JP4064741B2 - Semiconductor device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To make the whole device compact and to reduce parasitic inductance or the like by stacking metal plates and arranging a plurality of semiconductor elements in parallel with each other. <P>SOLUTION: On a base metal plate 2, lamination metal plates 5 and 8 are stacked via an insulator 6. The metal plates 2, 5, and 8 are equipped with low voltage terminals 3, high voltage terminals 7, and output terminals 9, respectively. Each IGBT 10 and each diode 11 on the high voltage side are arranged in parallel with each other, and each IGBT 12 and each diode 13 on the low voltage side are also arranged in parallel with each other. Due to this structure, for example, the metal plates 2, 5, and 8 are formed in a large width, etc., drawing the IGBTs 10 and 12 closer to each other, and parasitic inductances of the IGBTs can be reduced, while at the same time forming a current path wide. Consequently, the IGBTs 10 and 12 can be prevented from being damaged due to the concentration of surge voltage or current caused by the parasitic inductances. <P>COPYRIGHT: (C)2004,JPO

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a semiconductor device suitably used for outputting a large current by a semiconductor element such as an insulated gate bipolar transistor (IGBT) or a MOS transistor (MOSFET).
[0002]
[Prior art]
Generally, as a semiconductor device, for example, a three-phase AC type inverter device that converts a DC power source such as a battery into AC and drives an electric motor or the like with an AC current is known (for example, Japanese Patent Laid-Open No. 10-229680). etc).
[0003]
In this type of conventional inverter device, for example, each phase (U phase, V phase, W phase) of three-phase alternating current is constituted by a high voltage side circuit unit and a low voltage side circuit unit, respectively. The unit is configured by connecting a plurality of semiconductor elements in parallel.
[0004]
In this case, for example, in the circuit unit on the high voltage side, a U-shaped metal fin is erected vertically on a base plate that is a main body portion, and each semiconductor element is attached to the metal fin by means such as screwing. And installed vertically. Further, the high voltage side circuit units constituting each of the three phases are connected in parallel to each other using a substantially L-shaped high voltage terminal plate connected to a plus electrode such as a battery.
[0005]
Similarly, the circuit unit on the low voltage side is mounted with each semiconductor element standing on the metal fin on the base plate, and each phase circuit unit is substantially L-shaped connected to the negative electrode of a battery or the like. Are connected in parallel with each other using a low voltage terminal plate. In addition, a substantially L-shaped connection plate is provided between the high voltage side and low voltage side circuit units to connect the two.
[0006]
Here, each semiconductor element is attached to the metal fin in an upside-down state, and terminals such as a source and a gate protrude upward. For this reason, the connecting plate is connected to the source at a position where one end side covers each semiconductor element on the high voltage side, and the other end side is bent downward in a substantially L shape, and the circuit unit on the low voltage side It is connected. Similarly, each semiconductor element on the low voltage side has a source or the like protruding upward connected to another connection plate, and this connection plate is bent downward and connected to the low voltage terminal plate.
[0007]
In addition, the high voltage terminal plate and the low voltage terminal plate are formed by, for example, a metal plate extending along the back side of the base plate of each circuit unit. It is arranged so that it is pinched below. Further, one end side of each terminal plate is bent upward in a substantially L shape from the back side of the base plate, and is led out to the upper surface side of a power supply capacitor or the like provided in the inverter device.
[0008]
[Problems to be solved by the invention]
By the way, in the prior art mentioned above, it is set as the structure which attaches to a metal fin in the state which erected the metal fin on the base board and stood each semiconductor element upside down. However, in this case, for example, the source of each semiconductor element on the low voltage side needs to be routed in a substantially U shape from the upper side to the lower side of the semiconductor element by the connection plate and the low voltage terminal plate.
[0009]
For this reason, in the prior art, the wiring structure on the low voltage side including the connection plate and the low voltage terminal plate is complicated and long, and the parasitic inductance is increased. There is a problem that a large surge voltage or the like is generated in the wiring and the operation of the apparatus becomes unstable, and the reliability is lowered.
[0010]
Further, in the inverter device of the prior art, a connection plate for connecting the semiconductor elements on the high voltage side and the low voltage side, a low voltage terminal plate, a high voltage terminal plate, and the like are also bent in an L shape. Therefore, the wiring becomes complicated and long even in these portions, the parasitic inductance of the wiring increases, and a surge voltage is easily generated.
[0011]
The present invention has been made in view of the above-described problems of the prior art, and an object of the present invention is to simplify the wiring structure of the entire device even when a large number of semiconductor elements are mounted, for example. An object of the present invention is to provide a semiconductor device in which elements can be stably operated and reliability can be improved.
[0012]
[Means for Solving the Problems]
In order to solve the above-described problem, the invention of claim 1 is directed to a first metal plate provided with a low voltage terminal connected to a low voltage side of a power source, and an insulating material on the surface side of the first metal plate. And a second metal plate provided with a high voltage terminal connected to the high voltage side of the power supply, and insulated on the surface side of the first metal plate at a position different from the second metal plate A back surface electrode is formed on the second metal plate formed by a semiconductor element having a third metal plate laminated via a material and provided with an output terminal for outputting current to the outside, and a front surface electrode and a back surface electrode. A plurality of high-voltage side elements arranged side by side and connected to the third metal plate, and a semiconductor element having a surface electrode and a back electrode, and the back electrode is the third metal plate The first metal plate is arranged side by side and the surface electrode is the first metal plate A plurality of low voltage side elements connected to each other, and a control circuit board that controls the energization state of each of the high voltage side elements and the low voltage side elements, and a second metal plate on the first metal plate A configuration is adopted in which a plurality of high-voltage side elements arranged on the side and a plurality of low-voltage side elements arranged on the third metal plate are arranged in parallel with each other.
[0013]
By configuring in this manner, for example, the width dimension of each metal plate can be formed large, and each high voltage side element and low voltage side element can be arranged in parallel in the width direction, and the high voltage side and low voltage side elements can be arranged in parallel. Elements can be brought close together. As a result, the current path flowing through each metal plate can be formed wide, and the current path on the low voltage side by the first metal plate and the current path on the high voltage side by the second metal plate are stacked above and below. can do.
[0014]
As a result, the parasitic inductance can be reduced according to the width dimension of each metal plate, the distance between the high-voltage side element and the low-voltage side element, etc., and a large surge voltage or the like is generated due to the parasitic inductance. Can be prevented. In addition, since the amount of current applied to each element can be evenly distributed and uniform, even when a large current is controlled in the semiconductor device, each element can be protected from damage due to current concentration, etc. Can be realized. Further, since the elements can be mounted by laminating the respective metal plates, the wiring structure can be simplified, the entire apparatus can be formed compactly, and the heat dissipation of the elements can be enhanced.
[0015]
According to the invention of claim 2, the low voltage terminal is formed integrally with the first metal plate, the high voltage terminal is formed integrally with the second metal plate, and the output terminal is integrated with the third metal plate. It is set as the structure formed in.
[0016]
Thereby, individual terminals can be easily formed together with the first, second, and third metal plates, and the number of parts of the semiconductor device can be reduced. Further, since the flat terminals can be drawn out from the side surface of the semiconductor device, for example, it is not necessary to bend in an L shape in order to pull out each terminal from the upper surface side of the device, and the reduction of parasitic inductance can be promoted. .
[0017]
In the invention of claim 3, the first metal plate provided with the high voltage terminal connected to the high voltage side of the power source, and the first metal plate are laminated on the surface side of the first metal plate with an insulating material interposed therebetween. A second metal plate provided with a low voltage terminal connected to the low voltage side of the power source, and laminated on the surface side of the first metal plate at a position different from the second metal plate via an insulating material. A third metal plate provided with an output terminal for outputting current to the outside, a semiconductor element having a front electrode and a back electrode, and the back electrode is arranged side by side on the first metal plate and A surface electrode is formed by a semiconductor element having a plurality of high voltage side elements connected to the third metal plate, and a surface electrode and a back electrode, and the back electrode is arranged side by side on the third metal plate. And a plurality of low electrodes in which the surface electrode is connected to the second metal plate. A plurality of high-voltage side elements arranged on the first metal plate and the first voltage-side elements, and a control circuit board that controls the energization state of the high-voltage side elements and the low-voltage side elements. A plurality of low voltage side elements arranged on the third metal plate are arranged in parallel with each other on the metal plate.
[0018]
As a result, for example, the width dimension of the metal plate can be increased and the elements on the high voltage side and the low voltage side can be arranged side by side in the width direction, and these elements can be arranged in parallel due to surge voltage due to parasitic inductance or damage due to current concentration Can be protected from. Moreover, the whole apparatus can be formed compactly and the heat dissipation of an element can be improved.
[0019]
In addition, since the second metal plate connected to the low voltage side of the power supply can be formed in a smaller area, the parasitic inductance of the current path on the low voltage side can be further reduced. Thereby, the surge voltage generated on the second metal plate side can be further reduced. For this reason, for example, even when the potential of the second metal plate is used as the reference potential of the control circuit board, the control circuit board can be stably operated.
[0020]
According to the invention of claim 4, the high voltage terminal is formed integrally with the first metal plate, the low voltage terminal is formed integrally with the second metal plate, and the output terminal is connected to the third metal plate. It is configured to do.
[0021]
Thereby, the first and second metal plates can be formed together with the individual terminals to reduce the number of parts. In addition, since the flat terminal can be drawn from the side surface of the semiconductor device, reduction of parasitic inductance can be promoted.
[0022]
According to the invention of claim 5, at least one of the second and third metal plates is formed by a metal layer fixed to an insulating ceramic layer, and the ceramic layer and the metal layer are ceramics. It is configured as a substrate. Thereby, since a semiconductor device can be constituted using a general-purpose ceramic substrate, the number of parts such as an insulating material can be reduced and assembly work can be performed efficiently.
[0023]
According to the invention of claim 6, the high-voltage side element and the low-voltage side element are arranged together with the electric motor in the housing of the electric machine, and constitute an inverter device that drives the electric motor with an alternating current. .
[0024]
Thus, the inverter device can be formed compactly using the first to third metal plates, and the electric motor can be stably driven with a large current. Moreover, since the low voltage terminal, the high voltage terminal, the output terminal, etc. of the inverter device can be drawn out in parallel to the metal plate from the side surface of the device, these terminals can be easily extended to the outside of the housing of the electric machine. .
[0025]
Further, according to the invention of claim 7, the high-voltage side element and the low-voltage side element are constituted by insulated gate bipolar transistors, MOS transistors or bipolar transistors. As a result, the semiconductor element can control a large current by a semiconductor element such as an IGBT, MOSFET, or bipolar transistor.
[0026]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, a semiconductor device according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings.
[0027]
1 to 6 show a first embodiment. In this embodiment, an inverter device is described as an example of a semiconductor device.
[0028]
Reference numeral 1 denotes an inverter device for driving a load 17 described later. The inverter device 1 includes a base metal plate 2, a resin case 4, laminated metal plates 5 and 8, IGBTs 10 and 12, diodes 11 and 13, and a control circuit board 14 described later. Etc. are configured.
[0029]
Further, the inverter device 1 constitutes a circuit for one phase out of three phases including a U phase, a V phase, and a W phase in a three-phase AC inverter circuit 15 shown in FIG. 4 described later. is there.
[0030]
Reference numeral 2 denotes a base metal plate as a first metal plate constituting the inverter device 1, and the base metal plate 2 is formed as a substantially rectangular flat plate, and the left, right direction (X-axis direction) and front in FIG. , Extending in the rear direction (Y-axis direction).
[0031]
Reference numeral 3 denotes a low voltage terminal formed integrally with the base metal plate 2, and the low voltage terminal 3 is formed as a flat terminal protruding from the base metal plate 2, and protrudes from the left side surface of the inverter device 1, for example. The projecting end side is connected to the negative electrode side of the battery 16 to be described later. In this case, the low voltage terminal 3 and the high voltage terminal 7 and output terminal 9 to be described later are led out from a portion of the side surface of the inverter device 1 on the back surface side close to the base metal plate 2 and are almost the same as the metal plate 2 and the like. It extends in parallel.
[0032]
4 is an insulating resin case fixed to the surface side of the base metal plate 2 by means of, for example, adhesion or resin molding. The resin case 4 includes the laminated metal plates 5 and 8, the control circuit board 14 and the like. It is formed as a surrounding frame-like body and is closed by a cover plate (not shown) or the like.
[0033]
Reference numeral 5 denotes a high-voltage side laminated metal plate as a second metal plate laminated on the base metal plate 2 via an insulating material 6, and the laminated metal plate 5 is formed of a base metal as shown in FIGS. It is formed as a substantially rectangular flat plate that is smaller than the plate 2, and is disposed, for example, on one side (left side) of the base metal plate 2 in the X-axis direction and has a width dimension W1 in the Y-axis direction.
[0034]
Reference numeral 7 denotes a high voltage terminal formed integrally with the laminated metal plate 5 on the high voltage side. The high voltage terminal 7 is formed as a flat terminal extending from the laminated metal plate 5, for example, the left side surface of the resin case 4. And projecting in the same direction as the low voltage terminal 3, and arranged at a position not overlapping the low voltage terminal 3. The high voltage terminal 7 is connected to the positive electrode side of the battery 16.
[0035]
8 is a laminated metal plate on the output side as a third metal plate laminated on the base metal plate 2 via the insulating material 6. The laminated metal plate 8 is substantially the same as the laminated metal plate 5 as shown in FIG. Similarly, it is formed as a substantially rectangular flat plate having a width dimension W2 in the Y-axis direction. The laminated metal plate 8 is disposed, for example, on the other side (right side) of the base metal plate 2 in the X-axis direction, and faces the laminated metal plate 5 with a gap in the X-axis direction interposed therebetween.
[0036]
Reference numeral 9 denotes an output terminal formed integrally with the laminated metal plate 8 on the output side, and the output terminal 9 is formed as a flat terminal protruding from the laminated metal plate 8, for example, the terminal 3 from the right side surface of the resin case 4. , 7 protrudes in the opposite direction. The output terminal 9 is connected to a load 17 described later.
[0037]
Reference numeral 10 denotes, for example, three IGBTs as high-voltage side elements surface-mounted on the high-voltage side laminated metal plate 5, and each IGBT 10 is composed of, for example, a rectangular chip-shaped bare chip type semiconductor element. These diodes 11 are arranged in a straight line with a constant pitch (interval) in the Y-axis direction.
[0038]
Further, as shown in FIG. 4, an emitter E as a front electrode and a gate G for energization control are provided on the front side of each IGBT 10, and a collector C as a back electrode is disposed on the back side of the IGBT 10. ing. The IGBT 10 is fixed to the laminated metal plate 5 using solder or the like, and the collector C is connected to the high voltage terminal 7 of the laminated metal plate 5. The emitter E of the IGBT 10 is connected to the output-side laminated metal plate 8 using metal wires 10A and 10B by means such as wire bonding, for example, and the gate G is connected to a control circuit described later using another metal wire 10C. It is connected to the substrate 14.
[0039]
Reference numeral 11 denotes, for example, three diodes constituting a high-voltage side element together with the IGBT 10. Each of the diodes 11 is surface-mounted on the laminated metal plate 5, and is connected between the collector C and the emitter E of each IGBT 10 using a metal wire 10 </ b> A or the like. Are connected in parallel.
[0040]
Reference numeral 12 denotes an IGBT as, for example, three low-voltage side elements surface-mounted on the laminated metal plate 8 on the output side. Each IGBT 12 is composed of a semiconductor element substantially the same as the IGBT 10, and its collector C is a laminated metal plate 8. Connected with. The emitter E of the IGBT 12 is connected to the base metal plate 2 on the low voltage side using a metal wire 12A, is connected to a diode 13 described later using a metal wire 12B, and the gate G uses a metal wire 12C. Are connected to the control circuit board 14.
[0041]
Reference numeral 13 denotes, for example, three diodes constituting a low-voltage side element together with the IGBT 12. Each of the diodes 13 is surface-mounted on the laminated metal plate 8, and between the collector C and the emitter E of each IGBT 12 using a metal wire 12B or the like. Are connected in parallel.
[0042]
Here, the inverter device 1 increases the amount of current that can be energized as a whole by connecting three high-voltage-side IGBTs 10 and three low-voltage-side IGBTs 12 in parallel. The configuration is such that the loss due to internal resistance or the like is kept small.
[0043]
In this case, the high-voltage side and low-voltage side IGBTs 10 and 12 are arranged along the Y-axis direction at substantially equal pitches, and are parallel to each other over almost the entire length of the width dimensions W1 and W2 of the laminated metal plates 5 and 8. The IGBTs 10 and 12 are opposed to each other with an interval in the X-axis direction. Similarly, the high-voltage side and low-voltage side diodes 11 and 13 are also arranged side by side so as to have a parallel positional relationship.
[0044]
As a result, the inverter device 1 causes the base metal plate 2 and the laminated metal plate 8 when a large current flows between the laminated metal plates 5 and 8 via the high-voltage-side IGBTs 10 or via the low-voltage-side IGBTs 12. When a large current flows between them, these current paths are formed uniformly over substantially the entire width of the metal plates 2, 5, and 8, and the current paths on the high voltage side and the low voltage side are formed on the metal plates 2, 5, and 8. For example, the upper and lower layers are stacked. That is, the current path on the high voltage side and the low voltage side can be formed wide and extended to the immediate vicinity of the IGBTs 10 and 12, and these current paths are laminated so that the current directions are opposite to each other. Can do. Therefore, in the present embodiment, the parasitic inductance of the metal plates 2, 5, 8, etc. can be suppressed small according to the width dimensions W 1, W 2, etc., and a large current can be stably distributed to the individual IGBTs 10, 12. It has become.
[0045]
Reference numeral 14 denotes a control circuit board mounted in the resin case 4. The control circuit board 14 is disposed above the metal plates 2, 5, and 8 with a gap as shown in FIG. The control circuit board 14 is provided with a control circuit (not shown) for controlling the energization state of the IGBTs 10 and 12, and this control circuit uses the metal wires 10 C and 12 C in the vicinity of the end of the board 14. Are connected to the individual IGBTs 10 and 12.
[0046]
And the inverter apparatus 1 converts direct current power supplies, such as the battery 16, into alternating current by carrying out ON / OFF control of each IGBT10 and 12 using the control circuit board 14. FIG. In this case, as shown in FIG. 4, the inverter device 1 is connected in parallel to the battery 16 together with other inverter devices 1 ′ and 1 ″ configured substantially the same as the inverter device 1, for example. A three-phase AC type inverter circuit 15 is configured in which the devices 1, 1 'and 1 "are U phase, V phase and W phase. The output terminals 9, 9 ′, 9 ″ of the inverter circuit 15 output, for example, a three-phase alternating current to drive a load 17 such as an electric motor.
[0047]
The inverter device 1 according to the present embodiment has the above-described configuration, and the operation thereof will be described next.
[0048]
First, when the IGBTs 10 and 12 are turned on and off, a large current flows in the X-axis direction between the high-voltage side laminated metal plate 5 and the output-side laminated metal plate 8 via each IGBT 10, A large current also flows between the base metal plate 2 on the low voltage side and the laminated metal plate 8 through the IGBTs 12 in the X-axis direction.
[0049]
In this case, the IGBTs 10 and 12 are arranged side by side over the width dimensions W1 and W2 of the laminated metal plates 5 and 8 so as to be opposed to each other with a parallel positional relationship. 5 and 8 are formed uniformly over almost the entire width, and the current paths on the high voltage side and the low voltage side are stacked on the top and bottom.
[0050]
Since the current paths of the metal plates 2 and 5 are wide and the directions of the currents are opposite to each other, and the current paths of the metal plates 5 and 8 are also wide and opposite to each other, Inductance can be reduced. Thereby, the parasitic inductance of the metal plates 2, 5, 8 can be reduced according to the width dimensions W1, W2, and the like.
[0051]
In each IGBT 10, 12, the length of the current path from the high voltage terminal 7 to the output terminal 9 via the IGBT 10 and the length of the current path from the output terminal 9 to the low voltage terminal 3 via the IGBT 12 are individually set. The IGBTs 10 and 12 are substantially the same. Therefore, the current density of a part of the IGBTs with short current paths among the IGBTs is increased, and current can be prevented from concentrating on the IGBTs. That is, since a large current is distributed and supplied to the individual IGBTs 10 and 12 almost uniformly, it is possible to prevent a part of the IGBTs 10 and 12 from being damaged due to current concentration or the like.
[0052]
Further, when the IGBTs 10 and 12 are energized, a large amount of heat is generated according to the amount of current. However, the IGBTs 10 and 12 are surface-mounted on the laminated metal plates 5 and 8, and these metal plates 5 and 8 are laminated on the base metal plate 2 with a wide area. 5 and 8 can be efficiently escaped.
[0053]
Thus, in the present embodiment, the laminated metal plates 5 and 8 are laminated on the base metal plate 2, and the high voltage side and low voltage side IGBTs 10 and 12 are arranged in parallel to each other on these laminated metal plates 5 and 8. Since it is configured to be mounted, a uniform current path can be formed over almost the entire width of the metal plates 2, 5, and 8, and the current path on the high voltage side and the low voltage side are formed as wide as possible. Current paths can be stacked on top and bottom.
[0054]
In this case, even if a plurality of IGBTs are simply arranged in a plane using a metal plate, a wide and uniform current path is provided between the IGBTs unless the area of the metal plate is increased to increase the size of the inverter device. It is difficult to form or shorten the connection distance between IGBTs on the high voltage side and the low voltage side.
[0055]
However, in the present embodiment, by laminating the metal plates 2, 5, 8, the base metal plate 2 is formed to the minimum size necessary for mounting the IGBTs 10, 12, and the width dimensions W 1, The parasitic inductance can be easily reduced by securing W2 and the like. Moreover, the high-voltage side and low-voltage side IGBTs 10 and 12 can be brought close to each other to reduce the parasitic inductance between them, and the surge voltage and the like generated during energization can be suppressed to a small level. For this reason, it is possible to reliably prevent the IGBTs 10 and 12 from being damaged by the surge voltage or the like and the operation of the inverter device 1 from becoming unstable.
[0056]
In addition, since the amount of current supplied to the individual IGBTs 10 and 12 can be evenly distributed and kept small, even when a large current is controlled by the inverter device 1, the IGBTs 10 and 12 are protected from damage due to current concentration or the like. In addition, an inverter device 1 having a large allowable current can be realized.
[0057]
Furthermore, since there is no need to use a connection plate, a terminal plate or the like bent in an L shape as in the prior art, the inverter device 1 can be formed thin and compact, and the parasitic inductance can be more reliably reduced. Moreover, since a wide contact area can be ensured between the laminated metal plates 5 and 8 and the base metal plate 2, the heat dissipation of the IGBTs 10 and 12 can be enhanced.
[0058]
Therefore, according to the present embodiment, the wiring structure of the entire apparatus can be simplified by using the metal plates 2, 5, and 8, the operations of the IGBTs 10 and 12 and the like can be stabilized, and the performance and reliability of the inverter device 1 can be achieved. Can be improved. For example, even when four or more IGBTs 10 and 12 are mounted on the inverter device 1, the width dimensions W 1 and W 2 of the metal plates 2, 5, and 8 are simply increased corresponding to the number of IGBTs 10 and 12. Can be easily accommodated, and the degree of freedom in design can be increased.
[0059]
In addition, since the low voltage terminal 3, the high voltage terminal 7, and the output terminal 9 are integrally formed with the metal plates 2, 5, and 8, respectively, these terminals 3, 7, and 9 can be easily formed. The score can be reduced. In this case, since the flat terminals 3, 7, 9 can be drawn out from the side surface of the inverter device 1, for example, it is not necessary to bend the terminals from the upper surface side of the resin case 4, and it is not necessary to bend in an L shape. Reduction of inductance can be promoted.
[0060]
Further, since the control circuit board 14 is disposed above the metal plates 2, 5, 8 with a gap, for example, it is not necessary to provide the board 14 on the same plane as the metal plates 2, 5, 8, and the inverter device 1 can be made compact. It can be formed, and the high voltage side and low voltage side IGBTs 10 and 12 can be easily brought close to each other.
[0061]
In this case, since the gates G of the IGBTs 10 and 12 are connected to the control circuit board 14 by means such as wire bonding, as compared with the case where the terminals of the semiconductor elements are inserted through the through holes of the control circuit board as in the prior art. Thus, it is not necessary to align the control circuit board 14 with the IGBTs 10 and 12 with high accuracy, and these assembly and connection operations can be performed efficiently.
[0062]
In the present embodiment, the high voltage side IGBTs 10 and the low voltage side IGBTs 12 are arranged in parallel to each other, and the terminals 3, 7, and 9 (bus bar electrodes) are attached between the IGBTs 10, 12. There is no site. For this reason, the plurality of IGBTs 10 and the plurality of IGBTs 12 can be connected to each other at a short distance, and the parasitic impedances of these connection parts can be sufficiently reduced.
[0063]
Thereby, when the IGBTs 10 and 12 perform the switching operation, for example, negative surge voltage or voltage ringing occurs due to parasitic inductance of the metal plates 2, 5, 8, etc., and the potential of the base metal plate 2 is higher than the ground potential. For example, even when the potential of the base metal plate 2 is used as the reference potential of the control circuit board 14, the control circuit board 14 can be stably operated.
[0064]
Here, the negative surge voltage generated by the switching operation of the IGBTs 10 and 12 will be described with reference to the equivalent circuit of the inverter device 1 shown in FIG. In this case, L1 in FIG. 5 indicates the parasitic inductance of the high-voltage side laminated metal plate 5 and the like, L2 and L3 are parasitic inductances of the output-side laminated metal plate 8 and the like, and L4 is the low-voltage side base metal plate 2 Parasitic inductances such as are shown.
[0065]
First, when the high voltage side IGBT 10 is in the ON state and the low voltage side IGBT 12 is in the OFF state, the load current Ia flows from the battery 16 to the load 17 via the IGBT 10.
[0066]
Next, when the IGBT 10 is switched from ON to OFF, the load current Ia instantaneously changes due to the energy stored in the load 17 and changes to a transition current Ib flowing through the low-voltage side diode 13. Since the current change rate (di / dt) at this time is a large value, even if the parasitic inductances L4 and L3 of the metal plates 2 and 8, for example, are small, the low voltage terminal 3 and the output terminal 9 In the meantime, a large back electromotive force defined as, for example, (L3 + L4) × di / dt is generated.
[0067]
In addition, since a voltage drop due to the IGBT 10 being turned off also occurs between the low voltage terminal 3 and the output terminal 9, the voltage drop and the counter electromotive force are added, whereby the low voltage terminal 3 and the output terminal 9 are output. As shown in FIG. 6, a negative surge voltage Vs that varies more negatively than the ground potential may occur in the voltage V between the terminal 9 and the terminal 9.
[0068]
However, in the present embodiment, since the parasitic inductances L1 to L4 can be reduced by reducing the area of the metal plates 2, 5, 8, etc., the negative surge voltage Vs can be suppressed to a low level. The potential can be used as the reference potential of the control circuit board 14, and the control circuit board 14 can be prevented from malfunctioning due to negative surge voltage Vs, voltage ringing, or the like.
[0069]
Next, FIGS. 7 and 8 show a second embodiment according to the present invention. The feature of this embodiment is that a high voltage terminal is provided on the first metal plate, and a low voltage terminal is provided on the second metal plate. It is that it was set as the structure which provides. In the present embodiment, the same components as those in the first embodiment are denoted by the same reference numerals, and the description thereof is omitted.
[0070]
An inverter device 21 includes a base metal plate 22, a resin case 24, laminated metal plates 25 and 28, IGBTs 30 and 32, diodes 31 and 33, a control circuit board 34, and the like, which will be described later. For example, one phase of a three-phase AC inverter circuit is configured.
[0071]
Reference numeral 22 denotes a base metal plate as a first metal plate constituting the inverter device 21. The base metal plate 22 is formed as a substantially rectangular flat plate and extends in the X-axis direction and the Y-axis direction in FIG. Yes. Further, a flat high voltage terminal 23 is integrally formed on the base metal plate 22, and the high voltage terminal 23 protrudes from a portion on the back surface side near the base metal plate 22 on the right side surface of the inverter device 21, for example. Yes.
[0072]
Here, in the inverter device 21, the base metal plate 22 is connected to the positive electrode side of the battery 16 through the high voltage terminal 23, and a laminated metal plate 25 described later is connected to the negative electrode side of the battery 16 through the low voltage terminal 27. It is configured to be connected to. Thereby, the inverter device 21 is formed so that the conductor area on the low voltage side (laminated metal plate 25) is smaller than that of the first embodiment.
[0073]
Reference numeral 24 denotes an insulating resin case fixed to the surface side of the base metal plate 22. The resin case 24 includes the laminated metal plates 25 and 28, the control circuit board 34, and the like in substantially the same manner as in the first embodiment. It is formed as a surrounding frame.
[0074]
Reference numeral 25 denotes a low-voltage-side laminated metal plate as a second metal plate laminated on the base metal plate 22 via an insulating material 26. The laminated metal plate 25 is composed of a base metal as shown in FIGS. It is formed as a substantially rectangular flat plate smaller than the plate 22. Further, a flat low voltage terminal 27 is integrally formed on the laminated metal plate 25, and the low voltage terminal 27 protrudes from the right side surface of the resin case 24, for example.
[0075]
Reference numeral 28 denotes an output-side laminated metal plate as a third metal plate laminated on the base metal plate 22 via an insulating material 26. The laminated metal plate 28 is a substantially rectangular flat plate smaller than the base metal plate 22. It is formed as.
[0076]
Here, the laminated metal plate 28 is disposed in the vicinity of the center of the base metal plate 22 in the X-axis direction. The base metal plate 22 is provided with an IGBT 30 and a diode 31, which will be described later, on one side (left side) of the laminated metal plate 28, and the low voltage side on the other side (right side) of the laminated metal plate 28 in the X axis direction. The laminated metal plate 25 is arranged.
[0077]
Reference numeral 29 denotes a flat output terminal provided by connecting to the output side laminated metal plate 28 using a metal wire 29A. The output terminal 29 is formed of an elongated metal piece or the like. It is attached to the left side surface of the case 24 and protrudes in and out of the resin case 24. The output terminal 29 is connected to a load 17 such as an electric motor.
[0078]
Reference numeral 30 denotes, for example, three IGBTs as high-voltage side elements. Each of the IGBTs 30 is composed of, for example, a bare chip type semiconductor element or the like, as in the first embodiment. And are arranged in a straight line at a constant pitch along the Y-axis direction.
[0079]
In each IGBT 30, the collector C as the back electrode is connected to the base metal plate 22 on the high voltage side, and the emitter E as the front electrode is connected to the laminated metal plate 28 on the output side using the metal wires 30A and 30B. In addition, the gate G is connected to a control circuit board 34 to be described later using another metal line 30C. Further, each diode 31 is arranged together with each IGBT 30, and is connected in parallel between the collector C and the emitter E of each IGBT 30 using a metal wire 30A or the like.
[0080]
Reference numeral 32 denotes, for example, three IGBTs as low-voltage side elements. Each IGBT 32 is surface-mounted together with the diode 33 on the output-side laminated metal plate 28, and the collector C is connected to the laminated metal plate 28. Further, the emitter E of the IGBT 32 is connected to the low-voltage side laminated metal plate 25 using a metal wire 32A, is connected to a diode 33 using a metal wire 32B, and the gate G is controlled using a metal wire 32C. The circuit board 34 is connected. The diode 33 is connected in parallel between the collector C and the emitter E of each IGBT 32.
[0081]
Here, the IGBTs 30 and 32 on the high voltage side and the low voltage side are arranged along the Y-axis direction at substantially the same pitch as in the first embodiment, and the individual IGBTs 30 and 32 are arranged as X While facing each other at intervals in the axial direction, they are arranged in parallel over almost the entire width of the laminated metal plates 25 and 28. Similarly, the high-voltage side and low-voltage side diodes 31 and 33 are arranged in parallel with each other.
[0082]
As a result, the inverter device 21 is configured such that when a large current flows in the X-axis direction between the base metal plate 22 and the laminated metal plate 28 via the high-voltage-side IGBTs 30 or via the low-voltage-side IGBTs 32. When a large current flows between the laminated metal plates 25 and 28 in the X-axis direction, a wide current path is formed over almost the entire width in the Y-axis direction of the metal plates 22, 25 and 28, and the high-voltage side and the low-voltage side The current path is stacked on the top and bottom by the metal plates 22 and 25. Therefore, in the present embodiment, the parasitic inductance of the metal plates 22, 25, 28, etc. can be suppressed to be small according to their width dimensions, and a large current can be stably distributed to the individual IGBTs 30, 32.
[0083]
Reference numeral 34 denotes a control circuit board mounted in the resin case 24. The control circuit board 34 is disposed with a gap above the metal plates 22, 25, 28 in substantially the same manner as in the first embodiment. The individual IGBTs 30 and 32 are connected using the lines 30C and 32C.
[0084]
Thus, in the present embodiment configured as described above, it is possible to obtain substantially the same operational effects as those of the first embodiment. In particular, in the present embodiment, since the base metal plate 22 is provided with the high voltage terminal 23 and the laminated metal plate 25 is provided with the low voltage terminal 27, the conductor area on the low voltage side made of the laminated metal plate 25 is reduced. The parasitic inductance on the low voltage side can be further reduced.
[0085]
Thereby, when the IGBTs 30 and 32 perform the switching operation, negative surge voltage or voltage ringing occurs due to the parasitic inductance on the laminated metal plate 25 side, and the potential of the laminated metal plate 25 fluctuates to the minus side from the ground potential. For example, even when the potential of the laminated metal plate 25 is used as the reference potential of the control circuit board 34, the control circuit board 34 can be stably operated.
[0086]
Here, as in the case described with reference to FIGS. 5 and 6 in the first embodiment, the negative surge voltage generated by the switching operation of the IGBTs 30 and 32 will be described. In this case, first, when the high voltage side IGBT 30 is in the ON state and the low voltage side IGBT 32 is in the OFF state, the load current Ia flows from the battery 16 to the load 17 via the IGBT 30.
[0087]
Next, when the IGBT 30 is switched from ON to OFF, the load current Ia instantaneously changes due to the energy stored in the load 17 and changes to a transition current Ib flowing through the low-voltage side diode 33. Since the current change rate (di / dt) at this time is a large value, even if the parasitic inductances L4 and L3 of the laminated metal plates 25 and 28 are small, for example, the low voltage terminal 27 and the output terminal 29 In the meantime, a large back electromotive force defined as, for example, (L3 + L4) × di / dt is generated.
[0088]
In addition, since a voltage drop due to the IGBT 30 being turned off also occurs between the low voltage terminal 27 and the output terminal 29, the voltage drop and the counter electromotive force are added, whereby the low voltage terminal 27 and the output terminal 29 are output. A negative surge voltage Vs that fluctuates more negatively than the ground potential may occur in the voltage V between the terminal 29 and the terminal 29.
[0089]
However, in the present embodiment, since the area of the laminated metal plate 25 can be further reduced to reduce the parasitic inductance L4 on the low voltage side, the negative surge voltage Vs can be kept small. Can be used as the reference potential of the control circuit board 34, and the control circuit board 34 can be prevented from malfunctioning due to negative surge voltage Vs, voltage ringing, or the like.
[0090]
Next, FIG. 9 shows a third embodiment according to the present invention. The feature of this embodiment is that a ceramic substrate is used in the first embodiment. In the present embodiment, the same components as those in the first embodiment are denoted by the same reference numerals, and the description thereof is omitted.
[0091]
Reference numeral 41 denotes an inverter device. The inverter device 41 includes a base metal plate 2, a resin case 4, IGBTs 10 and 12, diodes 11 and 13, a control circuit board 14, and a laminate described later, almost as in the first embodiment. It includes metal plates 43, 46 and the like. However, the laminated metal plates 43 and 46 are configured as part of ceramic substrates 42 and 45 described later.
[0092]
Reference numeral 42 denotes a ceramic substrate provided on the base metal plate 2 by means of, for example, soldering or adhesion. The ceramic substrate 42 is constituted by, for example, a general-purpose laminated substrate, and the high voltage in the first embodiment. The laminated metal plate 5 and the insulating material 6 on the side are used instead. In the ceramic substrate 42, metal layers 42B are laminated on both sides of a ceramic layer 42A serving as an insulating material.
[0093]
Reference numeral 43 denotes a laminated metal plate as a second metal plate formed by using the metal layer 42B on the surface side of the ceramic substrate 42. On the laminated metal plate 43, the high voltage side IGBT 10 and the diode 11 are mounted. ing. Further, a high voltage terminal 44 is joined to the laminated metal plate 43 by means of, for example, soldering or ultrasonic joining, and the high voltage terminal 44 protrudes to the outside of the resin case 4.
[0094]
Reference numeral 45 denotes another ceramic substrate provided on the base metal plate 2. The ceramic substrate 45 is composed of a general-purpose laminated substrate or the like that is substantially the same as the ceramic substrate 42, and is laminated on the output side in the first embodiment. It is used instead of the metal plate 8 and the insulating material 6. The ceramic substrate 45 has a metal layer 45B laminated on both sides of a ceramic layer 45A serving as an insulating material.
[0095]
Reference numeral 46 denotes a laminated metal plate as a third metal plate formed by using the metal layer 45B on the surface side of the ceramic substrate 45, and the low voltage side IGBT 12 and the diode 13 are mounted on the laminated metal plate 46. The output terminal 47 is joined.
[0096]
Thus, in the present embodiment configured as described above, it is possible to obtain substantially the same operational effects as those of the first embodiment. In particular, in the present embodiment, since the inverter device 41 can be configured using the general-purpose ceramic substrates 42 and 45, the number of parts such as the insulating material 6 can be reduced and the assembly work can be performed efficiently.
[0097]
Next, FIG. 10 shows a fourth embodiment according to the present invention. The feature of this embodiment is that a ceramic substrate is used in the second embodiment. In the present embodiment, the same components as those in the second embodiment are denoted by the same reference numerals, and the description thereof is omitted.
[0098]
Reference numeral 51 denotes an inverter device. The inverter device 51 includes a base metal plate 22, a resin case 24, IGBTs 30 and 32, diodes 31 and 33, a control circuit board 34, and a laminate described later, almost as in the second embodiment. It includes metal plates 54, 57 and the like. However, the laminated metal plates 54 and 57 are configured as a part of ceramic substrates 53 and 56 described later.
[0099]
Reference numeral 52 denotes a first ceramic substrate provided on the base metal plate 22 by means of, for example, soldering or bonding. The ceramic substrate 52 is, for example, a general-purpose laminated layer, as in the third embodiment. A metal layer 52B is laminated on both sides of the insulating ceramic layer 52A. The high-voltage-side IGBT 30 and the diode 31 are mounted on the base metal plate 22 via the ceramic substrate 52, and the collector C of the IGBT 30 is connected to the base metal plate 22 using a metal wire 52C.
[0100]
53 is a second ceramic substrate provided on the base metal plate 22, and the ceramic substrate 53 is used in place of the low-voltage-side laminated metal plate 25 and the insulating material 26 in the second embodiment, Metal layers 53B are laminated on both sides of the ceramic layer 53A serving as an insulating material.
[0101]
Reference numeral 54 denotes a laminated metal plate as a second metal plate formed by using the metal layer 53B on the surface side of the ceramic substrate 53. The laminated metal plate 54 is lowered by means such as soldering or ultrasonic bonding. The voltage terminal 55 is joined, and the low voltage terminal 55 protrudes outside the resin case 24.
[0102]
Reference numeral 56 denotes a third ceramic substrate provided on the base metal plate 22. The ceramic substrate 56 is used in place of the output-side laminated metal plate 28 and the insulating material 26 in the second embodiment to provide insulation. Metal layers 56B are laminated on both sides of the ceramic layer 56A as a material.
[0103]
Reference numeral 57 denotes a laminated metal plate as a third metal plate formed by using the metal layer 56B on the surface side of the ceramic substrate 56. The low voltage side IGBT 32 and the diode 33 are mounted on the laminated metal plate 57. The output terminal 58 is joined using a metal wire 58A or the like.
[0104]
Thus, in the present embodiment configured as described above, it is possible to obtain substantially the same operational effects as those of the second and third embodiments.
[0105]
Next, FIG. 11 shows a fifth embodiment according to the present invention. The feature of this embodiment is that the control circuit board is constituted by a plurality of boards. In the present embodiment, the same components as those in the first embodiment are denoted by the same reference numerals, and the description thereof is omitted.
[0106]
Reference numeral 61 denotes an inverter device. The inverter device 61 includes a base metal plate 2, a resin case 4, laminated metal plates 5 and 8, IGBTs 10 and 12, diodes 11 and 13, as described in the first embodiment. And the control circuit board 62 and the like.
[0107]
Reference numeral 62 denotes a control circuit board mounted in the resin case 4. The control circuit board 62 is disposed with a gap above the metal plates 2, 5, and 8 in substantially the same manner as in the first embodiment. , 12 is provided with a control circuit (not shown) for controlling the energization state.
[0108]
Further, the control circuit board 62 is constituted by, for example, three boards 63, 64 and 65. The largest upper substrate 63 among the substrates 63 to 65 is arranged so as to overlap the lower substrates 64 and 65 in the upper and lower directions, and these substrates 63 to 65 are provided with metal wires 62A and the like. Connected to each other. The gates G of the IGBTs 10 and 12 are connected to the lower substrates 64 and 65 using a metal wire 62B or the like.
[0109]
Thus, in the present embodiment configured as described above, it is possible to obtain substantially the same operational effects as those of the first embodiment. In particular, in the present embodiment, the control circuit board 62 is constituted by the boards 63, 64, and 65 that are separated from each other in the direction perpendicular to the metal plates 2, 5, and 8. Therefore, the entire area of the control circuit board 62 is reduced. Can be formed as a large. In particular, the upper substrate 63 can secure a large area as large as the base metal plate 2, so that the degree of freedom in designing the inverter device 61 can be increased.
[0110]
Next, FIG. 12 shows a sixth embodiment according to the present invention. The feature of this embodiment is that the inverter device is applied to an electric machine.
[0111]
Reference numeral 71 denotes an electric machine with an inverter mounted on a vehicle such as an automobile. The electric machine with an inverter 71 has a stepped cylindrical housing 72 which is an outer shell thereof. The housing 72 is an electric motor 75 described later. Is substantially constituted by a cylindrical motor case 72A that accommodates the transmission, a transmission case 72B that accommodates the automatic transmission 73, and a partition plate 72C that partitions the cases 72A and 72B.
[0112]
73 is an automatic transmission housed in a transmission case 72B of the housing 72. The automatic transmission 73 has an input shaft 74 connected to the engine side of the vehicle and an output shaft (not shown) connected to the wheel side. For example, the engine speed is changed in accordance with a driver's speed change operation or the like, and the changed speed is transmitted to the output shaft.
[0113]
Reference numeral 75 denotes a multi-phase AC electric motor provided in a motor case 72A of the housing 72. The electric motor 75 is fixed to the annular stator 75A fixed in the motor case 72A and the outer peripheral side of the input shaft 74. And a rotor 75B made of a magnet or the like. The electric motor 75 rotates the input shaft 74 by being supplied with power from an inverter device 76 to be described later, and causes the vehicle to travel in cooperation with, for example, an engine.
[0114]
Reference numeral 76 denotes an inverter device provided in the motor case 72A of the housing 72. The inverter device 76 is one of the inverter devices 1, 21, 41, 51, 61 used in the first to fifth embodiments. And has a base metal plate 77, a high voltage terminal 78, a low voltage terminal 79, an output terminal 80, and the like.
[0115]
Here, in the inverter device 76, for example, the base metal plate 77 is attached to the partition plate 72C of the housing 72 via an insulating material (not shown) having high thermal conductivity. Further, the high voltage terminal 78 and the low voltage terminal 79 are drawn out of the housing 72 through a notch groove 81 provided at the opening end of the motor case 72A, and these are connected to a vehicle battery or the like. Yes. In this case, the notch groove 81 of the motor case 72A is provided with a seal member 82 that seals the inside and outside of the case.
[0116]
The output terminal 80 of the inverter device 76 is connected to the electric motor 75 in the motor case 72A, and the electric motor 75 is driven by an alternating current using electric power such as a battery.
[0117]
Thus, in the present embodiment configured as described above, it is possible to obtain substantially the same operational effects as those of the first to fifth embodiments. In particular, in the present embodiment, a base metal plate 77 located on the back side of the inverter device 76 is attached to the partition plate 72C of the housing 72.
[0118]
In this case, since the high voltage terminal 78 and the low voltage terminal 79 protrude from a portion of the side surface of the inverter device 76 close to the base metal plate 77, a notch groove 81 is formed at the opening end of the motor case 72A. The terminals 78 and 79 can be easily pulled out of the housing 72 along the partition plate 72C. As a result, it is not necessary to form a through hole or the like in the conventional motor case 72A, and the inverter device 76 can be easily disposed in the housing 72 by simply performing a groove processing, and the seal member 82 and the like are mounted. Can also be performed smoothly.
[0119]
Further, even when a battery having a high voltage of, for example, about 42 V is mounted on a vehicle, a surge voltage can be obtained by interposing an insulating material between the base metal plate 77 of the inverter device 76 and the partition plate 72C of the housing 72. Thus, it is possible to reliably take measures against insulation and the like, and to easily apply to high-voltage vehicles.
[0120]
In each of the above embodiments, the three IGBTs 10 and 30 and the diodes 11 and 31 are mounted as the high voltage side elements, and the three IGBTs 12 and 32 and the diodes 13 and 33 are mounted as the low voltage side elements. As an example. However, in the present invention, the number of high-voltage side elements and low-voltage side elements is not limited to the embodiment. For example, two high-voltage side elements and two low-voltage side elements are arranged in parallel. Alternatively, four or more high-voltage side elements and four or more low-voltage side elements may be arranged in parallel.
[0121]
In the embodiment, the high-voltage side element and the low-voltage side element are constituted by the IGBTs 10, 12, 30, 32, the diodes 11, 13, 31, 33, and the like. However, the present invention is not limited to this. For example, a MOSFET or the like may be used as the high voltage side element or the low voltage side element.
[0122]
In particular, by using MOSFETs as the high-voltage side element and the low-voltage side element and using parasitic diodes existing in these MOSFETs instead of the diodes 11, 13, 31, 33, the diodes 11, 13, 31, 33 are used. The operational effects described in the first to sixth embodiments can also be obtained by such a circuit configuration.
[0123]
In the embodiment, the metal plates 2, 5, 8, 22, 25, 28, 43, 46, 54, 57, 77 and the terminals 3, 7, 9, 23, 27, 29, 44, 47, 55 , 58, 78, 79, 80 are formed integrally as necessary. However, the present invention is not limited to this, all these metal plates and terminals are formed as separate metal parts, or some of the metal plates and terminals are formed as separate metal parts, both are soldered, It is good also as a structure connected by means, such as wire bonding. As a result, even when stress or the like is applied to the terminal from the outside, this stress can be prevented from being transmitted into the inverter device, and damage to the device due to external force or the like can be prevented.
[0124]
Further, in the embodiment, the inverter devices 1, 21, 41, 51, 61, and 76 are described as examples of semiconductor devices. However, the present invention is not limited to this, and can of course be applied to various semiconductor devices that carry a large current.
[Brief description of the drawings]
FIG. 1 is a perspective view showing an inverter device according to a first embodiment of the present invention.
FIG. 2 is a cross-sectional view of the inverter device as viewed from the direction of arrows II-II in FIG.
FIG. 3 is a cross-sectional view of the inverter device viewed from the direction of arrows III-III in FIG.
FIG. 4 is a circuit diagram showing an entire inverter circuit including an inverter device.
FIG. 5 is an equivalent circuit diagram showing parasitic inductance caused by a metal plate or the like of the inverter device.
FIG. 6 is a characteristic diagram showing a state in which a negative surge voltage is generated due to parasitic inductance on the low voltage side.
FIG. 7 is a cross-sectional view showing an inverter device according to a second embodiment of the present invention.
8 is a cross-sectional view of the inverter device viewed from the direction of arrows VIII-VIII in FIG.
FIG. 9 is a cross-sectional view showing an inverter device according to a third embodiment of the present invention.
FIG. 10 is a cross-sectional view showing an inverter device according to a fourth embodiment of the present invention.
FIG. 11 is a cross-sectional view showing an inverter device according to a fifth embodiment of the present invention.
FIG. 12 is a cross-sectional view showing a state where an inverter device according to a sixth embodiment of the present invention is mounted on an electric machine.
[Explanation of symbols]
1, 1 ', 1 ", 21, 41, 51, 61, 76 Inverter device (semiconductor device)
2,22,77 Base metal plate (first metal plate)
3,27,55,79 Low voltage terminal
4,24 Resin case
5, 25, 43, 54 Laminated metal plate (second metal plate)
6,26 Insulation material
7,23,44,78 High voltage terminal
8, 28, 46, 57 Laminated metal plate (third metal plate)
9, 9 ', 9 ", 29, 47, 58, 80 Output terminal
10,30 IGBT (High-voltage side element)
11,31 Diode (High-voltage side element)
12, 32 IGBT (Low-voltage side element)
13,33 Diode (Low-voltage side element)
14, 34, 62 Control circuit board
16 Battery (Power)
42, 45, 52, 53, 56 Ceramic substrate
42A, 45A, 52A, 53A, 56A Ceramic layer (insulating material)
42B, 45B, 52B, 53B, 56B Metal layer
63, 64, 65 substrate
71 Electric machine with inverter
72 Housing
75 Electric motor
E Emitter (surface electrode)
C collector (back electrode)

Claims (7)

A first metal plate provided with a low voltage terminal connected to the low voltage side of the power supply;
A second metal plate provided on the surface side of the first metal plate via an insulating material and provided with a high voltage terminal connected to the high voltage side of the power source;
A third metal plate provided with an output terminal that is stacked via an insulating material on the surface side of the first metal plate at a position different from the second metal plate and outputs an electric current to the outside;
A plurality of high-voltage side elements formed of a semiconductor element having a front electrode and a back electrode, wherein the back electrode is arranged side by side on the second metal plate and the front electrode is connected to the third metal plate When,
A plurality of low-voltage side elements formed of a semiconductor element having a front electrode and a back electrode, wherein the back electrode is arranged side by side on the third metal plate and the front electrode is connected to the first metal plate When,
A control circuit board that controls the energization state of each high-voltage side element and each low-voltage side element,
A configuration in which a plurality of high voltage side elements arranged on the second metal plate and a plurality of low voltage side elements arranged on the third metal plate are arranged in parallel with each other on the first metal plate. A semiconductor device.   The low voltage terminal is formed integrally with the first metal plate, the high voltage terminal is formed integrally with the second metal plate, and the output terminal is formed integrally with the third metal plate. The semiconductor device according to claim 1. A first metal plate provided with a high voltage terminal connected to the high voltage side of the power supply;
A second metal plate provided on the surface side of the first metal plate via an insulating material and provided with a low voltage terminal connected to the low voltage side of the power source;
A third metal plate provided with an output terminal that is stacked via an insulating material on the surface side of the first metal plate at a position different from the second metal plate and outputs an electric current to the outside;
A plurality of high-voltage side elements formed by a semiconductor element having a front electrode and a back electrode, wherein the back electrode is arranged side by side on the first metal plate and the front electrode is connected to the third metal plate When,
A plurality of low voltage side elements formed by a semiconductor element having a front electrode and a back electrode, wherein the back electrode is arranged on the third metal plate and the front electrode is connected to the second metal plate When,
A control circuit board that controls the energization state of each high-voltage side element and each low-voltage side element,
A configuration in which a plurality of high-voltage side elements arranged on the first metal plate and a plurality of low-voltage side elements arranged on a third metal plate on the first metal plate are arranged in parallel with each other. A semiconductor device.   The high voltage terminal is formed integrally with the first metal plate, the low voltage terminal is formed integrally with the second metal plate, and the output terminal is connected to the third metal plate. The semiconductor device according to claim 3. The second, at least one of the metal plates of the third metal plate is formed of a metal layer secured to insulating ceramic layer, wherein become configured as the ceramic substrate and the ceramic layer and the metal layer according to claim 1 or the semiconductor device according to 3.   5. The high-voltage side element and the low-voltage side element are arranged together with an electric motor in a housing of an electric machine and constitute an inverter device that drives the electric motor with an alternating current. Or the semiconductor device according to 5;   7. The semiconductor device according to claim 1, wherein the high-voltage side element and the low-voltage side element are insulated gate bipolar transistors, MOS transistors, or bipolar transistors.

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