink (13) and the like on the outer surface (67) is increased. It has the advantage of being easy to reduce in size.

An electrical device (1X) according to a twelfth aspect includes a housing (70).

In the electric device (1X) according to the twelfth aspect, the second case (61) and the first case (60) can be separately formed, and the second case (61) and the first case (60) are There is an advantage that a relatively simple shape can be adopted as compared with the case of integrally forming. In addition, since the fixing part (30) does not protrude to the outer surface (124) of the wall (122) of the first case (60), the area occupied by the second case (61) on the outer surface (67) of the first case (60) can be made smaller. Therefore, there is an advantage that the degree of freedom of the layout of the arrangement of the heat sink (13) and the like on the outer surface (67) is increased, and the size can be easily reduced.

Reference Signs List 1 power converter 1X electrical equipment 11 first case 12 second case 13 heat sink 14 power converter 30 fixing part 35 projecting part 40 sealing material 55 resin material 60 first case 61 second case 63 first heating element 64 second heat generation Body 65 First part 66 Second part 67 Outer surface 70 Housing 120 Opening (second opening)
121 bottom 122 wall 124 outer surface 127 edge 128 bottom 141 switching element 142 reactor

Claims (12)

A housing that has a plurality of switching elements and a reactor and houses a power conversion unit that converts power,
a heat sink thermally coupled to the plurality of switching elements for dissipating heat from the plurality of switching elements;
a second case having an opening formed by an edge and accommodating the reactor;
a first case housing the plurality of switching elements and to which the heat sink and the second case are attached;
with
The second case is
a wall extending from the edge and surrounding the reactor;
a fixing part for fixing the second case to the first case with the edge side of the second case facing the first case;
The fixing part is located in an area surrounded by the outer surface of the wall,
Enclosure of the power converter. The first case has a hole,
The second case is fixed to the first case so as to block the hole,
A housing for the power converter according to claim 1 . The edge has a protrusion that protrudes toward the inner surface of the wall,
The housing of the power conversion device according to claim 1 or 2, wherein the fixing portion is provided on the protruding portion. further comprising a sealing material arranged along the opening between the second case and the first case;
The fixing portion is arranged between the sealing material and the inner surface of the wall when viewed from the opening side.
A housing for the power converter according to any one of claims 1 to 3. further comprising a sealing material arranged along the opening between the second case and the first case;
The sealing material is arranged between the fixing portion and the inner surface of the wall when viewed from the opening side.
A housing for the power converter according to any one of claims 1 to 3. The second case is fixed to the first case by screws,
The housing of the power converter according to any one of claims 1 to 5. A resin material is filled between the second case and the reactor,
A housing for the power converter according to any one of claims 1 to 6. The fixing portion is continuous from the opening of the second case to a bottom surface of the second case surrounded by the wall,
A housing for a power converter according to any one of claims 1 to 7. The second case has fins on an inner surface on the reactor side in the thickness direction of the wall.
The housing of the power converter according to any one of claims 1 to 8. A housing of the power conversion device according to any one of claims 1 to 9,
and the power conversion unit housed in the housing,
Power converter. a first case that accommodates the first heating element therein;
a second case that accommodates the second heating element therein;
with
The first case has a first portion on the outer surface thereof, on which a heat sink for releasing heat generated by the first heating element is arranged, and the second case is arranged at a position different from the first portion. a second portion;
The second case has a second opening at a position facing the first opening in the second part in a state of being fixed to the second part, and the wall surrounding the second opening has a second opening. It has a fixing portion inside the outer surface, and is fixed to the second portion by the fixing portion so as to cover the first opening.
housing. A housing comprising the housing according to claim 11,
electrical equipment.

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