JP5515756B2 - Power converter - Google Patents

Description

  The present invention relates to a power conversion device such as an inverter mounted on a passenger car, a truck or the like, and more particularly to a power conversion device arranged outside a passenger compartment.

  A hybrid vehicle having both an internal combustion engine and an electric motor as a drive source, a vehicle having an electric motor as a drive source, and the like require a large-capacity inverter that performs bidirectional conversion between DC power and AC power. For this reason, various power converters including inverters have been developed. The power conversion device includes a power conversion circuit made up of transistors, semiconductor elements, etc., a cooler that cools electronic components such as transistors, semiconductor elements, etc., and prevents physical damage to the power conversion circuit and coolers and electromagnetic noise from external noise. And a case for shielding. Conventionally, power converters are often placed in a vehicle compartment that is not exposed to rainwater or the like, for example, under a seat or in a trunk room.

  However, depending on the design of the vehicle, it may be required to install the vehicle in a place other than the above, for example, outside the vehicle compartment such as a vehicle engine room or a lower part of a cargo truck. Many of the vehicle engine rooms have an open underfloor structure, and the lower part of the cargo platform is exposed to the outside, so there is a risk of splashing rainwater while driving and water exposure by high-pressure washing water during car washing. is there. For this reason, a case having a waterproof structure is required.

  As the waterproof structure, the case may be simply hermetically sealed. However, since the power conversion device houses the electronic components that generate heat in the case as described above, it cannot be completely sealed. The reason is that when the case is cooled while the temperature in the case is increased due to heat generation of the electronic component, moisture contained in the air in the case is condensed, and the moisture causes inconvenience such as a short circuit in the electronic component. Because. In order to prevent condensation, the case is provided with a vent hole that communicates the inside and outside of the case.

  When a power conversion device having a vent hole is mounted outside the vehicle compartment, a waterproof structure for the above-described rainwater splashing during traveling, high-pressure washing water at the time of car washing, and the like is required. As a waterproof structure related to such a vent hole, Patent Document 1 discloses that a cover body 102, which is a member different from the case 101, is disposed on the outer front surface of the vent hole 103 as shown in FIG. A structure is disclosed in which high-pressure washing water or the like at the time of car washing does not directly hit the vent hole 103.

JP 2002-118925 A

  However, in the case of the structure as described above, since the waterproof performance of the vent hole 103 is ensured by providing the cover body 102 as a separate member, an increase in the number of parts is a problem.

  This invention is made | formed in view of the said situation, and it aims at providing the power converter device which ensured the waterproofness of the ventilation hole, without causing the increase in a number of parts.

In order to solve the above problem, the invention according to claim 1 is a power conversion device in which an electronic component group constituting a part or the whole of a power conversion circuit is accommodated in a case. A ventilation hole that communicates the inside and outside of the case and a plurality of insertion holes that allow high-voltage cables to be inserted into and exited from the case. The ventilation hole and the insertion hole are formed on the same surface. A waterproof wall protruding from the side wall of the case is formed around the waterproof wall, and the waterproof wall has a drain opening that is open at a lower side in the gravitational direction , and the plurality of insertion holes include outer peripheries of the insertion holes. And a protruding wall that protrudes in the same direction as the waterproof wall from the side wall of the case, the protruding wall is formed of a continuous lump, formed so as to cover the outer periphery of the plurality of insertion holes, and a drain opening It is formed in the gravity direction lower side and a plurality of interpolation Of the hole, the top of the projecting wall formed in at least one of the insertion holes, and characterized in that when viewed from a horizontal direction relative to the case side wall intersecting the direction indicated gravity direction lower side overlaps the discharge apertures To do.

According to the said structure, since the protrusion wall of the penetration hole for high voltage | pressure cables is arrange | positioned under the waterproofing wall, a protrusion wall will block the moisture from the case lower side. Thereby, a part of function of the waterproofing wall formed as a waterproof structure of a vent plug, ie, the function which prevents the flooding from a lower side, will bear a function. Therefore, even if the lower side of the waterproof wall is opened in order to actively promote the dripping of the weight of water adhering to the gap between the vent hole and the waterproof wall, the waterproof property is improved without causing an increase in the number of parts of the case. be able to.
Moreover, according to the said structure, the protrusion wall is formed over the substantially whole of the left-right direction of a case side wall in the lower side of a case side wall. As a result, it is possible to block water from a wide range from the lower side of the case. Further, since the protruding wall is formed as one lump, the rigidity of the protruding wall can be increased.

  The invention according to claim 2 is characterized in that the protruding wall is formed to protrude from the waterproof side wall with respect to the case side wall.

  According to the above-described configuration, when receiving water from the lower side of the case, it is possible to block water from a wider angle than forming a waterproof wall with respect to the case side wall.

The perspective view which shows a power converter device Plan view showing power converter (A) is a front view which shows a power converter device, (B) is a front view which shows the area | region of a case side wall. The principal part expanded sectional view which follows the AA line in FIG. Front view showing another embodiment Cross section of the main part showing the conventional structure

[First Embodiment]
A power conversion device 1 according to an embodiment to which the present invention is applied will be described with reference to the drawings. FIG. 1 is a perspective view showing the overall configuration of the power conversion device 1, and FIG. 2 is a plan view of the power conversion device 1. In FIG. 2, the case lid 4 is omitted for convenience.

  As shown in FIGS. 1 and 2, the power conversion device 1 of the present embodiment is configured by housing an electronic component group 2 in a case 3 and assembling a case lid 4.

  The case 3 is a rectangular parallelepiped box having an internal space for accommodating the electronic component group 2 and opened upward. Moreover, the power converter device 1 is arrange | positioned so that case 3 bottom may become a road surface side at the time of vehicle mounting. Hereinafter, the direction of the bottom of the case 3 is referred to as “lower side”, and the direction facing the bottom of the case 3, that is, the direction in which the case lid 4 is provided is referred to as “upper side”. The direction from the upper side to the lower side and the opposite direction are referred to as the vertical direction. A direction orthogonal to the vertical direction is referred to as a horizontal direction.

  As shown in FIG. 2, as the electronic component group 2, a semiconductor laminated unit 20 including a semiconductor module 21 that forms part of a power conversion circuit and a cooler 22 that cools the semiconductor module 21 is housed in a case 3. Yes. Furthermore, a control circuit board (not shown) connected to the semiconductor module 21 as the electronic component group 2 to control the semiconductor module 21, a bus bar (not shown) connected to the semiconductor module 21 and allowing current to flow into and out of the semiconductor module 21, and A smoothing capacitor (not shown) or the like for suppressing voltage pulsation is accommodated in the case 3.

  The cooler 22 that cools the semiconductor module 21 includes a plurality of cooling pipes 221 that abut against and sandwich the main surface of the semiconductor module 21. The cooling pipe 221 is formed in a flat quadrangular shape and is laminated with a predetermined interval. In addition, connecting portions 222 that connect the cooling tubes 221 to each other are formed at both longitudinal ends of the plurality of stacked cooling tubes 221, and cooling water flows through the cooling tubes 221 and the connecting portions 222. Further, at the ends of the cooling pipe 221 in the stacking direction, at both ends in the longitudinal direction of the cooling pipe 221, a supply pipe 223 for supplying cooling water from the outside of the case 3 to the cooler 22, and cooling water from the cooler 22. A discharge pipe 224 for discharging the gas is connected to each other. The supply pipe 223 and the discharge pipe 224 are formed in a cylindrical shape, and are housed in the case 3 with their end portions protruding outward from the case 3. The supply pipe 223 and the discharge pipe 224 are provided with seal members 23 that are in contact with the case 3 and the case lid 4, respectively. The seal member 23 is made of rubber and prevents water from entering from the outside of the case 3.

  The semiconductor module 21 disposed between the stacked cooling pipes 221 is configured by molding using one or more types of semiconductor elements. Further, in order to bring the stacked semiconductor modules 21 and the cooling pipe 221 into close contact with each other, the cooling pipe 221 is connected to the supply pipe 223 and the discharge pipe 224 side between the end of the cooling pipe 221 in the stacking direction and the case 3. A leaf spring 225 is disposed so as to be biased.

  Further, in the case 3, a terminal block 5 in which wirings from the electronic component group 2 are gathered is provided in order to input and output power from the electronic component group 2 to the outside of the case 3.

  A vent hole 6 is formed in one side wall (hereinafter referred to as case side wall 31) of the case 3 that accommodates the electronic component group 2 and the terminal block 5 as shown in FIGS. As shown in FIG. 3B, when the case side wall 31 is divided into four regions of a first upper part 31a, a first lower part 31b, a second upper part 31c, and a second lower part 31d, the air holes 6 are formed in the case side wall 31. The first upper portion 31a is formed. The vent hole 6 is formed so as to communicate the inside of the case 3 with the outside.

  An input connector 32 is provided on the case side wall 31 in which the air holes 6 are formed. The input connector 32 is formed over more than half of the second upper portion 31 c of the four regions of the case side wall 31. The input connector 32 inputs signals from a vehicle ECU and sensors (not shown) to the electronic component group 2 inside the case 3.

  As shown in FIGS. 3 and 4, a vent plug 7 is disposed in the vent hole 6. The vent plug 7 is configured to include an insertion portion 71 that is slightly smaller in diameter than the vent hole 6 and a cover 72 that covers the outer end of the case 3 of the insertion portion 71.

  The insertion portion 71 is formed in a cylindrical shape having an internal space in order to secure an air inlet / outlet path inside and outside the case 3. The insertion portion 71 includes a claw portion 711 and a support portion 712 that are formed larger in diameter than the vent hole 6 at both ends across the case side wall 31. The claw portions 711 are located inside the case 3 and extend radially from the peripheral edge of the cylindrical insertion portion 71. The claw portion 711 is bent in the axial direction when the vent plug 7 is inserted into the vent hole 6. The support portion 712 is located outside the case 3 and extends radially outward from the entire periphery of the insertion portion 71.

  An annular groove (not shown) is formed over the entire circumference of the support portion 712 on the case 3 side of the support portion 712. A rubber O-ring seal 713 that is in close contact with the case side wall 31 is disposed in the groove. In addition, a circular ventilation filter 714 is disposed on the surface of the support portion 712 on the side opposite to the case 3 so as to cover the opening of the insertion portion 71 constituting the air inlet / outlet path. The ventilation filter 714 is configured by a member that allows air to pass but does not allow moisture to pass through, that is, has air permeability and waterproofness.

  Further, a cover 72 is formed on the support portion 712 so as to cover the end portion of the insertion portion 71 from the periphery of the support portion 712. The cover 72 includes an opposing wall 721 that is opposed to the ventilation filter 714 with a gap, and a cover side wall 722 that is continuous from the periphery of the opposing wall 721 and is coupled to the periphery of the support portion 712. The opposing wall 721 is not formed with an opening to prevent the ventilation filter 714 from being wetted. On the other hand, openings 723 are formed at equal intervals in the cover side wall 722 to ensure an air inflow path.

  When such a vent plug 7 is disposed in the vent hole 6, the insertion portion 71 is inserted into the vent hole 6 from the claw portion 711 side. As a result, the claw portion 711 and the inner wall surface 311 of the case side wall 31 come into contact with each other, the O ring seal 713 and the outer wall surface 312 of the case side wall 31 come into contact with each other, and the support portion 712 presses the O ring seal 713 toward the case side wall 31. To do. As a result, the vent plug 7 holds the case side wall 31 between the claw portion 711 and the support portion 712, and the vent plug 7 is fixed to the case 3. At the same time, since the O-ring seal 713 is pressed against the outer wall surface 312 of the case outer wall 31 by the support portion 712, water is prevented from entering the case 3 from the vent hole 6.

  A waterproof wall 61 is provided around the vent hole 6 and the vent plug 7. The waterproof wall 61 is formed so as to protrude perpendicular to the case side wall 31. With this waterproof wall 61, water attached to the case side wall 31 travels along the side wall to reach the O-ring seal 713 of the vent plug 7, or water flying toward the vent plug 7 directly enters the O-ring seal 713. It prevents you from hitting. The waterproof wall 61 is formed to protrude from the cover 72 of the vent plug 7 with respect to the case side wall 31. Further, a drainage opening 62 is formed in a portion of the waterproof wall 61 positioned vertically below the vent plug 7. That is, the waterproof wall 61 is not formed below the vent plug 7, and the waterproof wall 61 is formed in an arc shape when the vent hole 6 is viewed in the axial direction. The drainage opening 62 facilitates drainage of water adhering to the case side wall 31 between the vent plug 7 and the waterproof wall 61 and water adhering to the inner peripheral surface of the waterproof wall 61.

  As shown in FIGS. 3 and 4, a plurality of insertion holes 8 are formed in the case side wall 31 for inserting a plurality of high-voltage cables 9 in the same plane as the ventilation holes 6. In the present embodiment, five insertion holes 8 are formed. Three of the five insertion holes 8 are output insertion holes 8a1 to 8a3 for inserting motor cables for outputting three-phase AC power to a motor (not shown), and the remaining two are batteries (not shown). 2) through-holes 8b1 and 8b2 for inserting battery cables for inputting power into the case 3. The five insertion holes 8 are formed side by side so as to occupy more than half of the four regions of the case side wall 31 of the first lower portion 31b and the second lower portion 31d. The two input insertion holes 8b1 and 8b2 are arranged side by side in the left-right direction on the vertically lower side of the case side wall 31. The three output insertion holes 8a1 to 8a3 are arranged to line up with the input insertion holes 8b1 and 8b2 in the left-right direction. The three input insertion holes 8a1 to 8a3 are formed slightly above the input insertion holes 8b1 and 8b2 in the vertical direction. The output insertion hole 8a2 located at the center of the three output insertion holes 8a1 to 8a3 is formed above the other output insertion holes 8a1 and 8a3 located on both sides in the left-right direction in the vertical direction. ing. As described above, the three output insertion holes 8a1 to 8a3 are not arranged in a straight line, but are shifted in the vertical direction so that the upper output insertion hole 8a2 and the lower output insertion holes 8a1 and 8a3 are arranged. It is also possible to arrange them in the vertical direction, and the size of the case 3 can be reduced in the horizontal direction. Further, in the vicinity of the upper side of each of the output insertion holes 8a1 to 8a3 and the input insertion holes 8b1 and 8b2, output insertion holes 8a1 to 8a3 or input insertion holes 8b1 and 8b2 are shown to distinguish the five insertion holes 8. A marking 33 is provided.

  The high-voltage cable 9 has a function of inputting / extracting electric power into / from the case 3 and is fixed to the terminal block 5 disposed in the case 3 with bolts 10 as shown in FIG. The high-voltage cable 9 includes a wiring portion 92 in which a plurality of conducting wires are bundled, and a terminal portion 91 that is provided at the tip of the wiring portion 92 and is fixed to the terminal block 5.

  Most of the wiring part 92 is formed by covering the periphery of a plurality of conductive wires with an insulating film. The periphery of the front end side of the wiring portion 92 is covered with a resin cover 922. The periphery of the resin cover 922 in the wiring portion 92 is further surrounded by the rubber cover 921 at the boundary with the terminal portion 91. An annular groove 922a is formed in the resin cover 922, and an O-ring seal 923 is fitted in the annular groove 922a. The O-ring seal 923 is in close contact with the inner peripheral surface of the insertion hole 8 and prevents water from entering from the outside of the case 3 through the insertion hole 8.

  The terminal portion 91 includes a caulking portion 912 formed on the wiring portion 92 side and a round crimp terminal 911 formed on the distal end side of the caulking portion 912. The caulking portion 912 converges and fixes a plurality of conductive wires from the wiring portion 92. The crimp terminal 911 and the caulking portion 912 are formed of a conductive member. A crimp terminal 911 is fastened and fixed to the terminal block 5 with a bolt 10.

  The case side wall 31 is formed with a protruding wall 81 surrounding the plurality of insertion holes 8 (output insertion holes 8a1 to 8a3, input insertion holes 8b1 and 8b2). The protruding wall 81 is formed so as to protrude perpendicular to the case side wall 31, has an internal space having the same diameter as the insertion hole 8, and the insertion hole 8 is formed by extending the insertion hole 8 from the case side wall 31 by the protruding wall 81. .

  Further, the protruding wall 81 is formed at a predetermined height from the case side wall 31 so as to be able to flexibly cope with a change in the type of the high-voltage cable 9.

  Specifically, as described above, the high-voltage cable 9 is configured to include the crimp terminal 911, the caulking portion 912, the rubber cover 921, and the resin cover 922, and the crimp terminal 911 is fixed to the terminal block 5 with the bolt 10. . Further, the crimp terminal 911 and the O-ring seal 923 disposed on the resin cover 922 are arranged at a certain distance, and the installation location of the O-ring seal 923 is displaced in the axial direction depending on the type of the high-voltage cable 9.

  On the other hand, in order to ensure waterproofness between the high-voltage cable 9 and the insertion hole 8, the O-ring seal 923 needs to be brought into contact with the inner peripheral surface of the insertion hole 8 without fail. As one method for that purpose, there is a method of moving the case side wall 31 according to the installation location of the O-ring seal 923 that is displaced depending on the type. However, in this method, the case 3 becomes large, and an increase in the weight of the case 3 and an increase in manufacturing cost become a problem. Therefore, the resin cover 922 and the O-ring seal 923 are arranged outside the case side wall 31, and a protruding wall 81 having an inner space having the same diameter as the insertion hole 8 is formed around the insertion hole 8 to form the insertion hole 8. It is extended. The inner peripheral surface of the protruding wall 81 (insertion hole 8) and the O-ring seal 923 are in close contact with each other. As a result, the increase in weight is minimized without causing an increase in the size of the case 3, and waterproofness between the high-voltage cable 9 and the insertion hole 8 can be secured. Therefore, the protruding wall 81 is formed at a predetermined height so as to be able to cope with a change in the type of the high-voltage cable 9.

  Here, the characteristic structure of the present embodiment will be described.

  The protruding wall 81 formed in the plurality of insertion holes 8 is provided below the waterproof wall 61. Specifically, the protruding wall 81 of the output insertion hole 8 a 3 formed at the end of the case side wall 31 is formed so as to be positioned vertically below the drainage opening 62. In other words, the vent hole 6, the waterproof wall 61, and the drain opening 62 are formed vertically above the output insertion hole 8a3 at the end of the case side wall 31.

  The five insertion holes 8 are formed so as to occupy the lower side of the case side wall 31, that is, more than half of the first lower portion 31b and the second lower portion 31d. The two input insertion holes 8b1 and 8b2 are formed in the second lower portion 31d, and the three output insertion holes 8a1 to 8a3 are formed in the first lower portion 31b. An input connector 32 is disposed on the second upper portion 31c, which is above the input insertion holes 8b1 and 8b2. Of the three output insertion holes 8a1 to 8a3 formed above the input insertion holes 8b1 and 8b2 in the first lower portion 31b, the output insertion hole 8a1 on the input insertion hole 8b1 and 8b2 side is also the input connector. 32 is approaching. The central output insertion hole 8a2 is formed above the output insertion holes 8a1 and 8a3 on both sides in the left-right direction, and a marking 33 is formed above the central output insertion hole 8a2. . On the other hand, the marking 33 is only formed above the output insertion hole 8a3 at the end. Therefore, a relatively large space is formed in the case side wall 31 vertically above the output insertion hole 8a3 at the end, and the ventilation hole 6 and the waterproof wall 61 are formed there.

  Further, the protruding wall 81 protruding from the case side wall 31 is formed to protrude from the waterproof wall 61 with respect to the case side wall 31.

  Further, the protruding wall 81 is formed as one continuous lump, and this one lump surrounds the output insertion holes 8a1 to 8a3 and the input insertion holes 8b1 and 8b2. In other words, the individual projecting walls 81 that cover the output insertion holes 8a1 to 8a3 and the input insertion holes 8b1 and 8b2 are integrally formed. Therefore, the protruding wall 81 is formed over substantially the entire left and right direction of the case side wall 31, and a wall for suppressing water from below is formed over the wide area below the drainage opening 62. .

  Further, in the vertical direction of the case side wall 31, a part of the protruding wall 81 of the insertion hole 8 is formed to overlap the waterproof wall 61 of the vent hole 6. That is, the central output insertion hole 8a2 of the output insertion holes 8a1 to 8a3 is formed above the output insertion holes 8a1 and 8a3 on both sides, and thus is formed around the central output insertion hole 8a2. The upper portion of the projected wall 81 overlaps the lower portion of the waterproof wall 61.

    Next, the effect of this embodiment is demonstrated.

  According to the above configuration, since the protruding wall 81 formed for the insertion hole 8 for arranging the high-voltage cable 9 is arranged on the lower side including the vertical lower side of the vent hole 6, the protruding wall 81 passes from the lower side of the case 3. This will block water from being applied to the pores 6. Accordingly, a part of the function of the waterproof wall 61 formed in order to prevent the O-ring seal 713 of the vent plug 7 from being wetted, that is, the function of preventing water from the lower side is projected for the insertion hole 8. The wall 81 will bear. Therefore, even if the drainage opening 62 is formed on the lower side in the direction of gravity with respect to the waterproof wall 61 of the vent hole 6, water exposure from the drainage opening 62 can be suitably suppressed. Therefore, according to the present embodiment, as compared with the case where a wall is separately formed below the drainage opening 62 while preventing water accumulation and salt accumulation in the gap between the vent plug 7 and the waterproof wall 61. Thus, the waterproof property can be improved without increasing the number of parts of the case 3. In other words, according to the present embodiment, the drainage opening 62 is provided in the waterproof wall 61 of the vent hole 6 in order to positively promote the dripping of the dead weight of water adhering to the gap between the vent plug 7 or the vent plug 7 and the waterproof wall 61. It is also possible to prevent water from adhering to the ventilation filter 714 of the vent plug 7 and obstructing the air inflow path at low cost.

  Further, the protruding wall 81 is formed higher than the waterproof wall 61 in order to ensure the waterproof property between the high-voltage cable 9 and the insertion hole 8. Thereby, when receiving the water from the lower side of the case 3, it is possible to block water from a wider angle than forming the waterproof wall 61 with respect to the case side wall 31.

  Further, when the protruding wall 81 is not formed on the lower side of the waterproof wall 61, it is necessary to provide a separate waterproof wall on the lower side of the drainage opening 62. Since the protruding wall 81 higher than the waterproof wall 61 is formed on the lower side, it is not necessary to separately install a waterproof wall below the drain opening 62. As a result, since the waterproof wall is not separately formed, the weight of the case 3 can be reduced.

  Further, when a separate waterproof wall is formed below the drain opening 62, when a waterproof wall generally formed to be thinner is to be formed higher than the waterproof wall 61, In the die-cutting process of the case 3 at the time of manufacture, a problem that it is easily broken may occur. On the other hand, since the protruding wall 81 is formed to be relatively thick to support the high-voltage cable 9, unlike the case of separately forming a waterproof wall, there is no problem that the protruding wall 81 is broken in the die cutting process.

  Further, the protruding wall 81 is formed over substantially the entire left and right direction below the case side wall 31 and is formed as one lump. Therefore, it is possible to block water from a wide range from the lower side of the case 3. Further, since the protruding wall 81 is formed as one lump, the rigidity of the protruding wall 81 can be increased as compared with the case where individual protruding walls are formed around the plurality of insertion holes 8.

  In the case side wall 31, the vent hole 6 and the waterproof wall 61 are formed above the output insertion hole 8 a 3 at the end of the case side wall 31. As described above, the input connector 32 and the marking 33 are formed above the input insertion holes 8b1 and 8b2 and the output insertion holes 8a1 on the input insertion holes 8b1 and 8b2 side. The central output insertion hole 8a2 is formed above the output insertion holes 8a1 and 8a3 on both sides, and a marking 33 is formed on the upper side. On the other hand, since only the marking 33 is formed above the output insertion hole 8 a 3 at the end of the case side wall 31, a wider space can be secured as compared with other parts in the case side wall 31. Since the ventilation hole 6 and the waterproof wall 61 are formed in this space, the ventilation hole 6 can be formed large while suitably blocking water from the lower side.

  As described above, according to the present embodiment, it is possible to provide a power conversion device that ensures the waterproofness of the air vent without increasing the number of components.

[Other Embodiments]
In the first embodiment, the protruding wall 81 is formed to protrude from the waterproof wall 61, but the protruding wall 81 is not formed to protrude from the waterproof wall 61, and the protruding wall 81 is substantially the same height or protrudes from the waterproof wall 61. The wall 81 may be formed lower than the waterproof wall 61.

  In the first embodiment, the protruding walls 81 formed in the plurality of insertion holes 8 are formed as one lump. However, for example, as shown in FIG. 5, the protruding walls 81 are formed in the plurality of insertion holes 8. May be formed individually, or the adjacent protruding walls 81 may be integrally formed to form two or more lumps.

  In the first embodiment, a part of the protruding wall 81 is formed so as to overlap the waterproof wall 61 in the vertical direction, but the protruding wall 81 and the waterproof wall 61 are formed so as not to overlap in the vertical direction of the case side wall 31. May be. For example, the waterproof wall 61 may be positioned above the uppermost portion of the protruding wall 81 in the case side wall 31.

  In the first embodiment, the waterproof wall 61 and the protruding wall 81 protrude vertically from the case side wall 31, but may be protruded with an inclination with respect to the case side wall 31.

  In the first embodiment, the protruding wall 81 is formed on the lower side including the vertical lower side of the vent hole 6, the waterproof wall 61, and the drainage opening 62, but can be prevented from being wet from the lower side. Alternatively, the protruding wall 81 may be formed only at a predetermined angle below the vent hole 6, the waterproof wall 61, and the drainage opening 62.

DESCRIPTION OF SYMBOLS 1 Power converter device 2 Electronic component group 3 Case 31 Case side wall 4 Case lid 6 Vent hole 61 Waterproof wall 8 Insertion hole 81 Projection wall 9 High voltage cable

Claims (2)

In the power conversion device in which the electronic component group (2) constituting part or all of the power conversion circuit is accommodated in the case (3),
The case side wall (31) includes a ventilation hole (6) communicating with the inside and outside of the case (3), and a plurality of insertion holes (8) for inserting a high-voltage cable (9) for inputting and outputting power into the case (3). With
The vent hole (6) and the insertion hole (8) are formed on the same surface,
Around the insertion hole (6), a waterproof wall (61) protruding from the case side wall (31) is formed,
The waterproof wall (61) has a drainage opening (62) whose lower side in the direction of gravity is open ,
The plurality of insertion holes (8) are formed with protruding walls (81) that cover the outer periphery of the insertion holes (8) and protrude in the same direction as the waterproof wall (61) from the case side wall (31),
The protruding wall (81) is formed of a continuous lump, is formed so as to cover the outer periphery of the plurality of insertion holes (8), and is formed on the lower side in the gravity direction of the drainage opening (62). and,
Of the plurality of insertion holes, the upper part of the protruding wall (81) formed in at least one of the insertion holes (8) is horizontal with respect to the case side wall (31) intersecting the direction indicating the lower side in the gravitational direction. The power conversion device characterized by overlapping with the drain opening (62) when viewed from the direction . The power conversion device according to claim 1, wherein the protruding wall (81) is formed so as to protrude from the waterproofing wall (61) with respect to the case side wall (31).

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