JP2014171343A - Double-side cooling type power conversion device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To downsize a power conversion device, and to reduce a heat resistance of a bus bar.SOLUTION: A power conversion device comprises: a power semiconductor module; a flow channel forming body; and a power board for transmitting a DC current and an AC current. The power semiconductor module is configured by a power semiconductor element, a case, and a terminal. The flow channel forming body is formed with a flow channel space for housing the case, a recessed part formed on the side facing the flow channel space, and a first opening penetrating from the recessed part. With respect to the case, a part of the case is arranged within the recessed part. The terminal is protruded outside the flow channel space via the first opening, and in the case that diagonal projection is performed from a normal line direction of an upper surface of the flow channel forming body, the power board is arranged opposedly to the flow channel forming body so that a diagonal projection part of the power board is overlapped with the diagonal projection part of the recessed part. The power board is connected with the terminal.

Description

  The present invention relates to a power conversion device for converting a direct current into an alternating current, and more particularly to a power conversion device that supplies an alternating current to a drive motor of a hybrid vehicle or an electric vehicle.

  In recent years, power converters are demanded that can output a large current, while miniaturization is also required. If the power converter attempts to output a large current, the heat generated in the power semiconductor element built in the power semiconductor module will increase, and the heat resistance temperature of the power semiconductor element will not increase unless the heat capacity of the power semiconductor module or power converter is increased. This hinders the miniaturization of the power conversion device. Therefore, a double-sided cooling type power semiconductor module that improves the cooling efficiency by cooling the power semiconductor element from both sides and a double-sided cooling type power conversion device using the same have been developed. The double-sided cooling type power semiconductor module sandwiches both main surfaces of the power semiconductor element with plate-shaped conductors, and the surface of the plate-shaped conductor opposite to the surface facing the main surface of the power semiconductor element is thermally connected to the cooling medium, To be cooled.

  In Patent Document 1, a power module is configured by sandwiching both main surfaces of a power semiconductor element constituting an arm of an inverter circuit between plate-like insulating substrates, and an insertion hole for inserting the power module and a cooling water channel are integrally formed. Insert the power module into the case, pour resin into the gap between the insertion hole and the power module, cure it, assemble the power module into the case, and insulate the DC positive bus bar, DC negative bus bar and AC bus bar of the inverter circuit An invention of an inverter device that is brought into contact with a housing via a resin to achieve both high cooling performance and ease of assembly is disclosed.

  In Patent Document 2, a power module that constitutes an arm of an inverter circuit is formed such that a storage space for the power module is formed in a cooling water channel, and this cooling water channel is formed integrally with the housing. An invention of a heat generating component cooling structure is disclosed in which terminals are output to the outside of a casing and connected to a plate-shaped DC positive electrode bus bar, DC negative electrode bus bar, and AC bus bar structure.

JP 2005-237141 A JP 2010-087002 A

  However, in Patent Document 1, since the power module is assembled to the housing with the resin, even when the power module is not cured, the cooling / insulation of the power module is not achieved due to non-uniform separation of the adhesive interface, void, and filler dispersion when the resin is cured. Then, since all of the casing and the six power modules have to be discarded, there is a problem that the production yield decreases. Moreover, in patent document 2, since a housing | casing is shape | molded with resin and it has assembled | attached without contacting the structure of a bus bar with a housing | casing, there is no path | route which cools the heat_generation | fever of a bus bar, and the physique of a bus bar will enlarge. There are challenges.

  To achieve both a large current and a small power converter, it is necessary to cool not only the power semiconductor elements but also the peripheral components. Among them, the bus bar can be reduced in size by reducing the amount of the bus bar wiring material by improving the cooling water channel and cooling performance, but it is difficult to secure a wide cooling area with the downsizing of the power converter. Therefore, small size and high cooling performance are required.

  The subject of this invention is aiming at size reduction of a power converter device, and reduction of the thermal resistance of a bus-bar.

  In order to solve the above problems, a power conversion device according to the present invention includes a power semiconductor module that converts a direct current into an alternating current, a flow path forming body that forms a flow path for flowing a cooling refrigerant, and has an upper surface and a lower surface. A power board for transmitting the direct current and the alternating current, wherein the power semiconductor module includes a power semiconductor element, a case for housing the power semiconductor element, and a terminal for transmitting the direct current or the alternating current. The flow path forming body accommodates the case and flows the cooling refrigerant, and faces the lower surface of the flow path forming body and faces the flow path space. A recess formed and a first opening penetrating from the bottom surface of the recess to the top surface of the flow path forming body are formed, and the case has a part of the case disposed in the recess. When the terminal protrudes out of the flow path space through the first opening and is shaded from the normal direction of the upper surface of the flow path forming body, the power board is shaded by the power board. Is arranged to face the upper surface of the flow path forming body so as to overlap the shaded portion of the recess, and the power board is connected to the terminal.

  By this invention, size reduction of a power converter device and reduction of the thermal resistance of a bus bar can be aimed at.

It is a figure which shows the control block of a hybrid vehicle. It is a circuit diagram of an inverter apparatus. It is an external appearance perspective view of the power converter device 299. FIG. It is a disassembled perspective view which shows the process of assembling the power converter device 299. FIG. 5 is an exploded perspective view showing a process of assembling the power semiconductor module 300 and the capacitor cell 500 to the flow path forming body 400. FIG. It is sectional drawing when the cross section A of FIG.3 (b) is seen from the direction of the arrow. 2 is an external perspective view of a power semiconductor module 300. FIG. FIG. 5 is an exploded perspective view showing a process of assembling a sealing body 302 and the like to a case 304. 3 is an exploded perspective view of circuit components constituting a series circuit of upper and lower arms of a power semiconductor module 300. FIG. FIG. 6 is a circuit configuration diagram corresponding to FIG. 1 is an external perspective view of a power board 700. FIG. 2 is a top perspective view of a power board 700. FIG. 3 is a cross-sectional view of a power board 700 at a cross section B. FIG. It is sectional drawing in the cross section C of the power board 700. FIG. It is sectional drawing in the cross section D of the power board 700. FIG. 3 is an external perspective view of a flow path forming body 400. FIG. It is an external appearance perspective view of the flow-path formation body 400 seen from the viewpoint different from Fig.6 (a). It is an external appearance top view of channel formation object 400 seen from viewpoint A of Drawing 6 (a). It is an external appearance bottom view of the flow-path formation body 400 seen from the viewpoint B of FIG.6 (b). FIG. 7 is an external top view of the flow path forming body 400 in which an opening 403, a recess 406, and an opening 705 are overlapped when viewed from the viewpoint A in FIG. 5 is an exploded perspective view showing a process of assembling the power board 700 to the flow path forming body 400. FIG. FIG. 3 is an external perspective view of a flow path forming body 400 and a power board 700 assembled. It is a sectional exploded view showing a process of assembling the power semiconductor module 300 and the power board 700 to the flow path forming body 400 as seen from the direction of the arrow of the section E. FIG. 5 is an enlarged cross-sectional exploded view showing a process of assembling the power semiconductor module 300 and the power board 700 to the flow path forming body 400 as viewed from the direction of the arrow of the cross section E. It is sectional drawing explaining the cooling effect of the power board 700 seen from the direction of the arrow of the cross section E. FIG. It is an upper view which shows the arrangement structure of Example 1 of a power semiconductor module and a capacitor cell. It is an upper view which shows the other structural example of a power semiconductor module and a capacitor cell. It is an upper view which shows the other structural example of a power semiconductor module and a capacitor cell. It is an upper view which shows the other structural example of a power semiconductor module and a capacitor cell. It is an upper view which shows the structural example in the power converter device which incorporates 2 inverter circuits. It is an upper view which shows the structural example in the power converter device which incorporates 2 inverter circuits. It is an upper view which shows the structural example in the power converter device which incorporates a DC / DC converter circuit and an inverter circuit. It is sectional drawing which shows the other structural example regarding this embodiment.

  The power converter according to the present embodiment will be described in detail below with reference to the drawings. The power conversion device according to the present embodiment can be applied to a hybrid vehicle or a pure electric vehicle. As a representative example, FIG. 1 and FIG. 2 show a control configuration and a circuit configuration when applied to a hybrid vehicle. It explains using.

  The power conversion device according to the present embodiment will be described by taking, as an example, an inverter device for driving a vehicle that is used in an electric vehicle driving system and that has a very severe mounting environment and operational environment.

  The inverter device for driving the vehicle converts the DC power supplied from the in-vehicle battery or the in-vehicle power generator constituting the in-vehicle power source into predetermined AC power, and supplies the obtained AC power to the vehicle driving motor to drive the vehicle. Control the drive of the motor. In addition, since the vehicle drive motor also has a function as a generator, the vehicle drive inverter device also has a function of converting AC power generated by the vehicle drive motor into DC power according to the operation mode. Yes.

  The configuration of the present embodiment is optimal as a power conversion device for driving a vehicle such as an automobile or a truck. However, other power conversion devices such as a power conversion device such as a train, a ship, and an aircraft, and a factory facility are also included. Applicable to industrial power converters used as drive motor control devices, or household power conversion devices used in home solar power generation systems and motor control devices that drive household appliances It is.

  FIG. 1 is a diagram showing a control block of a hybrid vehicle. In FIG. 1, a hybrid electric vehicle 110 is one electric vehicle, and includes two vehicle drive systems. One of them is an engine system that uses an engine 120 that is an internal combustion engine as a power source. The engine system is mainly used as a drive source of a hybrid vehicle (hereinafter referred to as “HEV”). The other is an in-vehicle electric system using motor generators 192 and 194 as a power source. The in-vehicle electric system is mainly used as an HEV drive source and an HEV power generation source. The motor generators 192 and 194 are, for example, synchronous machines or induction machines, and operate as both a motor and a generator depending on the operation method.

  A front wheel axle 114 is rotatably supported at the front portion of the vehicle body, and a pair of front wheels 112 are provided at both ends of the front wheel axle 114. A rear wheel axle is rotatably supported at the rear portion of the vehicle body, and a pair of rear wheels are provided at both ends of the rear wheel axle (not shown). In the HEV of the present embodiment, a so-called front wheel drive system is employed, but the reverse, that is, a rear wheel drive system may be employed.

  A front wheel side differential gear (hereinafter referred to as “front wheel side DEF”) 116 is provided at the center of the front wheel axle 114. The output shaft of the transmission 118 is mechanically connected to the input side of the front wheel side DEF 116. The output side of the motor generator 192 is mechanically connected to the input side of the transmission 118. The output side of the engine 120 and the output side of the motor generator 194 are mechanically connected to the input side of the motor generator 192 via the power distribution mechanism 122. Motor generators 192 and 194 and power distribution mechanism 122 are housed inside the casing of transmission 118.

  A battery 136 is electrically connected to the inverter devices 140 and 142, and power can be exchanged between the battery 136 and the inverter devices 140 and 142. A capacitor 500 for smoothing a direct current is installed between the battery 136 and the inverter devices 140 and 142.

  In the present embodiment, the first motor generator unit composed of the motor generator 192 and the inverter device 140 and the second motor generator unit composed of the motor generator 194 and the inverter device 142 are provided. ing. That is, in the case where the vehicle is driven by the power from the engine 120, when assisting the driving torque of the vehicle, the second motor generator unit is operated as the power generation unit by the power of the engine 120 to generate power. The first electric power generation unit is operated as an electric unit by the obtained electric power. Further, in the same case, when assisting the vehicle speed of the vehicle, the first motor generator unit is operated by the power of the engine 120 as a power generation unit to generate power, and the second motor generator unit is generated by the electric power obtained by the power generation. Operate as an electric unit.

  In the present embodiment, the vehicle can be driven only by the power of the motor generator 192 by operating the first motor generator unit as an electric unit by the electric power of the battery 136. Furthermore, in the present embodiment, the battery 136 can be charged by generating power by operating the first motor generator unit or the second motor generator unit as the power generation unit by the power of the engine 120 or the power from the wheels.

  The battery 136 is also used as a power source for driving an auxiliary motor 195. As an auxiliary machine, for example, a motor that drives a compressor of an air conditioner or a motor that drives a hydraulic pump for control, DC power is supplied from the battery 136 to the inverter device 43 and converted into AC power by the inverter device 43. And supplied to the motor 195. The inverter device 43 has the same function as the inverter devices 140 and 142 and controls the phase, frequency, and power of alternating current supplied to the motor 195. For example, the motor 195 generates torque by supplying AC power having a leading phase with respect to the rotation of the rotor of the motor 195. On the other hand, by generating the delayed phase AC power, the motor 195 acts as a generator, and the motor 195 is operated in a regenerative braking state. Such a control function of the inverter device 43 is the same as the control function of the inverter devices 140 and 142. Since the capacity of the motor 195 is smaller than the capacity of the motor generators 192 and 194, the maximum conversion power of the inverter device 43 is smaller than that of the inverter devices 140 and 142, but the circuit configuration of the inverter device 43 is basically the circuit of the inverter devices 140 and 142. Same as the configuration.

  The electric circuit configuration of the inverter device 140, the inverter device 142, or the inverter device 43 will be described with reference to FIG. In FIG. 2, the inverter device 140 will be described as a representative example.

  The inverter circuit 144 corresponds to each phase winding of the armature winding of the motor generator 192 by using an upper and lower arm series circuit 150 including an IGBT 328 and a diode 156 that operate as an upper arm, and an IGBT 330 and a diode 166 that operate as a lower arm. Thus, three phases (U phase, V phase, W phase) are provided. Here, IGBT is an abbreviation for insulated gate bipolar transistor. Each of the upper and lower arm series circuits 150 is connected to an AC power line (AC bus bar) 186 from the middle point (intermediate electrode 169) to the motor generator 192 through the AC terminal 159 and the AC connector 188.

  The collector electrode 153 of the upper arm IGBT 328 is connected to the capacitor electrode on the positive electrode side of the capacitor 500 via the positive electrode terminal 157, and the emitter electrode of the lower arm IGBT 330 is connected to the capacitor electrode on the negative electrode side of the capacitor 500 via the negative electrode terminal 158. Electrically connected.

  The control unit 170 includes a driver circuit 174 that drives and controls the inverter circuit 144, and a control circuit 172 that supplies a control signal to the driver circuit 174 via the signal line 176. The IGBT 328 and the IGBT 330 operate in response to the drive signal output from the control unit 170, and convert DC power supplied from the battery 136 into three-phase AC power. The converted electric power is supplied to the armature winding of the motor generator 192.

  The IGBT 328 includes a collector electrode 153, a gate electrode 154, and a signal emitter electrode 155. The IGBT 330 includes a collector electrode 163, a signal emitter electrode 165, and a gate electrode 164. A diode 156 is electrically connected in parallel with the IGBT 328. A diode 166 is electrically connected to the IGBT 330 in parallel. A MOSFET (metal oxide semiconductor field effect transistor) may be used as the switching power semiconductor element, but in this case, the diode 156 and the diode 166 are not necessary.

  The capacitor 500 has a positive side capacitor terminal 506 and a negative side capacitor terminal 504. Capacitor 500 is electrically connected to battery 136 via DC connector 138. Note that the inverter device 140 is connected to the positive capacitor terminal 506 via the DC positive terminal 314 and connected to the negative capacitor terminal 504 via the DC negative terminal 316.

  The control circuit 172 includes a microcomputer (hereinafter referred to as “microcomputer”) for calculating the switching timing of the IGBTs 328 and 330. The microcomputer receives as input information a target torque value required for the motor generator 192, a current value supplied to the armature winding of the motor generator 192 from the upper and lower arm series circuit 150, and a magnetic pole of the rotor of the motor generator 192. The position has been entered. The target torque value is based on a command signal output from a host controller (not shown). The current value is detected based on the detection signal output from the current sensor 180 via the signal line 182. The magnetic pole position is detected based on a detection signal output from a rotating magnetic pole sensor (not shown) provided in the motor generator 192. In the present embodiment, the case where the current values of three phases are detected will be described as an example, but the current values for two phases may be detected.

  Note that the gate electrode 154 and the signal emitter electrode 155 in FIG. 2 correspond to a signal connection terminal 327U in FIG. 5 described later, and the gate electrode 164 and the emitter electrode 165 correspond to a signal connection terminal 327L in FIG. Further, the positive terminal 157 is the same as the positive terminal 315D in FIG. 5, and the negative terminal 158 is the same as the DC negative terminal 319D in FIG. The AC terminal 159 is the same as the AC terminal 320D in FIG.

  An embodiment of the power conversion device 299 according to the present embodiment will be described with reference to FIGS. 3 to 4.

  FIG. 3A is a perspective view showing the external appearance of the power converter 299. The power conversion device 299 includes a DC connector 138 for electrical connection with the battery 136, an AC connector 188 for electrical connection with the motor generator 192, and a flow path forming body 400.

  FIG. 3B is an exploded perspective view showing a process of assembling the power converter 299. The power conversion device 299 includes a flow path forming body 400 that is a housing integrally formed with a cooling flow path, a flow path lid 401 that hermetically seals the flow path forming body 400, and each portion of the bus bar covered with an insulating resin. A power board 700 integrated in a shape, a control board 200 including a control circuit 172 and a driver circuit 174, a control board base 800 on which the control board 200 is mounted, and a casing lid 900 that hermetically seals the whole. As shown in FIG. 3B, the power device 299 has a hierarchical structure in which these are stacked and assembled.

  The channel lid 401 is formed with a refrigerant input / output port 402 connected to a pipe for flowing the refrigerant into the power converter 299. The flow channel lid 401 is disposed on the lower surface of the flow channel forming body 400 as will be described later.

  The control board base 800 is disposed to face the flow path forming body 400 with the power board 700 interposed therebetween. The control board 200 is mounted above the control board base 800.

  FIG. 4A is an exploded perspective view showing a process of assembling a power semiconductor module 300 and a capacitor cell 500, which will be described later, into the flow path forming body 400. FIG.

  The flow path forming body 400 is provided with spaces for accommodating the power semiconductor module 300 and the capacitor cell 500, respectively. The power semiconductor module 300 is stored in a storage space formed in the flow path forming body 400 through an opening formed on the bottom surface side of the flow path forming body 400. The capacitor cell 500 is accommodated in the capacitor cell accommodation space 490 formed in the flow path forming body 400 through the opening formed on the upper surface side of the flow path forming body 400.

  A capacitor cell terminal 502 is connected to the capacitor cell 500. The capacitor cell terminal 502 protrudes in the direction in which the power board 700 is arranged when the capacitor cell 500 is accommodated in the flow path forming body 400.

  FIG. 4B is a cross-sectional view when the cross section A of FIG. 3B is viewed from the direction of the arrow. The capacitor cell 500 is sealed with the capacitor sealing resin 501 in the capacitor cell storage space 490 of the flow path forming body 400. The capacitor cell terminal 502 is formed to protrude from the capacitor sealing resin 501.

In a state where the flow path cover 401 is assembled to the flow path forming body 400, the refrigerant flows as indicated by the refrigerant flow 499. The refrigerant introduced from one of the refrigerant input / output ports 402 directly contacts the power semiconductor module 300 and cools the power semiconductor module 300. Further, since the refrigerant flow path is also formed in the lower part and the side part of the capacitor cell storage space 490, the capacitor cell 500 is also cooled at the same time.
(Power semiconductor module 300)
FIG. 5A is an external perspective view of the power semiconductor module 300. The power semiconductor module 300 includes a case 304 that houses a power semiconductor element, and an insulating mold terminal 600.

  The case 304 has a frame body 304D that forms side walls and a bottom surface, a fin 305 that is formed on the widest longitudinal surface orthogonal to the side walls and the bottom surface and cools the power semiconductor element, and is positioned when assembled with the flow path forming body. The positioning unit 311 is configured to include an O-ring groove 312 to which an O-ring is attached. The fins 305 are also formed in the same shape on opposite surfaces that face each other.

  The insulating mold terminal 600 includes a positive terminal 315D, a negative terminal 319D, an AC terminal 320, a signal connection terminal 327L, a signal connection terminal 327U, and an auxiliary mold body 601. The auxiliary mold body 601 is formed with a plurality of through holes for penetrating the positive terminal 315D, the AC terminal 320, the signal connection terminal 327L, and the signal connection terminal 327U. The auxiliary mold body 601 electrically insulates the positive terminal 315D, the negative terminal 319D, the AC terminal 320, the signal connection terminal 327L, and the signal connection terminal 327U from each other. Also, a separate insulating plate material can be assembled between the terminals to increase the insulation distance.

  FIG. 5B is an exploded perspective view showing a process of assembling the sealing body 302 to the case 304. As shown in FIG. 5B, the case 304 has a fully closed structure except for the insertion port 306 that outputs the terminal of the power semiconductor element. The power semiconductor element housed in the case 304 is protected from the refrigerant by the sealing body 302. Each terminal of the power semiconductor element is connected to the outside of the case 304 through an insulating mold terminal 600. Further, the positioning portion 311 and the O-ring groove 312 formed in the case 304 are formed so as to surround the outer periphery of the insertion port 306.

  A sealing body 302 that encapsulates the power semiconductor element is inserted by laminating an insulating material 333 from the insertion port 306 of the frame body 304D. Inside the sealing body 302, circuit components constituting the upper and lower arm series circuit 150 of the inverter circuit are sealed.

  FIG. 5C is an exploded perspective view of the circuit components constituting the upper and lower arm series circuit 150 of the power semiconductor module 300. As shown in FIG. 5C, the IGBT 328 and the diode 156 constituting the upper arm circuit are metal-bonded so as to be sandwiched between the conductor plate 315 and the conductor plate 318. Similarly, the IGBT 330 and the diode 166 constituting the lower arm circuit are metal-bonded so as to be sandwiched between the conductor plate 319 and the conductor plate 320 in parallel. The intermediate electrode 329A formed on the conductor plate 318 is metal-bonded with the intermediate electrode 329B formed on the conductor plate 320.

  The conductor plate 318 and the conductor plate 319 are arranged on the same plane. The conductor plate 318 and the conductor plate 319 form an exposed surface 321A (see FIG. 5B) on the surface opposite to the surface where the IGBTs 328 and 330 and the diodes 156 and 166 are joined, and are exposed from the sealing body 302. Yes.

  Similarly, the conductor plate 315 and the conductor plate 320 are disposed on the same plane. The conductor plate 315 and the conductor plate 320 form an exposed surface 321B (see FIG. 5B) on the surface opposite to the surface where the IGBTs 328 and 330 and the diodes 156 and 166 are joined, and are exposed from the sealing body 302. Yes. As shown in FIG. 5B, the exposed surfaces 321A and 321B are formed at positions overlapping the surface of the case 304 on which the fins 305 are formed.

  FIG. 5D is a circuit configuration diagram corresponding to FIG. The insulating mold terminals 600 have terminals corresponding to the sealing bodies 302, respectively, and are electrically connected to each other.

  The case 304 of the power semiconductor module 300 described above is a member having electrical conductivity, for example, a composite material such as Cu, Cu alloy, Cu—C, or Cu—CuO, or a composite material such as Al, Al alloy, AlSiC, or Al—C. It is formed from materials. The case 304 is formed by a highly waterproof joining method such as welding, or by forging or casting.

  As the sealing resin constituting the sealing body 302, for example, a resin based on a novolac-based, polyfunctional, or biphenyl-based epoxy resin can be used, and ceramics and gels such as SiO2, Al2O3, AlN, and BN , Rubber or the like is included, and the thermal expansion coefficient is brought close to the conductor portions 315, 320, 318, 319. Thereby, the difference in thermal expansion coefficient between the members can be reduced, and the thermal stress generated as the temperature rises in the use environment is greatly reduced, so that the life of the power semiconductor module can be extended. Further, a high heat-resistant thermoplastic resin such as PPS (polyphenyl sulfide) or PBT (polybutylene terephthalate) is suitable for the molding material of the auxiliary mold body 600.

As the metal bonding agent, for example, an Sn alloy-based soft brazing material (solder), a hard brazing material such as an Al alloy / Cu alloy, or a metal sintered material using metal nanoparticles / micro particles can be used.
(Power board 700)
FIG. 6A is an external perspective view of the power board 700. The power board 700 includes a positive electrode side bus bar 703, a negative electrode side bus bar 704, an AC bus bar 709, and an insulating coating member 708 that covers these and electrically insulates each other. In the figure, in order to describe the internal arrangement of each bus bar, the positive electrode side bus bar 703 and the AC bus bar 709 are shown by dotted lines.

  The power board 700 is provided with openings 705A and 705B penetrating from the front surface to the back surface. The positive electrode side bus bar 703, the negative electrode side bus bar 704, and the AC bus bar 709 are each provided with a terminal 701 and projecting from the edge of the opening 705A. As will be described later with reference to FIGS. 8 and 11, the terminal portion of the insulating mold terminal 600 of the power semiconductor module 300 penetrates the opening 705 </ b> A and is electrically connected to the terminal 701.

  Further, the power board 700 is provided with an opening 705C penetrating from the front surface to the back surface. The positive electrode side bus bar 703 and the negative electrode side bus bar 704 are each provided with a terminal 702, which protrudes from the edge of the opening 705 </ b> C and the edge of the power board 700. As will be described later with reference to FIG. 8, the capacitor cell terminal 502 of the capacitor cell 500 passes through the opening 705 </ b> C and is electrically connected to the terminal 702.

  FIG. 6B is a top view of the power board 700. The positive-side bus bar 703 and the negative-side bus bar 704 of the power board 700 are stacked so as to face each other with an insulating coating member 708 interposed therebetween. Thereby, the wiring inductance of the inverter main circuit can be reduced.

  FIG. 6C is a cross-sectional view of the power board 700 taken along a cross section B in FIG. FIG. 6D is a cross-sectional view of the power board 700 taken along a cross section C in FIG. FIG. 6E is a cross-sectional view of the power board 700 taken along a cross section D in FIG.

  As shown in FIG. 6 (d), the positive electrode side bus bar 703 and the negative electrode side bus bar 704 are arranged in parallel and facing each other. As shown in FIG. 6 (e), the AC bus bar 709 is arranged so that the main surface of the AC bus bar 709 does not overlap the main surface of the positive electrode side bus bar 703 and the main surface of the negative electrode side bus bar 704. The AC bus bar 709 is formed of a conductor that is thicker than the positive electrode side bus bar 703 and the negative electrode side bus bar 704. By forming the AC bus bar 709 thicker than the positive electrode bus bar 703 and the negative electrode bus bar 704, heat generation of the AC bus bar 709 through which a large current flows in order to drive the motor generator can be suppressed.

  Further, as shown in FIGS. 6C and 6E, the AC bus bar 709 is formed so as to be close to the side opposite to the side from which the terminal 701 protrudes, that is, the surface on the flow path forming body 400 side. To do. The thickness of the insulating coating member 708 on the flow path forming body 400 side with respect to the AC bus bar 709 is substantially the same as the thickness of the insulating coating member 708 on the flow path forming body 400 side with respect to the negative electrode side bus bar 704. Thus, by arranging the thickness of the insulating coating member 708 on the same surface side, the thermal resistance to the flow path forming body 400 through which the refrigerant flows can be reduced, and the productivity can be improved.

For the insulating coating member 708, for example, a resin based on a novolac-based, polyfunctional, or biphenyl-based epoxy resin can be used. Further, a material containing ceramics such as SiO ₂ , Al ₂ O ₃ , AlN, or BN, gel, rubber, etc. and having a thermal expansion coefficient close to that of the conductor portions 315, 320, 318, 319 can be used. In addition, a highly heat-resistant thermoplastic resin such as PPS (polyphenyl sulfide) or PBT (polybutylene terephthalate) may be used. Further, a printed board material such as glass epoxy impregnated with glass cloth may be used. The insulating covering member and the bus bar may be bonded with an adhesive. Also,
For the bus bar, for example, a material having high thermal conductivity and low electrical resistance, such as Cu alloy or Al alloy, is suitable, and the surface is subjected to oxidation treatment or roughening treatment in order to improve the adhesive strength with the insulating coating member. May be.
(Flow path forming body 400)
FIG. 7A is an external perspective view of the flow path forming body 400. FIG. 7B is an external perspective view of the flow path forming body 400 seen from a different viewpoint from FIG. As described above, the channel forming body 400 is formed with the module storage space 405 for storing the power semiconductor module 300 and the capacitor storage space 490 for storing the capacitor cell 500. The power semiconductor module 300 is stored in the module storage space 405 through an opening formed on the bottom surface of the flow path forming body 400. The capacitor cell 500 is stored in the capacitor storage space 490 from the opening formed on the upper surface of the flow path forming body 400.

  A flat surface 404 on which the power board 700 is mounted is formed on the upper surface of the flow path forming body 400, that is, the surface facing the power board 700.

  An opening 403 is formed in the flat surface 404 of the flow path forming body 400. The opening 403 is an opening that communicates from the flat surface 404 to the module storage space 405. The power semiconductor module 300 housed in the module housing space 405 is arranged such that the insulating mold terminal 600 of the power semiconductor module 300 is inserted through the opening 403.

  Further, the flow path forming body 400 is formed with a recess 406 surrounding the opening 403. The recess 406 is formed on the surface where the opening 403 is formed among the surfaces forming the module storage space 405. That is, the opening 403 is formed on the bottom surface of the recess 406. The positioning part 311 provided in the case 304 of the power semiconductor module 300 is assembled in the recess 406.

  FIG.7 (c) is a top view of the flow-path formation body 400 seen from the viewpoint A of Fig.7 (a). FIG.7 (d) is a bottom view of the flow-path formation body 400 seen from the viewpoint B of FIG.7 (b). FIG. 7E shows a flow path forming body 400 in which the opening 403, the projected portion of the recess 406, and the projected portion of the power board 700 and the opening 705 are overlapped as viewed from the viewpoint A in FIG. 7A. FIG.

  In this embodiment, three power semiconductor modules 300 are used corresponding to the three phases of the U phase, the V phase, and the W phase. The three power semiconductor modules 300 are arranged in parallel so that the main surfaces of the power semiconductor modules 300 face each other. The capacitor storage space 490 for storing the capacitor cell 500 is formed at a position facing the side walls of the three power semiconductor modules 300.

As illustrated in FIG. 7E, when projected in the normal direction of the flat surface 404 of the flow path forming body 400, the power board 700 has a projection portion of the power board 700 and a projection portion of the recess 406. Arranged to overlap. In addition, the openings 705A and 705B formed in the power board 700 are formed so that the projected portions of the openings 705A and 705B overlap the projected portion of the opening 403.
(Assembly process of flow path forming body 400 and power board 700)
FIG. 8A is an exploded perspective view showing a process of assembling the power board 700 to the flow path forming body 400. FIG. 8B is an external perspective view in which the flow path forming body 400 and the power board 700 are assembled.

  The power board 700 is mounted on the flat surface 404 of the flow path forming body 400. Although the power board 700 and the flow path forming body 400 are arranged in contact with each other, the surface of the power board 700 is covered with the insulating coating member 708 and thus is electrically insulated.

  FIG. 8C is a cross-sectional view showing a process of assembling the power semiconductor module 300 and the power board 700 to the flow path forming body 400, as viewed from the direction of the arrow of the cross section E in FIG. d) is an enlarged cross-sectional view showing a state in which the power semiconductor module 300 is assembled to the flow path forming body 400 from the state shown in FIG.

  As described above, the power semiconductor module 300 is housed in the module housing space 405 from the bottom surface side of the flow path forming body 400. The positioning part 311 formed in the case 304 of the power semiconductor module 300 is assembled in the concave part 406 of the flow path forming body 400. At this time, an O-ring (not shown) is attached to the O-ring groove 312 in order to ensure airtightness.

  The insulating mold terminal 600 of the power semiconductor module 300 is disposed through the opening 403 of the flow path forming body 400. The auxiliary mold body 601 of the insulating mold terminal 600 is disposed so that one surface of the auxiliary mold body 601 is flush with the flat surface 404 of the flow path forming body 400.

  The terminal portion protruding from the flat surface 404 of the flow path forming body 400 passes through the opening 705A of the power board 700 and is electrically connected to the terminal 701 of the power board, and the terminal connection portion 711 shown in FIG. Form.

  FIG. 8E is a cross-sectional view of the flow path forming body 400 and the power board 700 as seen from the direction of the arrow in the cross section F of FIG. The cooling effect of the power board 700 will be described with reference to FIG.

  The bus bars and terminals of the power board 700 cause a large loss due to the bus bar wiring resistance to generate heat because a large current of several hundreds A flows when the motor generator is driven. With this embodiment structure, this heat is transferred to the flow path forming body 400 as shown by the arrow in FIG. Thereby, even if the thickness of the wiring material which comprises each bus bar and a terminal is made thin, the temperature of a bus bar can be lowered | hung and the whole power converter device 299 can be reduced in size and reduced in weight.

  In addition, the positive electrode side bus bar 703 and the negative electrode side bus bar 704 constituting the power board 700 are arranged to be opposed to each other via the insulating coating member 708. Then, when the layered portion is projected from the normal direction of the flat surface 404 of the flow path forming body 400, the stacked portion is disposed so as to overlap with the projected portion of the concave portion 406 of the flow path forming body 400. With such a configuration, the wiring inductance of the inverter main circuit flowing through the power board can be reduced, and the heat generated in the power board can be transmitted to the flow path forming body 400.

  Furthermore, the auxiliary mold body 601 is arranged so that one surface of the auxiliary mold body 601 is flush with the flat surface 404 of the flow path forming body 400, so that the power board 700 cannot contact the flow path forming body 400 by the auxiliary mold body 601. Thus, the power board 700 can come into contact with the auxiliary mold body 601 and the flow path forming body 400. Therefore, the heat of the bus bar can be radiated without inhibiting the heat transfer as indicated by the arrow shown in FIG. Since the power board 700 forms a wider contact area, the heat dissipation area of the bus bar is increased and the heat dissipation performance is improved.

  A refrigerant blocking member 407 is disposed on the side of the fin 305. It is the area where the fins 305 are formed that needs to be actively cooled, and the refrigerant flowing in the other area can be blocked by the refrigerant blocking member 407 being arranged. Thereby, the flow rate of the refrigerant | coolant in the area | region in which the fin 305 was formed can be raised, and the cooling efficiency of a power semiconductor element can be raised. The refrigerant blocking member 407 is made of rubber or plastic.

  FIGS. 9A to 9D show other examples related to the present embodiment.

  FIG. 9A is a top view illustrating the first embodiment described with reference to FIGS. As described above, in the embodiment of FIG. 9A, the three power semiconductor modules are arranged such that the main surfaces of the three power semiconductor modules 300 corresponding to the three phases of the U phase, the V phase, and the W phase face each other. 300 are arranged in parallel. The capacitor storage space 490 for storing the capacitor cell 500 is formed at a position facing the side walls of the three power semiconductor modules 300. In this embodiment, four capacitor cells 500 are used, and the electrode surfaces of the respective capacitor cells 500 are arranged so as to be parallel to the main surface of the power semiconductor module 300.

  FIG. 9B shows a structure of the power conversion device in which the power semiconductor modules 300 are arranged in a line in the longitudinal direction, and the arrangement direction of the power semiconductor modules 300 and the arrangement direction of the capacitor cells 500 are parallel to each other. The openings 705 formed in the power board 700 may be arranged as illustrated in accordance with the arrangement of the power semiconductor module 300. This structure is a structure that can be applied when the space in which the power conversion device is mounted on the vehicle has an elongated rectangular shape.

  FIG. 9C shows the structure of the power conversion device in which the power semiconductor module 300 is disposed so as to face each of the three sides of the capacitor storage space 490 that stores the capacitor cell 500. That is, any two of the three power semiconductor modules 300 are disposed to face each other with the capacitor storage space 490 interposed therebetween. This structure is a structure that can be applied when the space in which the power conversion device is mounted on the vehicle has a rectangular shape that is relatively close to a square.

  FIG. 9D shows a power conversion device in which the power semiconductor module 300 is arranged with one power semiconductor module on one side and two power semiconductor modules on the other side across a capacitor storage space 490 for storing the capacitor cell 500. This is the structure. This structure is a structure that can be applied when the space in which the power conversion device is mounted on the vehicle has a rectangular shape.

  10 (a) to 10 (b) show an embodiment applied to a power conversion device incorporating a two inverter circuit, or a power conversion device incorporating a DC / DC converter circuit and an inverter circuit.

  FIG. 10A shows a structure in which two pieces of FIG. 9A are arranged symmetrically. That is, in FIG. 9A, the main surfaces of the three power semiconductor modules 300 are arranged in parallel so that they face each other, but in FIG. 10A, the main surfaces of the six power semiconductor modules 300 face each other. Are arranged in parallel. This structure is a structure that can be applied when the space in which the power conversion device is mounted on the vehicle has a rectangular shape that is relatively close to a square.

  FIG. 10B shows a structure in which the power semiconductor modules 300 of FIG. 9B are arranged in two rows. This structure is a structure that can be applied when the space in which the power conversion device is mounted on the vehicle has a rectangular shape.

  FIG. 10C shows the structure of the power conversion apparatus when a DC / DC converter circuit and an inverter circuit are incorporated. The power semiconductor module 1000 used for the DC / DC converter, the reactor 1001 used for the DC / DC converter, and the reactor storage space 1002 for storing the reactor 1001 are provided.

  FIG. 11 shows another example relating to the present embodiment.

  FIG. 11 shows a structure in which a low elastic sheet 1003 is provided between the flow path forming body 400 and the power board 700. An opening is formed in the low elastic sheet 1003 at a position overlapping the opening 705 of the power board 700. The elastic modulus of the low elastic sheet 1003 is lower than the elastic modulus of the insulating coating member 708 and the flow path forming body 400. As a result, in an in-vehicle environment where vibration or impact is applied, the power board 700 and the flow path forming body 400 are in direct contact with each other to prevent the insulating coating member 708 from being scratched or cracked by applying a load. Can be improved.

43 inverter device 110 hybrid vehicle 112 front wheel 114 front wheel axle 116 front wheel side differential gear 118 transmission 120 engine 122 power distribution mechanism 136 battery 138 DC connector 140 inverter device 142 inverter device 143 power converter 144 inverter circuit 150 upper and lower arm series circuit 153 collector Electrode 154 Gate electrode 155 Signal emitter electrode 156 Diode 157 Positive terminal 158 Negative terminal 159 AC terminal 163 Collector electrode 164 Gate electrode 165 Signal emitter electrode 166 Diode 169 Intermediate electrode 170 Control unit 172 Control circuit 174 Driver circuit 176 Signal line 180 Current sensor 182 Signal line 186 AC bus bar 188 AC connector 192 Motor generator 194 Motor Nerator 195 Auxiliary motor 200 Control board 299 Power converter 300 Power semiconductor module 302 Sealing body 304 Case 304D Frame body 305 Fin 306 Insertion port 311 Positioning part 312 O-ring groove 314 DC positive terminal 316 DC negative terminal 315 Conductor part 318 Conductor part 319 Conductor part 320 Conductor part 315D Positive terminal 319D Negative terminal 320D AC terminal 321A Exposed surface A
321B Exposed surface B
327U Upper arm signal connection terminal 327L Lower arm signal connection terminal 328 IGBT
329A Intermediate electrode A
329B Intermediate electrode B
330 IGBT
333 Insulating material 400 Flow path forming body 401 Flow path lid 402 Refrigerant input / output port 403 Opening 404 Flat surface 405 Module storage space 406 Recess 407 Refrigerant blocking member 490 Capacitor storage space 499 Refrigerant flow 500 Capacitor cell 501 Capacitor sealing resin 502 Capacitor cell Terminal 504 Negative side capacitor terminal 506 Positive side capacitor terminal 600 Insulated mold terminal 601 Auxiliary mold body 700 Power board 701 Terminal 702 Terminal 703 Positive side bus bar 704 Negative side bus bar 705 Opening 705A Opening A
705B Opening B
705C Opening C
708 Insulation coating member 709 AC bus bar 711 Terminal connection portion 800 Control board base 900 Case lid 1000 Double-sided cooling power module 1001 Reactor 1002 Reactor storage space 1003 Low elastic sheet

Claims (7)

A power semiconductor module that converts direct current to alternating current;
Forming a flow path for flowing the cooling refrigerant, a flow path forming body having an upper surface and a lower surface;
A power board for transmitting the direct current and the alternating current,
The power semiconductor module includes a power semiconductor element, a case that houses the power semiconductor element, and a terminal that transmits the direct current or the alternating current,
The flow path forming body accommodates the case and flows the cooling refrigerant, and a recess formed on the side facing the lower surface of the flow path forming body and facing the flow path space. A first opening penetrating from the bottom surface of the recess to the top surface of the flow path forming body is formed,
In the case, a part of the case is disposed in the recess,
The terminal protrudes out of the flow path space through the first opening,
When oblique from the normal direction of the upper surface of the flow path forming body,
The power board is disposed so as to face the upper surface of the flow path forming body so that the shaded portion of the power board overlaps with the shaded portion of the recess,
The power board is a power conversion device connected to the terminal. The power conversion device according to claim 1,
The power semiconductor module has a resin mold part,
The resin mold portion is disposed in the first opening,
The terminal is formed to protrude from one surface of the resin mold part,
The power semiconductor module is a power conversion device arranged so that the one surface of the resin mold portion is flush with the upper surface of the flow path forming body. The power conversion device according to claim 2,
The terminal includes a DC positive terminal and a DC negative terminal that transmit the DC power, an AC terminal that transmits the AC current, and a signal terminal that transmits the control signal.
The terminal is a power conversion device whose outer periphery is covered with the resin mold portion. The power conversion device according to any one of claims 1 to 3,
The power board includes a first DC bus bar and a second DC bus bar that transmit the DC current, and an insulating member.
In the first DC bus bar, a current having a polarity different from the current flowing in the second DC bus bar flows,
The first DC bus bar is disposed to face the second DC bus bar,
The insulating member is sealed so that the first DC bus bar and the second DC bus bar have a predetermined interval,
When projected from the normal direction of the upper surface of the flow path forming body,
The first DC bus bar and the second DC bus bar are power conversion devices that are arranged such that a projected portion of a facing region of the first DC bus bar and the second DC bus bar overlaps with a projected portion of the recess. The power conversion device according to claim 4,
The power board further includes an AC bus bar for transmitting the AC current,
The first DC bus bar is disposed between the second DC bus bar and the flow path forming body,
The surface of the first DC bus bar opposite to the side on which the second DC bus bar is disposed is defined as a first virtual surface,
A surface of the second DC bus bar opposite to the side on which the first DC bus bar is disposed is defined as a second virtual surface;
The AC bus bar is disposed between the first virtual surface and the second virtual surface, and is disposed in a region different from the region where the first DC bus bar and the second DC bus bar are disposed.
The AC bus bar is a power conversion device arranged so that one surface of the AC bus bar overlaps the first virtual surface. The power conversion device according to claim 5,
The AC bus bar is a power conversion device in which the thickness of the AC bus bar is greater than the thickness of the first DC bus bar and the thickness of the second DC bus bar. The power conversion device according to any one of claims 1 to 6,
The power board is placed on the upper surface of the flow path forming body with a low elastic sheet sandwiched between the power board and the upper surface of the flow path forming body,
The low-elastic sheet is a power conversion device formed such that an elastic modulus of the low-elastic sheet is smaller than an elastic modulus of the insulating member and an elastic modulus of the flow path forming body constituting the power board.