JP5391162B2 - Power semiconductor device - Google Patents

Description

  The present invention relates to a power semiconductor device, and particularly to a power semiconductor device using a SiC semiconductor element.

A power semiconductor device including a switching element and a diode element connected in reverse parallel to the switching element is widely used in a power converter that performs DC-AC conversion and DC-DC conversion.
In conventional power semiconductor devices, silicon elements (referred to as Si elements) have been used as switching elements and diode elements. Recently, power elements using silicon carbide elements (referred to as SiC elements) have been used. Development of semiconductor devices has been promoted.

A power semiconductor device using a SiC element has characteristics such as a low loss, high temperature operation, and a high breakdown voltage as compared with a Si element. Therefore, the power semiconductor device can be reduced in size and loss. Therefore, the power converter formed of the power semiconductor device using the SiC element can realize downsizing of the cooler and high efficiency of the power converter.
These effects can be obtained by using a SiC element for both the switching element and the diode element, but can also be obtained by using a SiC element for any one of the elements.
Therefore, a power semiconductor device in which the switching element is a Si element and the diode element is a SiC element has been devised (see, for example, Patent Document 1).

JP 2004-095670 A (page 10, page 12, FIG. 8, FIG. 10)

A diode element using an SiC element (referred to as an SiC diode element) can operate at a high temperature because of its small loss. However, when used in a power semiconductor device, consideration must be given to heat generated from the SiC diode element.
In the conventional power semiconductor device, due to the limitation of the intrinsic semiconductor temperature of the Si element, the upper limit of the use temperature is set to about 150 ° C., and the circuit design is made so as not to exceed this, the configuration of the power semiconductor device A material having a heat resistant temperature of about 200 ° C. could be used.
On the other hand, in a power semiconductor device using a SiC diode element, in order to realize a high temperature operation (200 ° C. or more), which is one of the characteristics of the SiC diode element, insulation between the bonding material and the power semiconductor device is required. It is essential to increase the heat resistance of materials used for power semiconductor devices, such as sealing materials to be maintained.

  However, in the power semiconductor device using the SiC diode element described in Patent Document 1, the substrate on which the Si switching element is mounted and the substrate on which the plurality of SiC diode elements are mounted are housed in the same package, In order to realize high temperature operation of the SiC diode element, which is filled with a heat conducting gel, a material having high heat resistance is required for a power semiconductor device, and there is a problem that the cost increases. there were. On the contrary, when a conventional heat-resistant material is used for the power semiconductor device, there is a problem that the high-temperature operation of the SiC diode element is sacrificed.

Also, when switching elements using Si elements (referred to as Si switching elements) and SiC diode elements are mounted on the same substrate, optimizing component arrangement to avoid thermal interference from the SiC diode elements to the Si switching elements Is required.
Further, in order to cool the Si switching element from the back surface of the substrate, a SiC diode element that does not need to be cooled deprives the heat capacity of the heat sink and lowers the cooling efficiency, so that a large cooler is required.
And the semiconductor device for electric power using the SiC diode element of patent document 1 is the board | substrate which mounts the Si element, and the board | substrate which mounts an SiC element joined to the same metal base, and needs cooling There is the above-mentioned problem that a large-sized cooler is unnecessary because the SiC diode element without the heat sink takes away the heat capacity of the heat sink and lowers the cooling efficiency.

Furthermore, when a plurality of small and small-capacity SiC diode elements are connected in parallel to replace a large and large-capacity element, the demerit that the manufacturing process of wiring and the like becomes complicated and a predetermined interval between the elements There is a demerit that the mounting area becomes large.
For this reason, even when a SiC element is used only for the diode element, the specifications are completely different from the configuration of the conventional power semiconductor device, and it takes a long time to increase the cost and develop the power semiconductor device. There was a problem.

  The present invention has been made to solve the above-described problems, and the purpose thereof is to use the same heat-resistant member as used in a conventional power semiconductor device using only Si elements. The cost increase is suppressed, and an excessively large cooler is unnecessary, the device can be downsized, and the structure of the conventional power semiconductor device using only the Si element can be used as it is. The object is to obtain a power semiconductor device equipped with a wide gap semiconductor element such as an SiC element, which is short in cost and has a short development period and can be applied to various configurations.

  A first power semiconductor device according to the present invention includes a base plate, an insulating substrate bonded to one surface of the base plate and provided with a circuit conductor pattern, an Si switching element mounted on the insulating substrate, An element package mounted on an insulating substrate and encapsulating a plurality of wide band gap semiconductor elements with an element sealing material; and a base plate, and at least a Si switching element, an element package, and an insulating substrate A power semiconductor device comprising a case containing a case and a case sealing material filled in the case, wherein the Si switching element and the element package are mounted on a circuit conductor pattern on the same insulating substrate The electrode of the Si switching element and the electrode of the wide band gap semiconductor element are electrically connected to the circuit conductor pattern, and the element sealing material In which Rudo resin was used.

  A second power semiconductor device according to the present invention includes a base plate, an insulating substrate bonded to one surface of the base plate and provided with a circuit conductor pattern, an Si switching element mounted on the insulating substrate, A device package mounted on an insulating substrate and encapsulating a plurality of wide band gap semiconductor devices with a device sealing body; and a base plate, and at least a Si switching device, a device package, and an insulating substrate A power semiconductor device comprising a case containing a case and a case sealing material filled in the case, wherein the Si switching element and the element package are mounted on a circuit conductor pattern on the same insulating substrate The electrode of the Si switching element and the electrode of the wide band gap semiconductor element are electrically connected to the circuit conductor pattern, and the element sealing body is formed. In which the ceramic casing were used.

  A third power semiconductor device according to the present invention is joined to a base plate, an insulating substrate bonded to one surface of the base plate and provided with a circuit conductor pattern, and a circuit conductor pattern of the insulating substrate. Si switching element, element package mounted on the surface of the base plate where the insulating substrate is bonded, a plurality of wide band gap semiconductor elements sealed with element sealing material, and covered with the base plate And a power semiconductor device comprising at least a case for accommodating the Si switching element, the element package, and the insulating substrate, and a case sealing material filled in the case, wherein the element package has a wide width. The surface of one heat spreader joined to the band gap semiconductor element is exposed from the side facing the base plate, and the exposed surface of the heat spreader and the base plate are In addition, a heat transfer portion having electrical insulation is provided in contact with the exposed surface of the heat spreader and the base plate, and the electrode of the Si switching element and the electrode of the wide band gap semiconductor element are electrically connected to the circuit conductor pattern. Conduction is performed, and a mold resin is used as the element sealing material.

  A first power semiconductor device according to the present invention includes a base plate, an insulating substrate bonded to one surface of the base plate and provided with a circuit conductor pattern, an Si switching element mounted on the insulating substrate, An element package mounted on an insulating substrate and encapsulating a plurality of wide band gap semiconductor elements with an element sealing material; and a base plate, and at least a Si switching element, an element package, and an insulating substrate A power semiconductor device comprising a case containing a case and a case sealing material filled in the case, wherein the Si switching element and the element package are mounted on a circuit conductor pattern on the same insulating substrate The electrode of the Si switching element and the electrode of the wide band gap semiconductor element are electrically connected to the circuit conductor pattern, and the element sealing material It is made of molded resin, and the sealing material for the element becomes a heat insulating material, and the heat of the wide band gap semiconductor element is suppressed from being transferred to the case, the sealing material for the case, the insulating substrate, and the base plate. Therefore, it is possible to use a member having a heat resistance level of a conventional power semiconductor device having a Si element, and the cost of the device can be suppressed. Further, an unnecessarily large cooler is unnecessary, and the apparatus can be downsized. In addition, a structure similar to that of a conventional Si element power semiconductor device can be adopted, and the development period can be shortened and the configuration can be diversified.

  A second power semiconductor device according to the present invention includes a base plate, an insulating substrate bonded to one surface of the base plate and provided with a circuit conductor pattern, an Si switching element mounted on the insulating substrate, A device package mounted on an insulating substrate and encapsulating a plurality of wide band gap semiconductor devices with a device sealing body; and a base plate, and at least a Si switching device, a device package, and an insulating substrate A power semiconductor device comprising a case containing a case and a case sealing material filled in the case, wherein the Si switching element and the element package are mounted on a circuit conductor pattern on the same insulating substrate The electrode of the Si switching element and the electrode of the wide band gap semiconductor element are electrically connected to the circuit conductor pattern, and the element sealing body is formed. A ceramic housing is used, and the element sealing body becomes a heat insulating part, and the heat of the wide band gap semiconductor element is transferred to the case, the case sealing material, the insulating substrate, and the base plate. Therefore, the heat resistant member of the power semiconductor device of the conventional Si element can be used, and the cost of the device can be suppressed. Further, an unnecessarily large cooler is unnecessary, and the apparatus can be downsized. In addition, a structure similar to that of a conventional Si element power semiconductor device can be adopted, and the development period can be shortened and the configuration can be diversified.

  A third power semiconductor device according to the present invention is joined to a base plate, an insulating substrate bonded to one surface of the base plate and provided with a circuit conductor pattern, and a circuit conductor pattern of the insulating substrate. Si switching element, element package mounted on the surface of the base plate where the insulating substrate is bonded, a plurality of wide band gap semiconductor elements sealed with element sealing material, and covered with the base plate And a power semiconductor device comprising at least a case for accommodating the Si switching element, the element package, and the insulating substrate, and a case sealing material filled in the case, wherein the element package has a wide width. The surface of one heat spreader joined to the band gap semiconductor element is exposed from the side facing the base plate, and the exposed surface of the heat spreader and the base plate are In addition, a heat transfer portion having electrical insulation is provided in contact with the exposed surface of the heat spreader and the base plate, and the electrode of the Si switching element and the electrode of the wide band gap semiconductor element are electrically connected to the circuit conductor pattern. In this case, a mold resin is used as the element sealing material, and heat from the wide band gap semiconductor element can be directly transferred to the base plate, improving heat dissipation to the base plate of the element package. Therefore, even when the amount of heat generated from the wide band gap semiconductor element is particularly large, the element package can be prevented from exceeding the heat resistance temperature.

1 is a schematic side sectional view of a power semiconductor device according to a first embodiment of the present invention. FIG. 3 is a schematic top view showing a state in which a main electrode, a control terminal, a case, and a case sealing material are removed from the power semiconductor device according to the first embodiment of the present invention. It is a cross-sectional schematic diagram of the diode package used for the electric power semiconductor device concerning Embodiment 1 of this invention. It is a cross-sectional schematic diagram of the diode package used for the power semiconductor device concerning Embodiment 2 of this invention. It is a cross-sectional schematic diagram of the diode package used for the power semiconductor device concerning Embodiment 3 of this invention. It is a cross-sectional schematic diagram of the diode package which provided the heat spreader only in one electrode surface of the SiC diode element used for the power semiconductor device concerning Embodiment 3 of this invention. It is a perspective schematic diagram of the heat spreader which used the isotropic heat conductive material and anisotropic heat conductive material used for a diode package. It is a cross-sectional schematic diagram of the diode package used for the power semiconductor device concerning Embodiment 4 of this invention. It is a cross-sectional schematic diagram (a) of the diode package used for the power semiconductor device concerning Embodiment 5 of this invention, and a perspective schematic diagram (b) which shows the lamination | stacking state of a heat spreader, a lead frame, and a SiC diode element. . It is a cross-sectional schematic diagram of the diode package used for the power semiconductor device concerning Embodiment 6 of this invention. It is a cross-sectional schematic diagram of the diode package used for the power semiconductor device concerning Embodiment 7 of this invention. It is a cross-sectional schematic diagram of the diode package used for the power semiconductor device concerning Embodiment 8 of this invention. It is a cross-sectional schematic diagram of the diode package used for the power semiconductor device concerning Embodiment 9 of this invention. It is a cross-sectional schematic diagram of the diode package used for the power semiconductor device concerning Embodiment 10 of this invention. In the power semiconductor device concerning Embodiment 10 of this invention, it is a top schematic diagram which shows the state except the main electrode, the control terminal, the case, and the case sealing material. It is a cross-sectional schematic diagram of the diode package used for the power semiconductor device concerning Embodiment 11 of this invention. It is a side surface cross-section schematic diagram of the power semiconductor device concerning Embodiment 12 of this invention. In the power semiconductor device concerning Embodiment 12 of this invention, it is an upper surface schematic diagram which shows the state except the main electrode, the control terminal, the case, and the case sealing material. In the power semiconductor device concerning Embodiment 12 of this invention, it is a schematic diagram which shows the heat-transfer part of the 1st structure provided between the exposed surface of the heat spreader of a diode package, and a base plate. It is a figure which shows the heat-transfer part of the 2nd structure provided between the exposed surface of a heat spreader of a diode package, and a base plate in the power semiconductor device concerning Embodiment 12 of this invention.

  Hereinafter, preferred embodiments of a power semiconductor device according to the present invention will be described with reference to the drawings.

Embodiment 1 FIG.
FIG. 1 is a schematic side sectional view of a power semiconductor device according to Embodiment 1 of the present invention.
A power semiconductor device 100 according to the first embodiment of the present invention is a power semiconductor device including a Si switching element 5 and a diode package 6, and is formed on one plane of a base plate 1 as shown in FIG. The surface of the insulating substrate 2 provided with the conductor pattern 4b is joined with solder (not shown) or the like. A circuit conductor pattern 4a serving as a current path is formed on the surface of the insulating substrate 2 opposite to the surface on which the conductor pattern 4b is provided.

  Then, the Si switching element 5 and the diode package 6 in which the SiC diode element 7 is sealed are mounted on the circuit conductor pattern 4 a of the same insulating substrate 2. The electrode surface of the Si switching element 5 is joined to the circuit conductor pattern 4a by the solder 3, and the lead terminal of the lead frame 15 of the diode package 6 is joined to the circuit conductor pattern 4a by the solder 3.

The Si switching element 5 is provided with a wire wiring 8, and is electrically connected to the main electrodes 9 and 10 and the control terminals 11 and 12 through the circuit conductor pattern 4 a and the wire wiring 8. The main electrodes 9 and 10 are connected to an external circuit and constitute a main circuit such as a power converter. The control terminals 11 and 12 are supplied with a control signal for ON / OFF control of the Si switching element 5 from an external circuit. In FIG. 1, the main electrodes 9 and 10 and the control terminals 11 and 12 are illustrated in a simplified manner for easy understanding of the circuit configuration.
The connection between the Si switching element 5 and the diode package 6 and the main electrodes 9 and 10 and the control terminals 11 and 12 may be electrically connected, and wire wiring or bus bar wiring is used.

  In the power semiconductor device 100 according to the present embodiment, the parts constituting the power semiconductor device such as the Si switching element 5 and the diode package 6 are housed in a case 13 covered by the base plate 1. In order to maintain insulation inside the power semiconductor device 100, an insulating sealing material (referred to as a case sealing material) 14 for sealing the inside of the case is filled.

FIG. 2 is a schematic top view showing a state in which the main electrode, the control terminal, the case, and the case sealing material are removed from the power semiconductor device according to the first embodiment of the present invention.
As shown in FIG. 2, main electrode attachment points 16 and 17 and control terminal attachment points 18 and 19 are provided on the circuit conductor pattern 4a. The main electrode 9 is connected to the main electrode attachment point 16, the main electrode 10 is connected to the main electrode attachment point 17, the control terminal 11 is connected to the control terminal attachment point 18, and the control terminal attachment point 19 is connected. Is connected to the control terminal 12.

The Si switching element 5 and the diode package 6 are electrically connected in reverse parallel via the circuit conductor pattern 4 a and the wire wiring 8.
For example, as will be described later, when an IGBT is used as the Si switching element 5, the lead terminal of the diode package 6 electrically connected to the collector of the IGBT and the cathode of the SiC diode element 7 is electrically connected via the circuit conductor pattern 4a. Connected.

The base plate 1 is provided with an attachment hole 20, and an external cooler or the like can be attached to the power semiconductor device 100 using the attachment hole 20.
Since the external cooler is provided in contact with the plane opposite to the one plane to which the insulating substrate 2 is bonded in the base plate 1, the external cooler is generated inside the power semiconductor device 100 from the other plane of the base plate 1. Heat is released to the outside.

FIG. 3 is a schematic cross-sectional view of a diode package used in the power semiconductor device according to the first embodiment of the present invention.
As shown in FIG. 3, the diode package 6 of the present embodiment is provided with a plurality of SiC diode elements 7 in an element sealing material 23 having high heat resistance and electrical insulation, and wire wiring 8 The SiC diode elements 7 are electrically connected in parallel by the lead frame 15.
That is, in the diode package 6 of the present embodiment, a plurality of SiC diode elements 7 are sealed with the element sealing material 23.

Specifically, the plurality of SiC diode elements 7 are mounted on the frame tab portion 21 a of the lead frame 15 on one side by bonding with a high heat-resistant bonding material 22. At this time, one homopolar electrode surface of each SiC diode element 7 is joined to the frame tab portion 21a.
Further, one end of the wire wiring 8 is connected to the electrode pad of the other electrode on the surface opposite to the surface joined to the frame tab portion 21a of each SiC diode element 7, and the other end of the wire wiring 8 is It is connected to the lead tip 21c of the other lead frame 15.
In the present embodiment, the wire wiring 8 is used, but ribbon bonding may be used instead of the wire wiring 8.

In the lead frame 15, one lead terminal 24 a led out from the frame tab portion 21 a to the outside of the element sealing material 23 and the other lead terminal 24 a led out from the lead tip portion 21 c to the outside of the element sealing material 23. The lead terminal 24b is joined to the circuit conductor pattern 4a by the solder 3.
That is, in the diode package 6 of the present embodiment, the SiC diode element 7, the wire wiring 8, and a part of the lead frame 15 are covered and protected by the element sealing material 23.

The Si switching element 5 used in the present embodiment may be a semiconductor element capable of ON-OFF control, and for example, an IGBT or a MOSFET is used.
In the present embodiment, an SiC diode element is used as the diode element, but, for example, a Schottky barrier diode, a PiN diode, or the like is also used. In addition, it is only necessary to have characteristics such as low loss and high temperature operation. For example, other wide band gap semiconductor diode elements such as gallium nitride materials or diamond may be used.

The lead frame 15, the high heat-resistant bonding material 22, and the element sealing material 23 used in the present embodiment are selected from materials having heat resistance higher than the operating temperature of the SiC diode element 7.
As the lead frame 15, in addition to oxygen-free copper, a copper alloy whose heat resistance is improved by adding Fe, Zr, Cr, Sn, Zn, Ni, Ag, Cd, Sb, Bi, In, or the like can be used.
Moreover, the high heat-resistant joining material 22 should just be a thing whose solidus line temperature of a junction part is higher than the operating temperature of a SiC diode element. As the high heat-resistant bonding material 22, a brazing material composed of two or more metals selected from the group of Sn, Sb, Ag, Cu, Ni, Bi, Zn, Au, and In, a metal sintered adhesive, and a high heat resistance For example, a conductive adhesive composed of a conductive resin or glass frit and a conductive filler can be used.

The element sealing material 23 is made of a mold resin that does not undergo significant degradation such as decomposition at the operating temperature of the SiC diode element 7 and satisfies heat resistance and electrical insulation. Examples of the mold resin used for the element sealing material 23 include a heat-resistant, thermosetting resin, a thermoplastic resin, or a heat-resistant resin composition containing a filler.
The thermosetting resin is preferably an epoxy resin that can be molded by a known technique such as transfer molding.
The thermoplastic resin is preferably polyphenylene sulfide (PPS), polybutylene terephthalate (PBT), or the like that can be molded by an injection molding method.

In the power running operation in which energy is supplied from the inverter side to the motor side when the power semiconductor device is used as an inverter for driving the motor, the energization period of the switching element is longer than that of the diode element, and the loss of the switching element is increased.
In such a case, the influence of thermal interference from the diode is small, and the heat generated from the switching element can be dissipated using the entire insulating substrate and base plate, so that the Si switching as in the power semiconductor device of the present embodiment There is no problem with a structure in which both the element and the SiC diode element are arranged on the same insulating substrate on the same base plate surface.
Such a structure is advantageous in that the number of parts can be reduced and wiring becomes easy.

However, in the regenerative motion in which energy is supplied from the motor side to the inverter side when used as a motor for an inverter, the energization time of the diode is longer than that of the switching element, and the diode loss increases.
In such a case, an SiC diode element is used as the diode element, and the power semiconductor device in which the SiC diode element and the Si switching element are arranged on the same insulating substrate on the same base plate surface is different from the SiC diode element used at high temperature. The influence of thermal interference becomes large, and it is necessary to increase the heat resistance of each material constituting the power semiconductor device, and it is necessary to use a large cooler.

However, in the power semiconductor device 100 according to the present embodiment, the Si switching element 5 and the diode package 6 in which the SiC diode element 7 is sealed are arranged on the same insulating substrate 2 provided on the surface of the base plate 1. Has been.
The SiC diode element 7 is sealed with a heat-resistant element sealing material 23 that can withstand the heat generation of the SiC diode element 7. Since the element sealing material 23 is a mold resin, the thermal conductivity is small and the thermal insulation is excellent, and the insulating substrate 2 and the base plate 1 can be thermally insulated from the SiC diode element 7.

  That is, in the power semiconductor device 100 of the present embodiment, in the diode package 6, the mold resin element sealing material 23 having heat resistance and electrical insulation serves as a heat insulating material. Heat generated by the diode element 7 can be prevented from being transferred to the case 13, the insulating substrate 2, and the base plate 1.

  The thermal insulation is only required to be substantially thermally insulated, and the heat from the SiC diode element is generated by the Si switching element 5, the case sealing material 14, the Si switching element 5, the diode package 6, and the main electrode 9. , 10 and the control terminals 11 and 12 to such an extent that they do not adversely affect members constituting the power semiconductor device, such as a bonding material for bonding the circuit conductor pattern 4a and a bonding material for the base plate 1 and the insulating substrate 2. Any state can be used as long as it is suppressed.

In power semiconductor device 100 of the present embodiment, a diode package 6 in which Si switching element 5 and SiC diode element 7 are sealed is mounted on the same insulating substrate 2 provided on the surface of base plate 1.
However, the SiC diode element 7 is electrically insulated and heat resistant, and is sealed with a molding resin element sealing material 23 that thermally insulates the SiC diode element 7 from the insulating substrate 2. Therefore, even when the SiC diode element 7 is operated at a high temperature, the base plate 1 and the insulating substrate 2 are joined, the Si switching element 5 and the diode package 6 are mounted on the circuit conductor pattern 4a, the main electrodes 9, 10 and General solder such as Sn-3.0Ag-0.5Cu can be used for joining the control terminals 11 and 12 to the circuit conductor pattern 4a, and the case sealing material 14 filled in the case 13 can be used. An inexpensive low heat insulating material such as silicone gel can be used.

  That is, the power semiconductor device 100 according to the present embodiment can use the same heat-resistant member as that used in a conventional power semiconductor device using only Si elements, thereby suppressing an increase in cost of the power semiconductor device. It is done. Further, an unnecessarily large cooler is unnecessary, and the apparatus can be downsized.

  Moreover, in the power semiconductor device 100 of the present embodiment, even if the SiC diode element is used, the substrate on which the Si switching element is mounted and the substrate on which the SiC diode element is mounted are not used separately. A structure similar to a conventional power semiconductor device using a Si switching element and a Si diode element, in which both the Si switching element and the SiC diode element are arranged on the same insulating substrate on the same base plate surface, can be adopted. It is possible to shorten the development period and diversify the configuration. In addition, since the number of parts can be reduced and wiring becomes easy, the cost can be reduced also from this aspect.

In the power semiconductor device 100 of the present embodiment, the power in which the Si switching element 5 and the diode package 6 in which the SiC diode element 7 is sealed are mounted on the same insulating substrate 2 provided on the surface of the base plate 1. Semiconductor device.
However, this is a power semiconductor device in which a Si switching element and a switching element package in which a SiC switching element is sealed with a molding resin element sealing material are mounted on the same insulating substrate provided on the base plate surface. The same effect can be obtained.

In power semiconductor device 100 of the present embodiment, the diode element sealed in the diode package is not only a SiC diode element but also another wide band gap semiconductor diode element such as a gallium nitride material or diamond. There may be.
In addition to the SiC switching element, the switching element sealed in the switching element package may also be another wide band gap semiconductor switching element such as a gallium nitride material or diamond.
That is, the power semiconductor device of the present embodiment uses an element package in which a wide gap semiconductor element is sealed.

Embodiment 2. FIG.
FIG. 4 is a schematic cross-sectional view of a diode package used in the power semiconductor device according to the second embodiment of the present invention.
As shown in FIG. 4, in the diode package 62 of the present embodiment, a plurality of SiC diode elements 7 are sealed with a molding resin element sealing material 23, and one electrode of each SiC diode element 7 is formed. The surface (anode side or cathode side) is bonded to the frame tab portion 21a of the lead frame 15 on one side by a high heat-resistant bonding material 22, and the other electrode surface of each SiC diode element 7 is connected to the lead on the other side. The frame tab portion 21 a of the frame 15 is bonded with a high heat-resistant bonding material 22.

The diode package 62 of the present embodiment is wired by a lead frame 15 instead of the wire wiring 8 in the diode package 6 of the first embodiment.
That is, wiring in the diode package 62 is performed by the direct lead bonding method.

The power semiconductor device of the present embodiment is the same as the power semiconductor device of the first embodiment except that the diode package 62 shown in FIG. 4 is used, and the same effect as the power semiconductor device of the first embodiment. Have
In addition, in the power semiconductor device according to the present embodiment, the wiring in the diode package 62 is performed by the direct lead bonding method. Therefore, in the case of a diode package in which many SiC diode elements are sealed, wire wiring is used. In comparison, the number of wiring processes is reduced and productivity is improved.

Embodiment 3 FIG.
FIG. 5 is a schematic cross-sectional view of a diode package used in the power semiconductor device according to the third embodiment of the present invention.
As shown in FIG. 5, in the diode package 63 a of the present embodiment, a plurality of SiC diode elements 7 are sealed with a molding resin element sealing material 23, and each electrode surface of each SiC diode element 7. A heat spreader 26 is thermally and electrically connected to the anode side and the cathode side by a high heat-resistant bonding material 22.

The heat spreader 26 bonded to one electrode surface of each SiC diode element 7 is electrically connected to the lead tip 21c of the lead frame 15 on one side and bonded to the other electrode surface of each SiC diode element 7. The heat spreader 26 is electrically connected to the lead tip 21c of the lead frame 15 on the other side.
For example, a copper alloy or an iron-based alloy is preferably used for the heat spreader 26, but the heat spreader 26 is not limited thereto.
In the diode package 63a of the present embodiment, the heat spreader 26 is thermally and electrically connected to each electrode surface of the SiC diode element 7 by the high heat-resistant bonding material 22, but as shown in FIG. The diode package 63b in which the heat spreader 26 is provided only on one electrode surface of each SiC diode element 7 may be used.

  The power semiconductor device of the present embodiment is the same as the power semiconductor device of the first embodiment except that the diode package 63a shown in FIG. 5 or the diode package 63b shown in FIG. 6 is used. This has the same effect as the power semiconductor device.

In addition, in the power semiconductor device of the present embodiment, the diode package is such that the heat spreader 26 is connected to at least one electrode surface of the SiC diode element 7, and the heat generated in the SiC diode element 7 is heat spreader. 26 is dissipated into the diode package through the lead frame 15, so that heat can be prevented from flowing out from the lead terminals 24a and 24b of the lead frame 15 to the outside of the diode package, and the operation of the SiC diode element 7 at a higher temperature can be suppressed. It becomes possible.
In addition, since the power semiconductor device of the present embodiment has a small temperature gradient in the diode package, the diode package itself has excellent heat cycle resistance and power cycle resistance.

In the present embodiment, an isotropic heat conductive material such as a copper alloy or an iron-based alloy is used for the heat spreader 26. However, the heat spreader 26 is not only made of an isotropic heat conductive material, A combination of an isotropic heat conductive material and an anisotropic heat conductive material may be used.
FIG. 7 is a schematic perspective view of a heat spreader used in a diode package, which is a combination of an isotropic heat conductive material and an anisotropic heat conductive material.

As shown in FIG. 7, the structure of the heat spreader 26a in which the isotropic heat conductive material 27a and the anisotropic heat conductive material 27b are combined is an isotropic heat conductive material 27a whose both ends can be joined to the lead frame. The isotropic heat conductive material 27a and the anisotropic heat conductive material 27b are alternately arranged and integrated. The anisotropic heat conductive material 27b has a heat conduction direction on the electrode surface of the SiC diode element 7. It is arrange | positioned so that it may become a perpendicular | vertical direction.
As the anisotropic heat conductive material 27b, for example, a carbon fiber or the like having excellent heat conductivity in a specific direction oriented in one direction can be used.

  As described above, the heat spreader 26a formed of the isotropic heat conductive material 27a and the anisotropic heat conductive material 27b is prevented from conducting heat in the longitudinal direction. Therefore, thermal interference with components and elements with low heat resistance adjacent to the diode package can be further reduced.

Embodiment 4 FIG.
FIG. 8 is a schematic cross-sectional view of a diode package used in the power semiconductor device according to the fourth embodiment of the present invention.
As shown in FIG. 8, the diode package 64 of the present embodiment is the back surface of each frame tab portion 21a of the lead frame 15 on one side and the lead frame 15 on the other side in the diode package 62 of the second embodiment. The heat spreader 26 is joined with the high heat-resistant joining material 22.
The power semiconductor device of the present embodiment is the same as the power semiconductor device of the second embodiment except that the diode package 64 shown in FIG. 8 is used, and the same effect as the power semiconductor device of the second embodiment. Have

  In addition, in the power semiconductor device of the present embodiment, the diode package 64 is connected to the electrode surface of the SiC diode element 7 and the heat spreader 26 through the lead frame 15. Since the heat generated in the diode element 7 is dissipated into the diode package 64 via the heat spreader 26, heat flowing out from the lead terminals 24a and 24b of the lead frame 15 to the outside of the diode package 64 can be suppressed, and a higher temperature. The operation of the SiC diode element 7 can be performed.

Also, the diode package 64 of the present embodiment can reduce the temperature gradient in the diode package 64, so that the diode package 64 itself is excellent in heat cycle resistance and power cycle resistance.
Further, since the diode package 64 of the present embodiment can directly connect the SiC diode element 7 and the circuit conductive pattern 4a with the lead frame 15, the heat spreader 26 does not need conductivity, and is made of ceramics or the like. An insulating material may be used.
Further, as the heat spreader of the present embodiment, a heat spreader 26a formed of an isotropic heat conductive material 27a and an anisotropic heat conductive material 27b may be used.

Embodiment 5 FIG.
9A is a schematic cross-sectional view of a diode package used in the power semiconductor device according to the fifth embodiment of the present invention, and FIG. 9B is a schematic perspective view illustrating a stacked state of the heat spreader, the lead frame, and the SiC diode element. ).
As shown in FIG. 9, the diode package 65 of the present embodiment uses the lead frame 15a having the frame tab portion 21b provided with a plurality of through holes 21d in the diode package 64 of the fourth embodiment. is there.

  The power semiconductor device of the present embodiment is the same as the power semiconductor device of the fourth embodiment except that the diode package 65 shown in FIG. 9 is used, and the same effect as the power semiconductor device of the fourth embodiment. Have

In addition, in the diode package 65 of the present embodiment, a plurality of through holes 21d are provided in the frame tab portion 21b of the lead frame 15a, and the SiC diode element 7 and the heat spreader 26 are placed in the through holes 21d. Since there is a portion that is directly bonded by the heat-resistant bonding material 22, the thermal diffusion from the SiC diode element 7 to the heat spreader 26 is improved as compared with the diode package 64 of the fourth embodiment.
That is, the power semiconductor device of the present embodiment can operate SiC diode element 7 at a higher temperature than the power semiconductor device of the fourth embodiment.

Embodiment 6 FIG.
FIG. 10 is a schematic cross-sectional view of a diode package used in the power semiconductor device according to the sixth embodiment of the present invention.
As shown in FIG. 10, the diode package 66 of the present embodiment is a hollow body that is formed of the high thermal conductivity material 28 and has a space provided in the diode package 63 of the third embodiment. The heat spreader 26b filled with the heat storage material 29 is used.
The high heat conductive material 28 includes, for example, an alloy mainly composed of copper, iron, and aluminum, and the heat storage material 29 includes, for example, a low melting point metal having a melting point near the heat generation temperature of the SiC diode element 7. And latent heat storage materials such as salts and polysaccharides.

The power semiconductor device of the present embodiment is the same as the power semiconductor device of the third embodiment except that the diode package 66 shown in FIG. 10 is used, and the same effect as the power semiconductor device of the third embodiment. Have
In addition, in the power semiconductor device according to the present embodiment, the heat spreader 26b used in the diode package 66 contains the heat storage material 29 therein, and has high thermal conductivity and large heat capacity. Therefore, the power spreader 26b used in the diode package 66 functions as a heat spreader. Since the effect is great and the efficiency of heat dissipation into the diode package 66 is high, the SiC diode element 7 can be operated at a higher temperature.
The heat spreader 26b of the present embodiment can also be used for the diode package in the power semiconductor device of the fourth and fifth embodiments.

Embodiment 7 FIG.
FIG. 11 is a schematic cross-sectional view of a diode package used in the power semiconductor device according to the seventh embodiment of the present invention.
As shown in FIG. 11, the diode package 67 of the present embodiment is a hollow body that is formed of the high thermal conductivity material 28 in the diode package 63 of the third embodiment and that has a plurality of independent spaces therein. The heat spreader 26c in which the heat storage material 29 is filled in the plurality of independent spaces is used.
The high heat conductive material 28 and the heat storage material 29 are the same as those used in the sixth embodiment.

The power semiconductor device of the present embodiment is the same as the power semiconductor device of the third embodiment except that the diode package 67 shown in FIG. 11 is used, and the same effect as the power semiconductor device of the third embodiment. Have
In addition, a hollow heat spreader 26c having a space formed of a high thermal conductive material 28 and filled with a heat storage material 29 is used in the diode package 67, and the same effect as that of the power semiconductor device of the sixth embodiment is used. Have

Further, in the heat spreader 26c of the present embodiment, the space inside the hollow body is a plurality of independent spaces, and the plurality of independent spaces are filled with the heat storage material 29. Therefore, the heat storage material 29 and the heat storage material 29 are filled. The heat transfer area increases and the effect as a heat spreader is even greater.
The heat spreader 26c of the present embodiment can also be used for the diode package in the power semiconductor device of the fourth and fifth embodiments.

Embodiment 8 FIG.
FIG. 12 is a schematic cross-sectional view of a diode package used in the power semiconductor device according to the eighth embodiment of the present invention.
As shown in FIG. 12, the diode package 68 of the present embodiment is the same as the diode package of the third embodiment, except that the element sealing material has a two-layer structure.

That is, as the element sealing material, an inner layer side element sealing material 35 formed of a mold resin of the same material as the element sealing material 23 of the third embodiment is used on the inner layer side, and on the outer layer side. The outer layer side element sealing material 36 having better heat insulation than the inner layer side element sealing material 35 is used.
The outer layer side element sealing material 36 includes a resin (thermosetting resin or thermoplastic resin) to which a hollow filler is added, a resin foam, and the like.
When the inner layer side element sealing material 35 is a mold resin highly filled with crystalline silica, a mold resin filled with glass fiber or amorphous inorganic filler is used for the outer layer side element sealing material 36. be able to.

  The power semiconductor device of the present embodiment is the same as the power semiconductor device of the third embodiment except that the diode package 68 shown in FIG. 12 is used, and the same effect as the power semiconductor device of the third embodiment. Have

In addition, in the power semiconductor device according to the present embodiment, the diode package 68 includes an element sealing material, a mold resin inner layer side element sealing material 35 having excellent strength, electrical insulation, and heat resistance, and SiC. Although the strength is insufficient to seal the diode element 7, it has a two-layer structure with the outer-layer-side element sealing material 36 having further excellent heat insulation properties, so that mechanical and electrical reliability is maintained. However, the thermal insulation of the diode package 68 can be further improved, and the SiC diode element 7 can be operated at a higher temperature.
The two-layer element sealing material as in the present embodiment is also applied to the diode package in the power semiconductor devices of the first and second embodiments and the fourth to seventh embodiments. Can be used.

Embodiment 9 FIG.
FIG. 13 is a schematic cross-sectional view of a diode package used in the power semiconductor device according to the ninth embodiment of the present invention.
As shown in FIG. 13, in the diode package 69 of the present embodiment, the heat spreader 26 is bonded to each electrode surface of each SiC diode element 7 in the diode package of the third embodiment, and the lead frame 15 is attached to each heat spreader 26. In the electrically connected state, a coating 30 of a high heat-resistant insulator is provided on the surfaces of the SiC diode element 7, the heat spreader 26, and the lead frame 15.

Examples of the material used for the coating 30 of the high heat resistance insulator include polyimide amide, polyimide, fluorine resin, and ceramics. As a coating method, in addition to spraying and dipping, chemical adsorption such as chemical deposition by plating or electrodeposition, CVD, PVD, vapor deposition, and thermal spraying can be used.
The power semiconductor device of the present embodiment is the same as the power semiconductor device of the third embodiment except that the diode package 69 shown in FIG. 13 is used, and the same effect as the power semiconductor device of the third embodiment. Have

In addition, in the power semiconductor device of the present embodiment, the coating 30 of the high heat-resistant insulator is provided on the surfaces of the SiC diode element 7, the heat spreader 26, and the lead frame 15 in the diode package 69, and the element sealing material 23. However, since it is in contact with the coating 30, a temperature gradient is generated between the surfaces of the SiC diode element 7, the heat spreader 26, the lead frame 15, and the element sealing material 23.
Therefore, the power semiconductor device of the present embodiment generates a large amount of heat, and the surface temperature of the SiC diode element 7, the heat spreader 26, and the lead frame 15 in the diode package 69 is higher than the heat resistance temperature of the element sealing material 23. It allows operation of the SiC diode at higher temperatures, such as higher.

Embodiment 10 FIG.
FIG. 14 is a schematic cross-sectional view of a diode package used in the power semiconductor device according to the tenth embodiment of the present invention.
FIG. 15 is a schematic top view showing a state in which the main electrode, the control terminal, the case, and the case sealing material are removed from the power semiconductor device according to the tenth embodiment of the present invention.
As shown in FIG. 14, the diode package 70 used in the power semiconductor device 200 of the present embodiment is one in which a plurality of SiC diode elements 7 are sealed with a molding resin element sealing material 23. The heat spreader 26 is bonded to one of the same polarity electrode surfaces of each SiC diode element 7 with a high heat resistant bonding material 22, and the conductive layer 31 is bonded to the other same polarity electrode surface of each SiC diode element 7. Bonded with a material 22.

And the surface of the heat spreader 26 and the conductive layer 31 opposite to the surface bonded to the electrode surface of the SiC diode element 7 is exposed from the element sealing material 23, and the exposed surface of the heat spreader 26 is solder 3. Thus, the conductor pattern 4 is joined. In addition, the wire wiring 8 is connected to the exposed surface of the conductive layer 31 as a wiring member. A bus bar may be used for this wiring member.
The power semiconductor device 200 of the present embodiment is the same as the power semiconductor device of the first embodiment except that the diode package 70 shown in FIG. 14 is used, and is the same as the power semiconductor device of the first embodiment. Has an effect.

  In the power semiconductor device 200 of the present embodiment, the electrode shape of the diode package 70 is the same as that of the bare chip of the Si diode element, so that the diode package 70 in which the SiC diode element 7 is sealed is provided as shown in FIG. It can be mounted on a wiring pattern similar to that of an existing power semiconductor device composed of a Si switching element and a Si diode element without changing the assembly method.

Embodiment 11 FIG.
FIG. 16 is a schematic cross-sectional view of a diode package used in the power semiconductor device according to the eleventh embodiment of the present invention.
As shown in FIG. 16, in the diode package 71 of the present embodiment, a plurality of SiC diode elements 7 are sealed with an element sealing body 50. The element sealing body 50 is formed of a ceramic casing having a space inside.

  Further, the plurality of SiC diode elements 7 are mounted on the frame tab portion 21a of the lead frame 15 on one side disposed in the ceramic casing by bonding with a high heat-resistant bonding material 22. At this time, one homopolar electrode surface of each SiC diode element 7 is joined to the frame tab portion 21a.

Further, one end of the wire wiring 8 is connected to the electrode pad of the other electrode on the surface opposite to the surface joined to the frame tab portion 21a of each SiC diode element 7, and the other end of the wire wiring 8 is The lead end portion 21c of the lead frame 15 on the other side disposed in the ceramic casing is connected.
That is, each SiC diode element 7 is electrically connected in parallel by the wire wiring 8 and the lead frame 15.
In the present embodiment, the wire wiring 8 is used, but ribbon bonding may be used instead of the wire wiring 8.

In the lead frame 15, one lead terminal 24 a led out from the frame tab portion 21 a to the outside of the element sealing body 50 and the other lead terminal 24 a led out from the lead tip 21 c to the outside of the element sealing body 50. The lead terminal 24b is joined to the circuit conductor pattern 4a by the solder 3.
That is, in the diode package 71 of the present embodiment, the SiC diode element 7, the wire wiring 8, and a part of the lead frame 15 are protected by the element sealing body 50.

The power semiconductor device of the present embodiment is the same as the power semiconductor device of the first embodiment except that the diode package 71 shown in FIG. 16 is used.
In the diode package 71 of the present embodiment, since the element sealing body 50 that seals the SiC diode element 7 is a ceramic casing, there is a space around the SiC diode element 7 disposed in the ceramic casing. There is a part, and this space part becomes a heat insulation layer.
That is, also in the diode package 71 of the present embodiment, the element sealing body 50 becomes a heat insulating portion, and the heat of the SiC diode element 7 is suppressed from being transferred to the inside of the case 13, the insulating substrate 2, or the base plate 1. Thus, the power semiconductor device of the present embodiment using this diode package 71 has the same effect as the power semiconductor device of the first embodiment.

The power semiconductor device according to the present embodiment is similar to the power semiconductor device according to the first embodiment in that the Si switching element 5 and the SiC diode element 7 are provided on the same insulating substrate 2 provided on the surface of the base plate 1. This is a power semiconductor device on which a sealed diode package 71 is mounted.
However, a power semiconductor device in which a Si switching element and a switching element package in which a SiC switching element is sealed with an element sealing body 50 of a ceramic housing are mounted on the same insulating substrate provided on the base plate surface. The same effect can be obtained.

In the power semiconductor device of the present embodiment, the diode element sealed in the diode package is not only a SiC diode element but also another wide band gap semiconductor diode element such as a gallium nitride material or diamond. May be.
In addition to the SiC switching element, the switching element sealed in the switching element package may also be another wide band gap semiconductor switching element such as a gallium nitride material or diamond.
That is, the power semiconductor device of this embodiment also uses an element package in which elements of a wide band gap semiconductor are sealed.

Embodiment 12 FIG.
FIG. 17 is a schematic side sectional view of the power semiconductor device according to the twelfth embodiment of the present invention.
FIG. 18 is a schematic top view showing a state in which the main electrode, the control terminal, the case, and the case sealing material are removed from the power semiconductor device according to the twelfth embodiment of the present invention.
The power semiconductor device 300 according to the twelfth embodiment of the present invention is also a power semiconductor device including the Si switching element 5 and the diode package 72 in which the SiC diode element 7 is sealed.
As shown in FIG. 17, in the power semiconductor device 300 of the present embodiment, the insulating substrate 2 is mounted on one plane of the base plate 1, and the surface on which the conductive pattern 4b of the insulating substrate 2 is provided is solder (FIG. 17). (Not shown) or the like. A circuit conductor pattern 4a serving as a current path is formed on the surface of the insulating substrate 2 opposite to the surface on which the conductor pattern 4b is provided.

The Si switching element 5 is mounted on the insulating substrate 2 by bonding its electrode surface to the circuit conductor pattern 4a with solder 3.
As shown in FIGS. 17 and 18, the Si switching element 5 is provided with wire wiring 8, and the main electrode attachment points 16, 17 are electrically connected via the circuit conductor pattern 4 a and the wire wiring 8. Are electrically connected to the control terminal mounting points 18 and 19.
However, in FIG. 17, the main electrodes 9 and 10 and the control terminals 11 and 12 are not shown.

As shown in FIGS. 17 and 18, in the power semiconductor device 300 of the present embodiment, the diode package 72 is mounted on the base plate 1.
In the diode package 72, the plurality of SiC diode elements 7 are sealed with a molding resin element sealing material 23 having high heat resistance and electrical insulation.
Further, the frame tab portion 21 of the lead frame 15 on one side is joined to one electrode surface of each SiC diode element 7 by a high heat-resistant joining material (not shown), and the other electrode surface is joined to the other side. The frame tab portion 21 of the lead frame 15 is bonded with a high heat-resistant bonding material (not shown).
Further, the lead terminals 24 a and 24 b of each lead frame 15 are joined to the circuit conductor pattern 4 a of the insulating substrate 2.

Further, a heat spreader 26 is bonded to the back surface of the frame tab portion 21a of the lead frame 15 on one side and the frame tab portion 21a of the lead frame 15 on the other side with a high heat-resistant bonding material (not shown).
The surface opposite to the joint surface with the lead frame 15 in the heat spreader 26 close to the base plate 1 joined to the lead frame 15 on one side is exposed from the element sealing material 23.

That is, the surface of the heat spreader 26 is exposed on the side of the diode package 72 mounted on the base plate 1 that faces the base plate 1.
Further, between the exposed surface of the heat spreader 26 and the base plate 1 in the diode package 72, a heat transfer section 40 having electrical insulation is provided in contact with each of the exposed surface of the heat spreader 26 and the base plate 1. ing.
In the diode package 72 of the present embodiment, the heat spreader 26 is provided on the lead frame 15 on one side and the other side, but may be provided only on the lead frame 15 on one side.

As shown in FIG. 17, in the power semiconductor device 300 of the present embodiment, the parts constituting the power semiconductor device such as the Si switching element 5 and the diode package 72 are housed in the case 13. In order to maintain insulation inside the power semiconductor device 300, the case sealing material 14 having an insulating property is filled.
Further, an external cooler can be provided in contact with the plane opposite to the one plane to which the insulating substrate 2 is bonded in the base plate 1.

Also in the power semiconductor device 300 of the present embodiment, the diode package 72 has the SiC diode element 7 sealed with the mold resin element sealing material 23 having high heat resistance and electrical insulation. The sealing material 23 becomes a heat insulating material, and the heat of the SiC diode element 7 is suppressed from being transferred to the case 13 or the insulating substrate 2.
Therefore, the power semiconductor device 300 of the present embodiment can use the same heat-resistant member as that used in the conventional power semiconductor device including only Si elements, and the cost increase of the power semiconductor device can be suppressed. It is done.

Further, in the power semiconductor device 300 of the present embodiment, the diode package 72 mounted on the base plate 1 has the exposed surface of the heat spreader 26 laminated on the base plate 1 via the heat transfer section 40. The heat of the SiC diode element 7 can be directly transferred to the base plate 1, the heat dissipation of the SiC diode element 7 to the base plate 1 is improved, an unnecessarily large cooler is unnecessary, and the apparatus can be downsized. It becomes.
In addition, the improvement of the heat dissipation performance of the SiC diode element 7 to the base plate 1 is used under the operating conditions in which the SiC diode element 7 generates heat intermittently. Even when the heat generation amount is large, the diode package 72 exceeds the heat resistance temperature. Can be prevented.

  In addition, since the power semiconductor device 300 of the present embodiment does not use separate substrates for the substrate on which the Si switching element is mounted and the substrate on which the SiC diode element is mounted, the conventional Si switching element and Si substrate are not used. A structure similar to that of a power semiconductor device using a diode element can be adopted, and the development period can be shortened and the configuration can be diversified. In addition, since the number of parts can be reduced and wiring becomes easy, the cost can be reduced also from this aspect.

FIG. 19 is a schematic diagram showing a heat transfer section of the first structure provided between the exposed surface of the heat spreader of the diode package and the base plate in the power semiconductor device according to the twelfth embodiment of the present invention.
As shown in FIG. 19, the heat transfer section 40 a of the first structure includes an electrically insulating high thermal conductive sheet 32 provided in contact with the exposed surface of the heat spreader 26, and the high thermal conductive sheet 32 and the base plate 1. It consists of grease 33 interposed between them. Examples of the high thermal conductive sheet 32 include a resin sheet that is highly filled with a high thermal conductive filler such as alumina, aluminum nitride, or boron nitride.
Since the exposed surface of the heat spreader 26 is in close contact with the base plate 1 via the high thermal conductive sheet 32, the heat transfer section 40a having the first structure lowers the thermal resistance between the heat spreader 26 and the base plate 1, thereby reducing the SiC. The heat dissipation to the base plate 1 of the diode element 7 is improved.

FIG. 20 is a diagram showing a heat transfer section having a second structure provided between the exposed surface of the heat spreader of the diode package and the base plate in the power semiconductor device according to the twelfth embodiment of the present invention.
As shown in FIG. 20, the heat transfer section 40 b of the second structure is a small-sized and mounted on the base plate 1 and the high thermal conductive sheet 32 having electrical insulation provided in contact with the exposed surface of the heat spreader 26. The cooling module 34 includes a grease 33 interposed between the high thermal conductive sheet 32 and the small cooling module 34. Examples of the small cooling module 34 include a Peltier element and a thermoelectric conversion element.
The heat transfer section 40b having the second structure includes a small cooling module 34, which further reduces the thermal resistance between the heat spreader 26 and the base plate 1, and the base plate 1 of the SiC diode element 7. Further improve the heat dissipation.

  The diode package 72 of the present embodiment has a structure in which the heat spreader 26 is bonded to the back surface of the frame tab portion 21a on which the SiC diode element 7 is mounted on at least one of the lead frames 15, but the SiC spreader is connected to the heat spreader. A structure in which the elements are directly joined and the lead end portion of the lead frame on one side is electrically connected to the heat spreader may be employed.

The power semiconductor device 300 according to the present embodiment is a power semiconductor device in which the Si switching element 5 is mounted on the insulating substrate 2 provided on the surface of the base plate 1 and the diode package 72 is mounted on the base plate 1. is there.
However, a power semiconductor device in which a switching element package in which an SiC switching element is sealed with a mold resin element sealing material is mounted on the base plate 1 may be used, and similar effects can be obtained.

In the power semiconductor device 300 of the present embodiment, the diode element sealed in the diode package is not only an SiC diode element but also another wide band gap semiconductor diode element such as a gallium nitride-based material or diamond. There may be.
In addition to the SiC switching element, the switching element sealed in the switching element package may also be another wide band gap semiconductor switching element such as a gallium nitride material or diamond.
That is, the power semiconductor device of this embodiment also uses an element package in which elements of a wide band gap semiconductor are sealed.

  Since the power semiconductor device according to the present invention is a power semiconductor device having a wide bandgap semiconductor element, the power semiconductor device is used for a power converter that is required to be downsized and highly efficient.

1 Base plate, 2 Insulating substrate, 3 Solder, 4a Circuit pattern for circuit,
4b Conductor pattern, 5 Si switching element, 6 Diode package,
7 SiC diode element, 8 wire wiring, 9,10 main electrode,
11, 12 control terminal, 13 case, 14 case sealing material,
15, 15a Lead frame, 16, 17 Main electrode attachment point,
18, 19 Control terminal mounting point, 20 mounting hole,
21a, 21b Frame tab part, 21c Lead tip part, 21d Through hole,
22 high heat-resistant bonding material, 23 element sealing material, 24a, 24b lead terminal,
26, 26a, 26b, 26c heat spreader, 27a isotropic heat conductive material,
27b anisotropic heat conductive material, 28 high heat conductive material, 29 heat storage material,
30 coating, 31 conductive layer, 32 high thermal conductivity sheet, 33 grease,
34 cooling module, 35 inner layer side element sealing material, 36 outer layer side element sealing material,
40 heat transfer section, 40a first structure heat transfer section, 40b second structure heat transfer section,
50 element sealing body, 62, 63a, 63b, 64 diode package,
65, 66, 67, 68, 69, 70, 71, 72 diode package,
100, 200, 300 Power semiconductor device.

Claims (15)

A base plate, an insulating substrate bonded to one surface of the base plate and provided with a circuit conductor pattern, a Si switching element mounted on the insulating substrate, and a plurality of mounted on the insulating substrate An element package in which a wide band gap semiconductor element is sealed with an element sealing material; and a case that covers the base plate, and at least houses the Si switching element, the element package, and the insulating substrate; A power semiconductor device comprising a case sealing material filled inside the case,
The Si switching element and the element package are mounted on a circuit conductor pattern of the same insulating substrate,
The electrode of the Si switching element and the electrode of the wide band gap semiconductor element are electrically connected to the circuit conductor pattern,
A power semiconductor device in which a mold resin is used for the element sealing material. It said element package, a plurality of SiC diode element electrically connected in parallel a diode package sealed with a sealing material for the element, the lead frame is electrically connected to the electrode of the SiC diode element, 2. The power semiconductor device according to claim 1 , wherein a lead terminal of the lead frame is derived from the element sealing material and joined to the circuit conductor pattern. The diode package, the one electrode surface of each SiC diode element, whereas the frame tab portion of the lead frame side are joined by a high heat-resistant bonding material, the other electrode surface of each SiC diode element, the wire wiring the one end is connected, the other end of the wire wiring, power semiconductor device according to claim 2, characterized in that connected to the lead tip portions of the lead frame on the other side. The diode package, the one electrode surface of each SiC diode element, whereas the frame tab portion of the lead frame side are joined by a high heat-resistant bonding material, the other electrode surface of each SiC diode element, the other side the power semiconductor device according to claim 2, wherein the frame tab portion of the lead frame has been joined by the high heat-resistant bonding material. The diode package, the one electrode surface and the other electrode surface of each SiC diode element, the heat spreader is bonded with a high heat-resistant bonding material, a heat spreader is joined to one electrode surface above, one side of the lead claims lead tip portions of the frame are electrically connected to the heat spreader bonded to the other electrode surface, the lead distal end of the lead frame on the other side is characterized in that electrically connected Item 3. The power semiconductor device according to Item 2 . The diode package, the bonding surface of the opposite side of the joint surface between the SiC diode element in the frame tab portion of the lead frame of the one side, and the SiC diode element in the frame tab portion of the lead frame of the other side of the the opposite surface, power semiconductor device according to claim 4, the heat spreader is characterized in that which has been joined by the high heat-resistant bonding material. The frame tab portion of the lead frame of the frame tab portion and the other side of the lead frame of the one side a plurality of through holes are provided, the high heat-resistant bonding material said SiC diode element and the heat spreader has entered the above through hole The power semiconductor device according to claim 6 , wherein the power semiconductor device is directly joined to each other. The heat spreader has a structure in which both ends are isotropic heat conductive materials and the isotropic heat conductive material and the anisotropic heat conductive material are alternately arranged and integrated. The power semiconductor device according to any one of claims 5 to 7, wherein a heat conduction direction is arranged to be a direction perpendicular to an electrode surface of the SiC diode element. It said heat spreader is formed with the high thermal conductive material, and a hollow body which space is provided inside, claim 5 claims, characterized in that the heat storage material in the space of the hollow body is filled structure the power semiconductor device according to any one of 7. The element sealing material is an inner layer side element sealing material made of a mold resin on the inner layer side, and the outer layer side is made of a resin material having better heat insulation than the inner layer side element sealing material. The power semiconductor device according to claim 1 , wherein the power semiconductor device has a two-layer structure as a stopper. The element package is a diode package in which a plurality of SiC diode elements electrically connected in parallel are sealed with the element sealing material, and a heat spreader is bonded to one electrode surface of each SiC diode element with a high heat resistance. The conductive layer is bonded to the other electrode surface of each SiC diode element with the high heat-resistant bonding material, and is opposite to the surface of the heat spreader and the conductive layer bonded to the electrode surface of the SiC diode element. A side surface is exposed from the element sealing material, an exposed surface of the heat spreader is a surface to be bonded to the circuit conductor pattern, and an exposed surface of the conductive layer is a surface to which the wiring member is bonded. The power semiconductor device according to claim 1 , wherein the power semiconductor device is a power semiconductor device. A base plate, an insulating substrate bonded to one surface of the base plate and provided with a circuit conductor pattern, a Si switching element mounted on the insulating substrate, and a plurality of mounted on the insulating substrate An element package in which a wide band gap semiconductor element is sealed with an element sealing body, and a case that covers the base plate and at least contains the Si switching element, the element package, and the insulating substrate; A power semiconductor device comprising a case sealing material filled inside the case,
The Si switching element and the element package are mounted on a circuit conductor pattern of the same insulating substrate,
The electrode of the Si switching element and the electrode of the wide band gap semiconductor element are electrically connected to the circuit conductor pattern,
A power semiconductor device in which a ceramic casing is used for the element sealing body. The element package is a diode package in which a plurality of SiC diode elements electrically connected in parallel are sealed with the element sealing body, and a lead on one side is formed on one electrode surface of each SiC diode element. The frame tab portion of the frame is bonded with a high heat-resistant bonding material, one end of the wire wiring is connected to the other electrode surface of each SiC diode element, and the other end of the wire wiring is connected to the leading end of the lead frame on the other side 13. The power semiconductor according to claim 12 , wherein a lead terminal of the lead frame that is connected to a portion and led out of the element sealing body is joined to the circuit conductor pattern. apparatus. A base plate, an insulating substrate bonded to one surface of the base plate and provided with a circuit conductor pattern, a Si switching element bonded to the circuit conductor pattern of the insulating substrate, and the base plate An element package mounted on the surface to which the insulating substrate is bonded, in which a plurality of wide band gap semiconductor elements are sealed with an element sealing material, and is covered with the base plate and at least the Si switching A power semiconductor device comprising: a case for housing an element, the element package, and the insulating substrate; and a case sealing material filled in the case,
The element package exposes the surface of one heat spreader joined to the wide band gap semiconductor element from the side facing the base plate,
Between the exposed surface of the heat spreader and the base plate, a heat transfer portion having electrical insulation is provided in contact with the exposed surface of the heat spreader and the base plate,
The electrode of the Si switching element and the electrode of the wide band gap semiconductor element are electrically connected to the circuit conductor pattern,
A power semiconductor device in which a mold resin is used for the element sealing material. It said element package, a power semiconductor device according to a plurality of SiC diode element electrically connected in parallel to claim 14, characterized in that the diode package is sealed with a sealing material for the element.

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