JP4764979B2 - Semiconductor device - Google Patents

Description

  The present invention relates to a semiconductor device used for a power conversion device such as an inverter device, and more particularly to a structure of a control terminal in a semiconductor device such as an IGBT (Insulated Gate Bipolar Transistor).

  In power electronics application devices such as general-purpose inverters, uninterruptible power supply devices, machine tools, and industrial robots, power modules are used as semiconductor devices. This power module is a module in which a power switching circuit combining a plurality of IGBTs and FWD (Free Wheeling Diode) is mounted in a case. For example, in a power module used for an inverter, a DC power input terminal and an output terminal serving as a main circuit and a control signal control terminal serving as a control circuit are provided outside the case. The control terminal is composed of a plurality of pins or plate-like tabs, one end of which is connected to an IGBT control electrode or the like inside the case, and an insulating terminal block holding these pins or tabs. It is mounted by methods such as secondary molding, adhesion, and screwing. In some cases, an IGBT drive circuit (IC or the like) is connected between the control terminal and the control electrode of the IGBT and stored in the case to constitute an IPM (Intelligent Power Module).

When such a power module is used by a user, the user attaches the main circuit to the device by screwing it to each terminal. In that case, for the control circuit, the board on which the control integrated circuit or the like is mounted is soldered directly to the pin or tab coming out of the terminal block, or the board connected to or attached to the board comes out of the terminal block. Connection with the control terminal of the power module is performed by inserting a pin or tab.
As described above, in the conventional semiconductor device, soldering or connector placement is required by the user side, and there is a great cost for wiring man-hours and component costs. In view of this, a semiconductor device having a structure in which the user does not solder the control terminal to the control circuit board outside the case to reduce the material of the product and the processing cost has been proposed (for example, Patent Document 1).

According to this semiconductor device, the control terminal is configured by a bellows-like spring or a coil spring, and the electrical connection between the control terminal and the external control circuit board is not applied by soldering, but the applied force utilizing the elastic force of the control terminal is used. This is done by pressure contact. In addition, the control terminal is held in the resin case by insert molding on the side wall of the resin case, and the connection between the control terminal and the case internal substrate that are concentrated on the side wall of the resin case is joined by a bonding wire. ing.
JP 2001-144249 A (paragraph numbers [0024] to [0025], FIG. 3)

However, in the conventional semiconductor device, all the control terminals are insert-molded on the side wall of the resin case, and the arrangement position of the control terminals is limited to the vicinity of the outer periphery of the resin case. Even if it is arranged and the wiring to the external control circuit board is to be the shortest distance, the wiring from the interconnection position to at least the side wall position on the external control circuit board connected by the control terminal as well as the in-case board. Need to be routed. Therefore, there is a problem in that the degree of freedom in the layout of the control terminals and the layout of the wiring is low.
The present invention has been made in view of the above points, and an object of the present invention is to make it possible to freely set an arrangement position of a spring terminal in a semiconductor device using a spring terminal as a control terminal.

  In the present invention, in order to solve the above problem, a power semiconductor element bonded to a circuit pattern of an insulating substrate, a control terminal (spring terminal) for leading a control electrode of the power semiconductor element to the outside, and the power semiconductor element A semiconductor device comprising: a case for housing; and a cover that covers an opening of the case and that includes a terminal housing portion for housing the control terminal. The control terminal is a terminal lead-out port of the terminal housing portion. A coil portion having one end led out from the outside in pressure contact with an external control circuit board, a linear portion formed integrally with the other end of the coil portion and extending in the same axial direction as the coil portion, and the straight line A joint portion that is integrally formed with the linear portion and joined to the circuit pattern of the substrate at the end opposite to the side that is connected to the coil portion, and the coil portion of the control terminal is one A first coil portion having a small diameter in pressure contact with an external control circuit board, and a second coil having a larger outer diameter than the first coil portion, formed integrally with the other end of the first coil portion in the same axial direction. And the control terminal is held so as not to be detached from the terminal accommodating portion by forming the terminal outlet of the terminal accommodating portion with a diameter smaller than the outer diameter of the second coil portion. A semiconductor device is provided.

In such a semiconductor device, the spring terminal is supported by the frame or the terminal accommodating portion of the cover. Thereby, a spring terminal can be arrange | positioned in arbitrary positions inside a case side wall.

In the semiconductor device of the present invention, since the connection with the external control circuit board is ensured by the elastic force of the spring terminal, electrical connection with the external control circuit board is possible without using solder. Can be attached and detached freely and easily.
In addition, since the spring terminal can be arranged at an arbitrary position inside the case side wall, the wiring with the external control circuit board connected by the spring terminal can be made the shortest distance, and the induction noise due to the routing of the wiring There is an advantage that the influence of can be reduced.

Hereinafter, an embodiment in which the present invention is applied to a semiconductor device (for example, an IGBT power module) will be described in detail with reference to the drawings.
(Embodiment 1)
FIG. 2 is a cross-sectional view showing a mounting state of the control terminal in the semiconductor device according to the first embodiment, and FIG. 3 is an enlarged detailed view showing the control terminal of FIG.
As shown in FIG. 1, the IGBT power module 1 incorporates a semiconductor element such as an IGBT 13, an in-case substrate 2, and the like as a power semiconductor part in a case 2 constituting an outer frame. The lower part of the case 2 is airtightly joined to a heat dissipation base 11 which will be described later, and the upper part becomes an opening and is covered with a cover 7. The DC power input terminals 3 and 4 and the power output terminals 5 and 6 are integrated in the case 2, and a control signal control terminal (hereinafter referred to as a spring terminal 8) is provided on the cover 7. It is led out from the terminal lead-out port.

  In the case 2 of the IGBT power module 1, as shown in FIG. 2, a circuit pattern of a substrate 12 in the case in which ceramic is used as a base material and a copper plate is attached to the back surface on a base 11 for heat dissipation. Is mounted with a semiconductor element such as IGBT or FWD (not shown) to constitute a power semiconductor portion. The back electrode of the IGBT 13 or FWD is bonded to the circuit pattern on the in-case substrate. The electrode formed on the front surface of the IGBT 13 or FWD and the circuit pattern are connected by a wire 14. One end of the spring terminal 8 is joined to a circuit pattern connected to the control signal electrode of the power semiconductor portion, specifically, the gate electrode of the IGBT 13. They are joined by soldering or conductive adhesive. Since the upper portion of the case 2 is an opening, it is easy to place and join the spring terminals 8 at predetermined locations in the circuit pattern. After soldering the spring terminals or joining with a conductive adhesive, the cover 7 covers the opening of the case 2.

Further, the main electrode of the power semiconductor portion, specifically, the collector electrode and emitter electrode of the IGBT 13, the anode electrode and the cathode electrode of the FWD are corresponding main terminals 25 (reference numerals 3, 4 and 4 in FIG. 1). 5, 6). The main electrode of the power semiconductor part and the main terminal 25 are connected by the wire 14. Or you may join the main terminal 25 to the circuit pattern 12 to which the main electrode of the power semiconductor part was connected.
Here, the semiconductor device may be configured as an IPM in which the drive circuit of the IGBT 13 is incorporated in the IGBT module 1. The drive circuit receives a control signal from an external control circuit board and outputs a drive signal to the gate electrode of the IGBT 13. In the IPM, a drive circuit is connected between the IGBT 13 and the spring terminal 8. That is, one end of the drive circuit is connected to the circuit pattern to which the spring terminal 8 is joined. Here, each of the plurality of spring terminals 8 is accommodated in a terminal accommodating portion 16 formed in the cover 7 which is a resin molded part. Further, the upper end surface of the main electrode 25 in the case 2 is configured to be positioned at the same height as the board fastening screw hole 9.

In the cover 7, a terminal accommodating portion 16 is integrally formed of resin at a position where the spring terminal 8 is disposed. As will be described later, the spring terminal 8 includes coil portions having different outer diameters. Further, the terminal accommodating portion 16 of the cover 7 is formed such that the terminal outlet 16 a is smaller than the outer diameter of the large coil portion of the spring terminal 8. Accordingly, the spring terminal 8 is held in the terminal accommodating portion 16 so as not to be detached from the case 2 while protruding from the board contact surface 17 of the external control circuit board 26 by the amount of spring deflection A.
Further, a plurality of screw holes 9 for fastening the substrate and a plurality of positioning pins 10 are formed at predetermined positions inside the case 2. On the user side, the external control circuit board 26 is positioned by these positioning pins 10, and then fastened to the IGBT power module 1 by using the screw holes 9 with reference to the board contact surface 17. In the IGBT power module 1, the spring terminal 8 serves as a control terminal for a control signal. The coil portion of the spring terminal 8 is compressed to the spring set length B by the control circuit board 26. Here, the length of the bending allowance A of the spring terminal 8 is defined by the height of the board fastening screw hole 9 provided in the case 2, that is, the position of the board contact surface 17. Thereby, the energization part load of the spring terminal 8 can be appropriately maintained only by screwing an external control circuit board to the IGBT power module 1 on the user side. Further, after the board is fastened, excessive pressing from the control circuit board 26 to the in-case board 12 via the spring terminal 8 is avoided, and an appropriate contact state can be secured. Further, soldering of an external control circuit board on the user side or arrangement of a connector becomes unnecessary.

As shown in FIG. 3, the spring terminal 8 includes a first coil portion 20 a having a contact terminal surface 19 whose upper end in the drawing is in direct pressure contact with an external control circuit board 26, and the other end of the first coil portion 20 a. And a coil portion 20 formed of the second coil portion 20b having a larger outer diameter than the first coil portion 20a. The coil portion 20 is integrally formed at the lower end of the coil portion 20 and has the same axis as the coil portion 20. A linear portion 21 extending in the direction, and a soldering portion 22 formed integrally with the lower end portion of the linear portion 21 and soldered to the electrode of the in-case substrate.
The first coil portion 20 a of the spring terminal 8 is accommodated in the terminal outlet 16 a of the terminal accommodating portion 16, and the second coil portion 20 b is accommodated in the opening 7 a formed in the cover 7. The terminal outlet 16a and the opening 7a are formed on the same axis, and since the diameter of the opening 7a is larger than the terminal outlet 16a, a step 16b is formed on the connection surface. Therefore, when the external control circuit board 26 is fastened to the case 2 of the IGBT power module 1, the coil portion 20 of the spring terminal 8 bends. Thereby, the contact terminal surface 19 of the spring terminal 8 is press-contacted with the circuit arrange | positioned at the external control circuit board 26 side by appropriate spring force, and the electrical conductivity can be ensured.

The side opposite to the contact terminal surface 19 of the spring terminal 8 is constituted by a linear portion 21 having a linear shape for ensuring conduction in the in-case substrate 12. The straight line portion 21 has a distance to the in-case substrate 12, and the soldering portion 22 is joined to the electrodes of the in-case substrate 12 by soldering.
Here, since the external control circuit board 26 is normally prepared on the user side, the coil portion 20 of the spring terminal 8 is handled in a state where the coil portion 20 of the spring terminal 8 protrudes by the amount of spring deflection A. Therefore, in the conventional IGBT power module 1, since the contact terminal surface 19 of the spring terminal 8 is pulled and stress is generated during the handling or the mounting operation of the control circuit board 26, the soldering portion 22 and the in-case board There was a possibility that a problem would occur in the state of fixing with No. 12.

In the first embodiment, a step 16b is formed on the joint surface between the cover 7 and the terminal accommodating portion 16 formed therein, and the spring terminal 8 is not detached from the case 2 by the second coil portion 20b. Therefore, even when the contact terminal surface 19 of the spring terminal 8 is pulled, there is an effect that does not affect the fixing state with the in-case substrate 12.
Further, a deformed portion is formed at a portion where the spring terminal is covered with the solder or the conductive adhesive at a portion where the spring terminal 8 and the circuit pattern of the substrate are joined with the solder or the conductive adhesive. The deformed portion may be a deformed end portion of the straight portion of the spring terminal, and may be an L shape, an arc shape, or a shape in which the end portion is crushed. As described above, when configured as a shape other than the linear shape, even when a pulling force is applied to the joint portion, the spring terminal 8 is difficult to come off, and a good fixed state with the in-case substrate 12 can be maintained.

In addition, when soldering and joining the spring terminal 8 and the substrate 12 in the case, heating at two hundred and several tens of degrees Celsius is necessary, and the spring terminal 8 is in an annealed state by receiving a thermal history. There is a case. On the other hand, if a thermosetting conductive adhesive is used, the heating temperature for curing may be several hundreds of degrees Celsius. Therefore, the thermosetting conductive adhesive does not require high-temperature heat treatment, and is advantageous in that the original spring property of the spring terminal 8 is not lost.
(Embodiment 2)
FIG. 1 is a plan view showing an external appearance of an IGBT power module as a semiconductor device according to the present invention, FIG. 4 is a cross-sectional view showing a mounting state of a control terminal in a semiconductor device according to Embodiment 2, and FIG. 5 is a control terminal of FIG. FIG. 6 is a cross-sectional view taken along the line aa in FIG.

  As shown in FIG. 1, the IGBT power module 1 incorporates a semiconductor element such as an IGBT 13, an in-case substrate 2, and the like as a power semiconductor part in a case 2 constituting an outer frame. As described above, the lower portion of the case 2 is airtightly joined to the heat radiating base 11, and the upper portion is an opening and is covered with the cover 7. The DC power input terminals 3 and 4 and the power output terminals 5 and 6 are integrated into the case 2, and the spring terminal 8 is led out through the cover 7 (terminal outlet). Yes. The case 2 includes a screw hole 9 and a pin 10. On the user side, the control circuit board is positioned outside the IGBT power module 1 by the pin 10 provided integrally with the cover 7, and the control circuit board is fastened to the screw hole 9. In this IGBT power module 1, since the spring terminal 8 serves as a control terminal for the control signal, the load on the current-carrying part of the spring terminal 8 can be appropriately set by simply screwing the external control circuit board to the IGBT power module 1 on the user side. Can be maintained. Further, soldering of an external control circuit board on the user side or arrangement of a connector becomes unnecessary.

  As shown in FIG. 4, the inside of the IGBT power module 1 includes a base 11 for heat dissipation, on which a ceramic is used as a base material, and a copper plate is attached to the back surface of the in-case substrate 12. A circuit pattern is formed on the front surface. A semiconductor element such as IGBT 13 or FWD (not shown) is mounted on the circuit pattern of the in-case substrate 12 to constitute a power semiconductor portion. The electrodes formed on the back surface of the IGBT 13 or FWD are bonded to the circuit pattern on the in-case substrate, and the electrodes formed on the front surface and the circuit pattern are connected by a wire 14. One end of the spring terminal 8 is joined to the circuit pattern connected to the control signal electrode of the power semiconductor part, specifically, the gate terminal of the IGBT 13 by soldering or a conductive adhesive. Here, the semiconductor device may be configured as an IPM in which the drive circuit of the IGBT 13 is incorporated in the IGBT power module 1. The drive circuit receives a control signal from an external control circuit board and outputs a drive signal to the gate of the IGBT 13. In the IPM, a drive circuit is connected between the IGBT 13 and the spring terminal 8. That is, one end of the drive circuit is connected to the circuit pattern to which the spring terminal 8 is soldered.

A frame 15 is disposed inside the cover 7, and the frame 15 has a terminal housing portion 16 integrally formed of resin at a position where the spring terminal 8 is disposed. The spring terminal 8 is held in the terminal accommodating portion 16 of the frame 15 in a state protruding from the board contact surface 17 of the external control circuit board by the amount of spring deflection A. Accordingly, when an external control circuit board (not shown) is positioned by the positioning pins 10 and then fastened to the IGBT power module 1 with the board contact surface 17 as a reference by the board fastening screw hole 9, external control is performed. It is compressed to the spring set length B by the circuit board.
Here, the board contact surface 17 of the control circuit board need only be at a high position of the terminal accommodating portion 16 of the frame 15 and does not necessarily have to coincide. The length of the bending allowance A of the spring terminal 8 is defined by the height of the board fastening screw hole 9 provided in the case 2, that is, the position of the board contact surface 17. Thereby, excessive pressing from the control circuit board to the frame 15 via the spring terminal 8 is avoided.

The frame 15 is also formed, for example, in a lattice shape as a whole and has a large number of openings 18. These openings 18 allow access to the joints between the spring terminals 8 and the control signal electrodes of the drive circuit mounted on the in-case substrate 12 with the frame 15 installed in the case. . That is, the soldering iron, hot gas, ultraviolet light, and the like can be accessed from the opening 18, and joining by solder or a conductive adhesive is possible.
As shown in FIG. 5, the spring terminal 8 is formed integrally with a coil part 20 having a contact terminal surface 19 whose upper end is directly pressed against an external control circuit board, and a lower end of the coil part 20. The straight portion 21 extending in the same axial direction as the coil portion 20 and the soldering portion 22 that is integrally formed at the lower end portion of the straight portion 21 and is soldered to the electrode of the in-case substrate. .

The terminal accommodating portion 16 of the frame 15 in which the coil portion 20 of the spring terminal 8 is accommodated has a tapered spring terminal pressure receiving portion 23 with which the lower end portion of the coil portion 20 abuts. Therefore, when the external control circuit board is fastened to the IGBT power module 1, the coil part 20 of the spring terminal 8 is arranged on the external control circuit board side by bending with respect to the spring terminal pressure receiving part 23. The contact terminal surface 19 is brought into pressure contact with an appropriate circuit by an appropriate spring force, and electrical conductivity is ensured.
Further, the side of the spring terminal 8 opposite to the contact terminal surface 19 is constituted by a linear portion 21 having a linear shape for ensuring conduction in the in-case substrate 12. The straight portion 21 has a length that is a distance to the in-case substrate 12 and is joined to the electrodes of the in-case substrate 12 by soldering. Further, the linear portion 21 is disposed on the same axis as the coil portion 20 in order to eliminate the rotation direction when the spring terminal 8 is inserted into the terminal accommodating portion 16 of the frame 15. And the soldering part 22 is made into the ring-shaped structure in order to earn a joining area in consideration of heat fatigue resistance.

Here, when the soldering portion 22 of the spring terminal 8 is joined to the electrode of the in-case substrate 12, the linear portion 21 of the spring terminal 8 is interposed between the spring terminal pressure receiving portion 23 and the electrode of the in-case substrate 12. Will be placed. Moreover, one end of the linear portion 21 is fixed to the electrode of the in-case substrate 12 by solder bonding, and the other end is constrained by the spring terminal pressure receiving portion 23.
However, since the IGBT power module 1 uses a heat-resistant ceramic as a base material as an insulating material of the in-case substrate 12, the linear expansion coefficient is different from that of the base 11 to which this is soldered. For this reason, when the IGBT power module 1 is operating and generates heat, the base 11 is warped due to the difference in coefficient of linear expansion between the two soldered. When warping occurs in the base 11, relative displacement occurs between the soldering portion 22 of the spring terminal 8 and the spring terminal pressure receiving portion 23 of the terminal accommodating portion 16, and the linear portion 21 and the soldering portion 22 of the spring terminal 8. Stress is generated. In particular, the spring terminal 8 disposed near the center of the base 11 has a large relative displacement, and in some cases, a displacement of several hundred μm, and a large stress is generated in the soldering portion 22 of the spring terminal 8, This leads to a decrease in reliability.

The stress on the soldering portion 22 generated by such repeated thermal cycles is eliminated by making the spring terminal pressure receiving portion 23 into a tapered shape. That is, since the spring terminal pressure receiving portion 23 is tapered, only the outer peripheral portion of the coil portion 20 of the spring terminal 8 is supported by the spring terminal pressure receiving portion 23. As shown in FIG. 6, there is a connection part 24 for connecting them between the coil part 20 and the straight part 21, and the spring property of this connection part 24 depends on the joint part of the soldering part 22 and the spring terminal. Since the relative displacement generated between the pressure receiving portion 23 and the pressure receiving portion 23 is absorbed, the stress applied to the joint portion of the soldering portion 22 can be relaxed.
In the above-described embodiment, the case where the spring terminal pressure receiving portion 23 is formed in a tapered shape has been described as an example in order to allow the connecting portion 24 to be deformed in the axial direction of the straight portion 21. Since only the outer peripheral portion of the coil portion 20 needs to be supported by the spring terminal pressure receiving portion 23, the spring terminal pressure receiving portion 23 is formed in a stepped shape so as to support only the outer peripheral portion of the coil portion 20. May be.

FIG. 7 is a detailed view showing a state in which the control terminal of FIG. 3 is positioned by the frame.
The frame 15 is used to position the spring terminal 8 and, like the second embodiment, is entirely formed in a lattice shape, for example, and has a large number of openings. These openings allow access to the joint between the spring terminal 8 and the control signal electrode of the drive circuit mounted on the in-case substrate 12 with the frame 15 installed in the case. That is, a soldering iron, hot gas, ultraviolet light, or the like can be accessed from the opening 18, and joining by solder or a conductive adhesive is possible.
The lower end portion of the second coil portion 20b of the spring terminal 8 is brought into contact with the tapered spring terminal pressure receiving portion 23 of the frame 15, and the coil portion 20 is bent when the external control circuit base 26 is fastened to the case 2. It becomes the standard.

Therefore, the spring terminal pressure receiving portion 23 can be eliminated with respect to the stress on the soldering portion 22 generated by the above-described thermal cycle.
In each of the above examples, the portion joined by solder or a conductive adhesive can be replaced with another joining material such as a brazing material or another joining method.

It is a top view which shows the external appearance of the semiconductor device by this invention. FIG. 3 is a cross-sectional view showing a state where a control terminal is attached in the semiconductor device according to the first embodiment. FIG. 3 is an enlarged detailed view showing a control terminal of FIG. 2. FIG. 10 is a cross-sectional view showing a state where a control terminal is attached in the semiconductor device according to the second embodiment. FIG. 5 is an enlarged detailed view showing a control terminal of FIG. 4. FIG. 6 is a cross-sectional view taken along the line aa in FIG. 5. FIG. 4 is a detailed view showing a state where the control terminal of FIG. 3 is further positioned by a frame.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 IGBT power module 2 Case 3, 4, 5, 6 Terminal 7 Cover 7a Opening 8 Spring terminal 9 Screw hole 10 Pin 11 Base 12 Case substrate 13 IGBT
14 Wire 15 Frame 16 Terminal accommodating portion 16a Terminal outlet 16b Step 17 Substrate contact surface 18 Opening portion 19 Contact terminal surface 20 Coil portion 20a First coil portion 20b Second coil portion 21 Linear portion 22 Soldering portion 23 Spring terminal pressure receiving portion 24 connection part 25 main electrode 26 control circuit board

Claims (5)

A power semiconductor element bonded to a circuit pattern of an insulating substrate; a control terminal for leading out a control electrode of the power semiconductor element; a case for housing the power semiconductor element; and the control terminal covering an opening of the case In a semiconductor device provided with a cover in which a terminal accommodating portion for accommodating
The control terminal is formed integrally with a coil part whose one end led out from the terminal lead-out port of the terminal accommodating part is in pressure contact with an external control circuit board, and the other end of the coil part. A linear portion that extends in the same axial direction as the linear portion, and a joint portion that is integrally formed with the linear portion at the end of the linear portion that is opposite to the side that is connected to the coil portion, and that is joined to the circuit pattern of the substrate. Have
The coil portion of the control terminal is formed in the same axial direction integrally with the first coil portion having a small diameter, one end of which is in pressure contact with an external control circuit board, and the other end of the first coil portion. A second coil portion having a larger outer diameter than the coil portion,
The semiconductor device is characterized in that the control terminal is held so as not to be detached from the terminal accommodating portion by forming a terminal outlet of the terminal accommodating portion with a diameter smaller than the outer diameter of the second coil portion. .   The joint portion of the control terminal is joined to the circuit pattern of the substrate with solder or a conductive adhesive, and a deformed portion is formed at a place covered with the solder or the conductive adhesive. The semiconductor device according to claim 1.   3. The semiconductor device according to claim 2, further comprising: a frame that has a terminal accommodating portion in the case, holds the coil portion by the terminal accommodating portion, and positions the control terminal. The terminal housing portion of the frame includes a spring terminal pressure receiving portion that serves as a reference for bending of the coil portion when the case and the external control circuit board are fastened, and the bending stress in the coil portion of the control terminal is measured. The semiconductor device according to claim 3, wherein the semiconductor device is supported by the spring terminal pressure receiving portion. The semiconductor device according to claim 4, wherein the terminal pressure receiving portion is formed in a tapered shape.

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