US20050218426A1 - Power semiconductor module - Google Patents
Power semiconductor module Download PDFInfo
- Publication number
- US20050218426A1 US20050218426A1 US11/142,471 US14247105A US2005218426A1 US 20050218426 A1 US20050218426 A1 US 20050218426A1 US 14247105 A US14247105 A US 14247105A US 2005218426 A1 US2005218426 A1 US 2005218426A1
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- ceramic substrate
- metal base
- ceramic
- plate
- solder
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Definitions
- the present invention relates to a power semiconductor module that may be applied to a converter or inverter of a power switching device, for example.
- FIGS. 9 a and 9 b the assembled structure of a conventional example of such a power semiconductor module (in which six elements form a structure for three circuits), will now be described using FIGS. 9 a and 9 b .
- a metal base (copper base plate) 1 is provided for radiating heat, which is a heat sink
- an outer case 2 is provided having terminals formed integrally
- a main circuit terminal 3 is provided in this outer enclosing case 2 .
- a control terminal 4 , a power circuit block 5 , a control circuit block 6 , and bonding wires 7 including internal wiring are also provided.
- FIGS. 9 a and 9 b illustrate the power circuit block 5 having six of each of a power semiconductor chip 9 , such as an IGBT, and a free-wheeling diode 10 , mounted on a ceramic substrate 8 that is in the shape of a rectangular oblong.
- the ceramic substrate 8 is a direct copper bonding substrate including an upper circuit plate 8 b , and a lower plate 8 c , which are plated with copper foil and are directly joined to the upper surface and lower surface, respectively, of a ceramic plate 8 a made from alumina, aluminum nitride or silicon nitride.
- a semiconductor pattern is formed on the upper circuit plate 8 b .
- the semiconductor chips 9 are mounted on the upper circuit plate 8 b via a solder join layer 11 including solder.
- the control circuit 6 is made such that drive ICs 6 b , which are for driving power circuit elements, and circuit components associated with these drive ICs, are mounted on a U-shaped printed substrate 6 a surrounding the power circuit block 5 .
- the power circuit block 5 and the control circuit block 6 are placed side by side on a metal base 1 .
- the lower plate 8 c of the ceramic substrate 8 , on the power circuit block 5 , and the metal base 1 are joined using Sn—Pb solder (this solder is represented by “ 12 ”) to conduct heat generated by the power semiconductor chips 9 to the metal base 1 via the ceramic substrate 8 .
- the printed substrate 6 a of the control circuit block 6 is affixed to the metal base 1 using an adhesive.
- the outer case 2 having terminals integrally formed therein is joined to the metal base 1 using an adhesive. Specifically, the outer case 2 is placed over the power circuit block 5 and the control circuit block 6 is mounted on the metal base 1 so as to enclose the power circuit block 5 and the control circuit block 6 .
- the inner lead portions 3 a of the main circuit terminals 3 are soldered to the printed pattern of the ceramic substrate 8 , and control terminals 4 become internal wiring as a result of bonding wires 7 to the printed pattern of the printed substrate 6 .
- the outer enclosing case 2 is covered with a lid (not shown) to thus complete the power semiconductor module.
- a gel-like filler material silicon gel, for example
- Power semiconductor modules like those mentioned above are extensively employed in various fields, from low-capacity devices for everyday use to high-capacity devices which are used industrially or in vehicles, for example.
- low-capacity modules for everyday-use for which the degree of reliability required is not particularly high, and in which the amount of heat generated by power semiconductor elements is limited, can be designed and manufactured with barely any restrictions being placed on the material and size of each of the components.
- high-capacity modules are concerned, which are typically used in power circuits of vehicle drive devices, there is sometimes an increased amount of heat generated per unit area of power chips in the high-capacity modules. Because the size of such power chips is smaller and more compact, there is a demand for high reliability and long life in high-capacity modules compared to the low-capacity modules in products manufactured for everyday use.
- a heat cycle test to which manufactured power modules are subjected to include conditions for one heat cycle: ⁇ 40° C. (60 minutes), followed by room temperature (30 minutes), followed by 125° C. (60 minutes), and followed by room temperature (30 minutes).
- ordinary general-purpose products are subjected to a test of around 100 cycles. Accordingly, the reliability required for products manufactured for vehicle drive devices is such that such products must sufficiently withstand a heat cycle test of 3000 cycles.
- a pressing problem regarding these power semiconductor chips includes ensuring a durability that can sufficiently withstand high levels of heat radiation, and the severe heat cycles accompanying the motion of the vehicle, at the same time as ensuring the required electrical insulation resistance.
- Thermal stress attributable to a difference in the thermal expansion of the ceramic substrate/metal base specifically, while a rate of thermal expansion of the ceramic substrate is 7 ppm/K for alumina, 4.5 ppm/K for aluminum nitride, and 3 ppm/K for silicon nitride, a rate of thermal expansion of the metal base (copper base) is 16.5 ppm/K, which provides for a large difference between the thermal expansion rates of the ceramic substrate and the metal base.
- the yield strength of the solder (Sn—Pb solder), which forms the join between the metal base and the ceramic substrate, is low at around 35 to 40 MPa, and, when the stress at the solder join portion repeatedly increases with successive heat cycles on account of the difference between the thermal expansion rates of the metal base and the ceramic substrate, this solder eventually burns out.
- the ceramic material of the ceramic substrate soldered onto the metal base is the same: (a) an increase in the plate thickness of the ceramic substrate entails an increase in the strain generated in the solder join portion, and the life before burn-out becomes short (dependence on the thickness of the substrate); (b) an increase in the surface area of the ceramic substrate entails an increase in the strain generated in the solder join portion, and the life before burn-out becomes short (dependence on the surface area of the substrate); (c) an increase in the ratio of the length and breadth of the ceramic substrate entails an increase in the strain generated in the solder join portion, and the life before burn-out becomes short (dependence on the shape of the substrate); and (d) a decrease in the thickness of the solder constituting the solder join layer entails an increase in the strain generated, and the life before burn-out becomes short (dependence on the thickness of the solder).
- thermo conduction rate of the ceramic substrate is 20 W/mK for alumina, 180 to 200 W/mK for aluminum nitride, 70 to 100 W/mK for silicon nitride, and the thermal conduction rate of the copper base is 398 W/mK
- the thermal conduction rate of the solder (Sn—Pb solder), which forms a join between the metal base and the ceramic substrate, is 40 to 50 W/mK.
- a thermal resistance of the solder join portion has a major influence on the thermal conduction in the thermal conduction path between the power semiconductor chip and the metal base.
- the present invention provides a power semiconductor module, including: a metal base including a heat sink; a circuit assembly body including an upper circuit plate, a lower plate, a ceramic plate including an upper surface and a lower surface; a ceramic substrate placed on the metal base including the upper circuit plate and the lower plate, wherein the upper circuit plate and the lower plate are joined to the upper surface and lower surface of the ceramic plate, respectively, and a semiconductor chip, wherein the semiconductor chip is placed on the ceramic substrate; an outer case including terminals formed integrally therein; a join formed between the metal base and the lower plate of the ceramic substrate; and a power semiconductor module assembled by forming a join using solder between the metal base and the ceramic substrate.
- the solder includes a melting point of 183 to 250° C. and the thickness of the solder layer is at least 0.1 mm and no more than 0.3 mm.
- the upper circuit plate and the lower plate are made of metal.
- the metal base includes copper or a copper alloy with a thermal conduction rate of at least 250 W/mK.
- a plate thickness of the metal base includes between about 3.9 mm to 6 mm.
- a thickness of the ceramic plate of the ceramic substrate includes between about 0.1 mm to 0.65 mm, a thickness of the upper circuit plate and of the lower plate includes between about 0.1 mm to 0.5 mm, an overall size of the ceramic substrate includes 50 mm ⁇ 50 mm, and a ratio of a length and a breadth of the ceramic substrate including 1:1 to 1:1.2.
- the ceramic plate of the ceramic substrate is aluminum nitride, and the upper circuit plate and the lower plate are aluminum.
- the ceramic plate of the ceramic substrate is silicon nitride, and the upper circuit plate and the lower plate are copper.
- the power semiconductor module comprises the ceramic plate of the ceramic substrate is alumina, and the upper circuit plate and the lower plate are copper and placing at least one ceramic substrate on the metal base.
- a power semiconductor module including: a metal base including a heat sink; a semiconductor chip; a ceramic substrate; a circuit assembly body including the ceramic substrate, wherein the semiconductor chip is placed on the ceramic substrate which is then placed on the metal base; and an outer case having terminals formed integrally therein, wherein the ceramic substrate is integrally formed on the metal base by successively spray-forming a ceramic layer of the ceramic substrate, and a copper layer of the upper circuit plate, on the surface of the metal base.
- the ceramic layer is any one of alumina, aluminum nitride, and silicon nitride. Aluminum is spray-formed on the surface of the copper layer to form an upper circuit plate bonding pad.
- a power semiconductor module including: a metal base including a heat sink; a semiconductor chip; a ceramic substrate; a circuit assembly body including a ceramic plate, an upper circuit plate, and the ceramic substrate, wherein the semiconductor chip is placed on the ceramic substrate which is then placed on the metal base; and an outer case having terminals formed integrally therein, wherein a casting method integrally molds the metal base on the underside of the ceramic plate of the ceramic substrate, which has no lower plate. and in which the upper circuit plate is joined to the ceramic plate.
- the present invention also provides a power semiconductor module, including: a metal base including a heat sink; a semiconductor chip; a ceramic substrate; a circuit assembly body including the ceramic substrate, wherein the semiconductor chip is placed on the ceramic substrate which is then placed on the metal base; and an outer case having terminals formed integrally therein, wherein an upper circuit plate and the metal base are formed directly by a formation of a layer of molten metal on an upper face and a lower face of the ceramic plate, respectively.
- the present invention also provides a power semiconductor module, including: a metal base including a heat sink; a semiconductor chip; a ceramic substrate; a circuit assembly body including a circuit assembly body including an upper circuit plate, a ceramic plate, and the ceramic substrate, wherein the semiconductor chip is placed on the ceramic substrate which is then placed on the metal base; and an outer case having terminals formed integrally therein, wherein the ceramic substrate has no lower plate and in the ceramic substrate, a silver wax material brazes the upper circuit plate joined to the ceramic plate and the metal base.
- FIG. 1 a is a schematic side view showing an assembly body including a metal base/a ceramic substrate/a power semiconductor chip, relating to a first embodiment of the present invention
- FIG. 1 b is a schematic view showing a planar view of the assembly body of FIG. 1 a;
- FIG. 2 is a figure showing an assembly body including a metal base/a ceramic substrate/a power semiconductor chip, according to a second and a third embodiment of the present invention
- FIG. 3 is a figure showing an assembly body including a metal base/a ceramic substrate/a power semiconductor chip, according to a fourth embodiment of the present invention.
- FIG. 4 is a figure showing a conventional power semiconductor module having an assembly body including a metal base/a ceramic substrate/a power semiconductor chip;
- FIG. 5 a is a figure showing a planar view of a manufactured power semiconductor module having one ceramic substrate, according to the present invention.
- FIG. 5 b is a figure showing a planar view of the manufactured power semiconductor module having one ceramic substrate with an outer enclosing case removed, according to the present invention
- FIG. 6 a is a figure showing an exploded perspective of a manufactured power semiconductor module having two ceramic substrates, according to the present invention.
- FIG. 6 b is a figure showing a side view of the manufactured power semiconductor module having two ceramic substrates with the outer enclosing case removed, according to the present invention
- FIG. 7 a is a figure showing a planar view of a circuit assembly body in the power semiconductor module of FIG. 6 ;
- FIG. 7 b is a figure showing a side view of a circuit assembly body in the power semiconductor module of FIG. 6 ;
- FIG. 8 a is a figure showing a planar view of a manufactured power semiconductor module having six ceramic substrates, according to the present invention.
- FIG. 8 b is a figure showing a cross-sectional view seen from a side of a manufactured power semiconductor module having six ceramic substrates, according to the present invention.
- FIG. 9 a is a figure showing an exploded view of a conventional power semiconductor module.
- FIG. 9 b is a perspective view of an outside of the conventional power semiconductor module of FIG. 9 a in an assembled condition.
- FIG. 1 a is a schematic side view showing an assembly body including a metal base/a ceramic substrate/a power semiconductor chip, relating to a first embodiment of the present invention.
- FIG. 1 b is a schematic view showing a planar view of the assembly body of FIG. 1 a.
- a structure of a ceramic substrate 8 is such that an upper circuit plate 8 b and a lower plate 8 c are joined to the upper surface and lower surface of a ceramic plate 8 a , respectively; and a join is formed using solder between the metal base 1 and the lower plate 8 c of the ceramic substrate 8 .
- the material of the metal base 1 is copper or a copper alloy, which has a thermal conduction rate equal to or greater than 250 W/mK.
- a plate thickness t 1 of this metal base is 3.9 mm to 6 mm.
- a thickness t 2 of the ceramic plate 8 a of the ceramic substrate 8 is 0.1 mm to 0.65 mm, and the thickness of the upper circuit plate 8 b and of the lower plate 8 c is 0.1 mm to 0.5 mm.
- An overall size (a ⁇ b) of the ceramic substrate 8 is set to be at most 50 mm ⁇ 50 mm, and the ratio of the length and breadth thereof is set within a range of 1:1 to 1:1.2.
- the metal base 1 and the ceramic substrate 8 are assembled by forming a join therebetween using solder, where the solder employed is Sn—Pb solder having a melting point of 183 to 250° C. and the thickness of the solder join layer 12 is 0.1 to 0.3 mm.
- the ceramic substrate 8 may include the ceramic substrate 8 .
- the material of the ceramic plate 8 a may be aluminum nitride, and the material of the upper circuit plate 8 b and the lower plate 8 c , which are joined to the upper side and the lower side of the ceramic plate 8 a , may be aluminum;
- the material of the ceramic plate 8 a may be silicon nitride, and the material of the upper circuit plate 8 b and the lower plate 8 c may be copper; and (3) the material of the ceramic plate 8 a may be alumina, and the material of the upper circuit plate 8 b and the lower plate 8 c may be copper.
- a power semiconductor module includes: the material of the metal base 1 and the ceramic substrate 8 , the size thereof, and the material and thickness of the solder, as described above.
- FIG. 5 a and FIG. 5 b show examples of manufactured products in which a power circuit block 5 is includes one ceramic substrate 8 mounted on a metal base 1 , where the metal base 1 is made from a copper alloy and has a plate thickness of 4 mm, and an overall size of length 86 mm and breadth 107 mm.
- the ceramic plate 8 a of the ceramic substrate 8 is an alumina plate with a plate thickness of 0.32 mm, and an overall size of length 51 mm and breadth 50 mm, where the length to breadth ratio is 1:1.02.
- a join is formed using Sn—Pb solder between the metal base 1 and the ceramic substrate 8 , where a thickness of the solder join layer is 0.15 mm.
- the power circuit block 5 is divided into two ceramic substrates 8 , which are placed side by side on the metal base 1 , where the metal base 1 is made from a copper alloy having a plate thickness of 4 mm and an overall size of length 68 mm and breadth 98 mm.
- ceramic plates of the ceramic substrates 8 may be alumina plates with a thickness of 0.25 mm, and an overall size of a ceramic plate of the ceramic substrate 8 positioned on a left of the power circuit block 5 may include: a length of 38 mm and a width of 33 mm.
- An overall size of a ceramic plate of ceramic substrate 8 positioned on a left of the power circuit block 5 may include: a length of 38 mm, a width of 39 mm, where a length to breadth ratio of the left and right plates may be 1:1.15 and 1:1.02, respectively.
- a join is formed using Sn—Pb solder between the metal base 1 and each of the ceramic substrates 8 , respectively, positioned on the left and right of the power circuit block 5 , where the thickness of the solder join layer may be 0.15 mm.
- the power circuit block 5 is divided into six ceramic substrates 8 , which are placed side by side on the metal base 1 , where the metal base 1 may be made from a copper alloy with a plate thickness of 4 mm, and with an overall size of length 122 mm and breadth 162 mm.
- a ceramic plate of each of these ceramic substrates 8 is an alumina plate with a thickness of 0.32 mm, and with an overall size of length 38 mm, and width 41.9 mm, where the length to breadth ratio of these plates is 1:1.1.
- a join is formed using Sn—Pb solders between the metal base 1 and each of the ceramic substrates 8 , where the thickness of the solder join layer is 0.15 mm.
- FIG. 2 A second embodiment of the present invention will be described hereinbelow referring to FIG. 2 .
- the ceramic substrate 8 is integrally molded directly onto the metal base 1 using the method described below.
- a ceramic layer which corresponds to the ceramic plate 8 a and having thickness of 0.1 to 0.65 mm, is formed covering and adhering to the surface of the metal base 1 .
- copper is spray-formed, using the plasma spray-forming method, on this ceramic layer, where a copper layer, which corresponds to the upper circuit plate 8 b and has a thickness of 0.1 to 0.5 mm, is formed as a lamination layer thereon.
- copper, aluminum or molybdenum, or a combination of these materials may be employed for the metal base 1 .
- the above-mentioned ceramic layer and copper layer which are formed on the metal base using the plasma spray-forming method, correspond to the ceramic plate 8 a of the ceramic substrate 8 , and the upper circuit plate 8 b , respectively.
- a power semiconductor chip 9 for example, is mounted using solder on this upper circuit plate 8 b . It is also possible to form a bonding pad by spray-forming an alumina layer on the copper layer.
- the ceramic layer which is spray-formed on the metal base 1 , is not restricted to one particular kind of ceramic material.
- Alumina for example, may be spray-formed on the metal base 1 , and, subsequently, aluminum nitride, silicon nitride or another insulating material may be spray-formed on the resulting laminated metal base 1 to form lamination layers.
- a ceramic substrate 8 which has no lower plate and in which an upper circuit plate 8 b is made using copper foil or the like, is joined to the surface of a ceramic plate 8 a , and has a metal base 1 integrally molded with the underside of the ceramic plate 8 a using a casting method.
- the metal base 1 is made from aluminum (melting point: 500 to 700° C.), which has a lower melting point than copper (melting point: 1085° C.).
- the underside of the ceramic plate 8 a of the ceramic substrate 8 is set in a mold.
- the mold is full of molten metal that is to be the material of the metal base, such that the underside of this ceramic plate is soaked with this molten metal, and the metal base 1 is cast in these conditions alone.
- a metal base 1 is thus formed that is integrally connected to the ceramic substrate 8 .
- a metal base 1 and a ceramic substrate 8 which has no lower plate and in which an upper circuit plate 8 b has already been joined to a ceramic plate 8 a , are combined using silver wax 13 .
- This fixing operation using wax involves inserting silver wax in the form of a sheet or a cream between the metal base 1 and the ceramic plate 8 a of the ceramic substrate 8 , and then introducing the resulting assembly into a reflow furnace to cause this fixing using wax.
- the thermal conduction rate of the silver wax material is equal to or greater than 300 W/mK, which is at least six times higher than the thermal conduction rate of 40 to 50 W/mK of Sn—Pb solder. Therefore, in addition to being able to obtain a high degree of heat dissipation in comparison with the conventional structure shown in FIG. 4 , a yield strength is high in comparison with that of solder, and reliability with respect to burn-out is also improved.
- the second through fourth embodiments described above may be applied to each of the different types of manufactured power semiconductor module shown in FIGS. 5 through 8 .
- the following are optimally set: the material of the ceramic substrate, which has a power semiconductor chip mounted thereon, and of the metal base for radiating heat, which is a heat sink; the dimensions thereof; the solder material, which joins the ceramic substrate and the metal base; and the thickness of the solder layer.
- the material of the ceramic substrate which has a power semiconductor chip mounted thereon, and of the metal base for radiating heat, which is a heat sink
- the dimensions thereof the solder material, which joins the ceramic substrate and the metal base
- the thickness of the solder layer Such a constitution makes it possible to obtain a high degree of heat radiation and to reduce thermal strain, which is generated between the ceramic substrate/metal base with successive heat cycles during electrification of the power semiconductor module. Further, the constitution ensures the required insulation resistance. It is thus possible to obtain a power semiconductor module that satisfies the conditions of high reliability and durability that are required for use, for example, in vehicles.
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Abstract
A power semiconductor module has a circuit assembly body, which includes a metal base, a ceramic substrate, and a power semiconductor chip, and is combined with a package having terminals formed integrally. The ceramic substrate of the module has a structure such that an upper circuit plate and a lower plate are joined to both sides of a ceramic plate, respectively, and the metal base and the ceramic substrate are fixed to one another using solder, thereby improving reliability and lengthening a life of a power semiconductor module by optimizing a ceramic substrate and a metal base thereof, the dimensions thereof, and material and method used for a join formed between the ceramic substrate and metal base.
Description
- This application is a divisional application of U.S. Pat. No. 6,690,087 filed Dec. 28, 2001, now issued and incorporated by reference herein.
- 1. Field of the Invention
- The present invention relates to a power semiconductor module that may be applied to a converter or inverter of a power switching device, for example.
- 2. Description of the Related Art
- First, the assembled structure of a conventional example of such a power semiconductor module (in which six elements form a structure for three circuits), will now be described using
FIGS. 9 a and 9 b. In the figures, a metal base (copper base plate) 1 is provided for radiating heat, which is a heat sink, anouter case 2 is provided having terminals formed integrally, and amain circuit terminal 3 is provided in this outer enclosingcase 2. Acontrol terminal 4, apower circuit block 5, acontrol circuit block 6, andbonding wires 7 including internal wiring are also provided. -
FIGS. 9 a and 9 b illustrate thepower circuit block 5 having six of each of apower semiconductor chip 9, such as an IGBT, and a free-wheeling diode 10, mounted on aceramic substrate 8 that is in the shape of a rectangular oblong. Further, as shown by the schematic view ofFIG. 4 , theceramic substrate 8 is a direct copper bonding substrate including anupper circuit plate 8 b, and alower plate 8 c, which are plated with copper foil and are directly joined to the upper surface and lower surface, respectively, of aceramic plate 8 a made from alumina, aluminum nitride or silicon nitride. A semiconductor pattern is formed on theupper circuit plate 8 b. Thesemiconductor chips 9 are mounted on theupper circuit plate 8 b via asolder join layer 11 including solder. Referring toFIGS. 9 a and 9 b, thecontrol circuit 6 is made such that drive ICs 6 b, which are for driving power circuit elements, and circuit components associated with these drive ICs, are mounted on a U-shaped printedsubstrate 6 a surrounding thepower circuit block 5. - In addition, the
power circuit block 5 and thecontrol circuit block 6 are placed side by side on ametal base 1. Thereupon, thelower plate 8 c of theceramic substrate 8, on thepower circuit block 5, and themetal base 1 are joined using Sn—Pb solder (this solder is represented by “12”) to conduct heat generated by thepower semiconductor chips 9 to themetal base 1 via theceramic substrate 8. Further, the printedsubstrate 6 a of thecontrol circuit block 6 is affixed to themetal base 1 using an adhesive. - The
outer case 2 having terminals integrally formed therein is joined to themetal base 1 using an adhesive. Specifically, theouter case 2 is placed over thepower circuit block 5 and thecontrol circuit block 6 is mounted on themetal base 1 so as to enclose thepower circuit block 5 and thecontrol circuit block 6. Theinner lead portions 3 a of themain circuit terminals 3 are soldered to the printed pattern of theceramic substrate 8, andcontrol terminals 4 become internal wiring as a result ofbonding wires 7 to the printed pattern of the printedsubstrate 6. Further, after a gel-like filler material (silicon gel, for example), has been injected into the outer enclosingcase 2 to seal off each of the circuit blocks using resin, the outer enclosing case is covered with a lid (not shown) to thus complete the power semiconductor module. - Power semiconductor modules like those mentioned above are extensively employed in various fields, from low-capacity devices for everyday use to high-capacity devices which are used industrially or in vehicles, for example. In such cases, low-capacity modules for everyday-use, for which the degree of reliability required is not particularly high, and in which the amount of heat generated by power semiconductor elements is limited, can be designed and manufactured with barely any restrictions being placed on the material and size of each of the components. On the other hand, where high-capacity modules are concerned, which are typically used in power circuits of vehicle drive devices, there is sometimes an increased amount of heat generated per unit area of power chips in the high-capacity modules. Because the size of such power chips is smaller and more compact, there is a demand for high reliability and long life in high-capacity modules compared to the low-capacity modules in products manufactured for everyday use.
- For example, a heat cycle test to which manufactured power modules are subjected to include conditions for one heat cycle: −40° C. (60 minutes), followed by room temperature (30 minutes), followed by 125° C. (60 minutes), and followed by room temperature (30 minutes). In contrast, ordinary general-purpose products are subjected to a test of around 100 cycles. Accordingly, the reliability required for products manufactured for vehicle drive devices is such that such products must sufficiently withstand a heat cycle test of 3000 cycles.
- Satisfying these requirements of high reliability and long life naturally means improving the reliability of the power semiconductor chips themselves. In addition, a pressing problem regarding these power semiconductor chips includes ensuring a durability that can sufficiently withstand high levels of heat radiation, and the severe heat cycles accompanying the motion of the vehicle, at the same time as ensuring the required electrical insulation resistance.
- In a structure in which a
ceramic substrate 8 mounted on ametal base 1 is joined thereto with solder, as shown inFIG. 4 , the problems set forth above are accompanied by the problems noted hereinbelow. - (1) Thermal stress attributable to a difference in the thermal expansion of the ceramic substrate/metal base: specifically, while a rate of thermal expansion of the ceramic substrate is 7 ppm/K for alumina, 4.5 ppm/K for aluminum nitride, and 3 ppm/K for silicon nitride, a rate of thermal expansion of the metal base (copper base) is 16.5 ppm/K, which provides for a large difference between the thermal expansion rates of the ceramic substrate and the metal base. Meanwhile, the yield strength of the solder (Sn—Pb solder), which forms the join between the metal base and the ceramic substrate, is low at around 35 to 40 MPa, and, when the stress at the solder join portion repeatedly increases with successive heat cycles on account of the difference between the thermal expansion rates of the metal base and the ceramic substrate, this solder eventually burns out.
- In addition, with regard to a life of the solder until burn-out, after performing various testing on the life of the solder in addition to a corresponding analysis, it has been established that there was a tendency for the life of the solder to be heavily dependent on the conditions below. In other words, assuming that the ceramic material of the ceramic substrate soldered onto the metal base is the same: (a) an increase in the plate thickness of the ceramic substrate entails an increase in the strain generated in the solder join portion, and the life before burn-out becomes short (dependence on the thickness of the substrate); (b) an increase in the surface area of the ceramic substrate entails an increase in the strain generated in the solder join portion, and the life before burn-out becomes short (dependence on the surface area of the substrate); (c) an increase in the ratio of the length and breadth of the ceramic substrate entails an increase in the strain generated in the solder join portion, and the life before burn-out becomes short (dependence on the shape of the substrate); and (d) a decrease in the thickness of the solder constituting the solder join layer entails an increase in the strain generated, and the life before burn-out becomes short (dependence on the thickness of the solder).
- (2) Thermal conductivity between the ceramic substrate/metal base: The heat generated by the power semiconductor chip is thermally conducted via the ceramic substrate to the metal base, which functions as a heat sink, and is radiated from the metal base to the outside. Consequently, it is necessary to keep the resistance to thermal conduction as low as possible between the ceramic substrate and the metal base.
- Accordingly, (a) while a thermal conduction rate of the ceramic substrate is 20 W/mK for alumina, 180 to 200 W/mK for aluminum nitride, 70 to 100 W/mK for silicon nitride, and the thermal conduction rate of the copper base is 398 W/mK, the thermal conduction rate of the solder (Sn—Pb solder), which forms a join between the metal base and the ceramic substrate, is 40 to 50 W/mK. As a result, a thermal resistance of the solder join portion has a major influence on the thermal conduction in the thermal conduction path between the power semiconductor chip and the metal base. (b) Further, upon soldering the ceramic substrate onto the metal base, when voids (air bubbles) are generated in the solder join layer, these voids provide for a thermal resistance and therefore obstruct the radiation of heat. Consequently, an increase in the thickness of the solder layer of the solder join layer entails lower heat radiation, which has an adverse effect on the reliability and durability of the module.
- It is therefore an object of the present invention to provide a power semiconductor module in which the material of the ceramic substrate and the metal base, the dimensions thereof, the material for joining the ceramic substrate and the metal base, and the joining method, are optimized on the basis of an analysis of the results of each of the above-mentioned tests, and in which module the thermal strain, which is generated between the ceramic substrate and the metal base with successive heat cycles, is alleviated and thermal conductivity is improved, thus it becomes possible to ensure the high degree of reliability and long life that are required for use in vehicles.
- The present invention provides a power semiconductor module, including: a metal base including a heat sink; a circuit assembly body including an upper circuit plate, a lower plate, a ceramic plate including an upper surface and a lower surface; a ceramic substrate placed on the metal base including the upper circuit plate and the lower plate, wherein the upper circuit plate and the lower plate are joined to the upper surface and lower surface of the ceramic plate, respectively, and a semiconductor chip, wherein the semiconductor chip is placed on the ceramic substrate; an outer case including terminals formed integrally therein; a join formed between the metal base and the lower plate of the ceramic substrate; and a power semiconductor module assembled by forming a join using solder between the metal base and the ceramic substrate.
- The solder includes a melting point of 183 to 250° C. and the thickness of the solder layer is at least 0.1 mm and no more than 0.3 mm. The upper circuit plate and the lower plate are made of metal. The metal base includes copper or a copper alloy with a thermal conduction rate of at least 250 W/mK. A plate thickness of the metal base includes between about 3.9 mm to 6 mm. A thickness of the ceramic plate of the ceramic substrate includes between about 0.1 mm to 0.65 mm, a thickness of the upper circuit plate and of the lower plate includes between about 0.1 mm to 0.5 mm, an overall size of the ceramic substrate includes 50 mm×50 mm, and a ratio of a length and a breadth of the ceramic substrate including 1:1 to 1:1.2.
- The ceramic plate of the ceramic substrate is aluminum nitride, and the upper circuit plate and the lower plate are aluminum. The ceramic plate of the ceramic substrate is silicon nitride, and the upper circuit plate and the lower plate are copper. The power semiconductor module comprises the ceramic plate of the ceramic substrate is alumina, and the upper circuit plate and the lower plate are copper and placing at least one ceramic substrate on the metal base.
- The present invention is also achieved by a power semiconductor module, including: a metal base including a heat sink; a semiconductor chip; a ceramic substrate; a circuit assembly body including the ceramic substrate, wherein the semiconductor chip is placed on the ceramic substrate which is then placed on the metal base; and an outer case having terminals formed integrally therein, wherein the ceramic substrate is integrally formed on the metal base by successively spray-forming a ceramic layer of the ceramic substrate, and a copper layer of the upper circuit plate, on the surface of the metal base. The ceramic layer is any one of alumina, aluminum nitride, and silicon nitride. Aluminum is spray-formed on the surface of the copper layer to form an upper circuit plate bonding pad.
- The present invention is also achieved by a power semiconductor module, including: a metal base including a heat sink; a semiconductor chip; a ceramic substrate; a circuit assembly body including a ceramic plate, an upper circuit plate, and the ceramic substrate, wherein the semiconductor chip is placed on the ceramic substrate which is then placed on the metal base; and an outer case having terminals formed integrally therein, wherein a casting method integrally molds the metal base on the underside of the ceramic plate of the ceramic substrate, which has no lower plate. and in which the upper circuit plate is joined to the ceramic plate.
- The present invention also provides a power semiconductor module, including: a metal base including a heat sink; a semiconductor chip; a ceramic substrate; a circuit assembly body including the ceramic substrate, wherein the semiconductor chip is placed on the ceramic substrate which is then placed on the metal base; and an outer case having terminals formed integrally therein, wherein an upper circuit plate and the metal base are formed directly by a formation of a layer of molten metal on an upper face and a lower face of the ceramic plate, respectively.
- The present invention also provides a power semiconductor module, including: a metal base including a heat sink; a semiconductor chip; a ceramic substrate; a circuit assembly body including a circuit assembly body including an upper circuit plate, a ceramic plate, and the ceramic substrate, wherein the semiconductor chip is placed on the ceramic substrate which is then placed on the metal base; and an outer case having terminals formed integrally therein, wherein the ceramic substrate has no lower plate and in the ceramic substrate, a silver wax material brazes the upper circuit plate joined to the ceramic plate and the metal base.
- These together with other objects and advantages, which will be subsequently apparent, reside in the details of construction and operation as more fully hereinafter described and claimed, reference being had to the accompanying drawings forming a part hereof, wherein like numerals refer to like parts throughout.
- The above objective and advantage of the present invention will become more apparent by describing in detail preferred embodiments thereof with reference to the attached drawings in which:
-
FIG. 1 a is a schematic side view showing an assembly body including a metal base/a ceramic substrate/a power semiconductor chip, relating to a first embodiment of the present invention; -
FIG. 1 b is a schematic view showing a planar view of the assembly body ofFIG. 1 a; -
FIG. 2 is a figure showing an assembly body including a metal base/a ceramic substrate/a power semiconductor chip, according to a second and a third embodiment of the present invention; -
FIG. 3 is a figure showing an assembly body including a metal base/a ceramic substrate/a power semiconductor chip, according to a fourth embodiment of the present invention; -
FIG. 4 is a figure showing a conventional power semiconductor module having an assembly body including a metal base/a ceramic substrate/a power semiconductor chip; -
FIG. 5 a is a figure showing a planar view of a manufactured power semiconductor module having one ceramic substrate, according to the present invention; -
FIG. 5 b is a figure showing a planar view of the manufactured power semiconductor module having one ceramic substrate with an outer enclosing case removed, according to the present invention; -
FIG. 6 a is a figure showing an exploded perspective of a manufactured power semiconductor module having two ceramic substrates, according to the present invention; -
FIG. 6 b is a figure showing a side view of the manufactured power semiconductor module having two ceramic substrates with the outer enclosing case removed, according to the present invention; -
FIG. 7 a is a figure showing a planar view of a circuit assembly body in the power semiconductor module ofFIG. 6 ; -
FIG. 7 b is a figure showing a side view of a circuit assembly body in the power semiconductor module ofFIG. 6 ; -
FIG. 8 a is a figure showing a planar view of a manufactured power semiconductor module having six ceramic substrates, according to the present invention; -
FIG. 8 b is a figure showing a cross-sectional view seen from a side of a manufactured power semiconductor module having six ceramic substrates, according to the present invention; -
FIG. 9 a is a figure showing an exploded view of a conventional power semiconductor module; and -
FIG. 9 b is a perspective view of an outside of the conventional power semiconductor module ofFIG. 9 a in an assembled condition. - Reference will be now made in detail to the present exemplary embodiments of the present invention, examples of which are illustrated in the accompanying drawings. Further, a description has been omitted for members corresponding to
FIGS. 4 through 9 and to which the same reference numerals have been assigned in each of the embodiments. -
FIG. 1 a is a schematic side view showing an assembly body including a metal base/a ceramic substrate/a power semiconductor chip, relating to a first embodiment of the present invention.FIG. 1 b is a schematic view showing a planar view of the assembly body ofFIG. 1 a. A structure of aceramic substrate 8 is such that anupper circuit plate 8 b and alower plate 8 c are joined to the upper surface and lower surface of aceramic plate 8 a, respectively; and a join is formed using solder between themetal base 1 and thelower plate 8 c of theceramic substrate 8. - Here, the material of the
metal base 1 is copper or a copper alloy, which has a thermal conduction rate equal to or greater than 250 W/mK. A plate thickness t1 of this metal base is 3.9 mm to 6 mm. A thickness t2 of theceramic plate 8 a of theceramic substrate 8 is 0.1 mm to 0.65 mm, and the thickness of theupper circuit plate 8 b and of thelower plate 8 c is 0.1 mm to 0.5 mm. An overall size (a×b) of theceramic substrate 8 is set to be at most 50 mm×50 mm, and the ratio of the length and breadth thereof is set within a range of 1:1 to 1:1.2. Further, themetal base 1 and theceramic substrate 8 are assembled by forming a join therebetween using solder, where the solder employed is Sn—Pb solder having a melting point of 183 to 250° C. and the thickness of thesolder join layer 12 is 0.1 to 0.3 mm. - Further, combining materials such as those detailed hereinafter may include the
ceramic substrate 8. Specifically, (1) the material of theceramic plate 8 a may be aluminum nitride, and the material of theupper circuit plate 8 b and thelower plate 8 c, which are joined to the upper side and the lower side of theceramic plate 8 a, may be aluminum; (2) the material of theceramic plate 8 a may be silicon nitride, and the material of theupper circuit plate 8 b and thelower plate 8 c may be copper; and (3) the material of theceramic plate 8 a may be alumina, and the material of theupper circuit plate 8 b and thelower plate 8 c may be copper. - Furthermore, a power semiconductor module, as exemplified in
FIGS. 5 a through 8 b, includes: the material of themetal base 1 and theceramic substrate 8, the size thereof, and the material and thickness of the solder, as described above. By way of example,FIG. 5 a andFIG. 5 b show examples of manufactured products in which apower circuit block 5 is includes oneceramic substrate 8 mounted on ametal base 1, where themetal base 1 is made from a copper alloy and has a plate thickness of 4 mm, and an overall size of length 86 mm and breadth 107 mm. Further, theceramic plate 8 a of theceramic substrate 8 is an alumina plate with a plate thickness of 0.32 mm, and an overall size of length 51 mm and breadth 50 mm, where the length to breadth ratio is 1:1.02. A join is formed using Sn—Pb solder between themetal base 1 and theceramic substrate 8, where a thickness of the solder join layer is 0.15 mm. - In addition, in the example of a manufactured product shown in
FIGS. 6 a and 6 b, andFIGS. 7 a and 7 b, thepower circuit block 5 is divided into twoceramic substrates 8, which are placed side by side on themetal base 1, where themetal base 1 is made from a copper alloy having a plate thickness of 4 mm and an overall size of length 68 mm and breadth 98 mm. In turn, ceramic plates of theceramic substrates 8 may be alumina plates with a thickness of 0.25 mm, and an overall size of a ceramic plate of theceramic substrate 8 positioned on a left of thepower circuit block 5 may include: a length of 38 mm and a width of 33 mm. An overall size of a ceramic plate ofceramic substrate 8 positioned on a left of thepower circuit block 5 may include: a length of 38 mm, a width of 39 mm, where a length to breadth ratio of the left and right plates may be 1:1.15 and 1:1.02, respectively. Further, a join is formed using Sn—Pb solder between themetal base 1 and each of theceramic substrates 8, respectively, positioned on the left and right of thepower circuit block 5, where the thickness of the solder join layer may be 0.15 mm. - Further, in the example of a manufactured product shown in
FIGS. 8 a and 8 b, thepower circuit block 5 is divided into sixceramic substrates 8, which are placed side by side on themetal base 1, where themetal base 1 may be made from a copper alloy with a plate thickness of 4 mm, and with an overall size of length 122 mm and breadth 162 mm. Further, a ceramic plate of each of theseceramic substrates 8 is an alumina plate with a thickness of 0.32 mm, and with an overall size of length 38 mm, and width 41.9 mm, where the length to breadth ratio of these plates is 1:1.1. A join is formed using Sn—Pb solders between themetal base 1 and each of theceramic substrates 8, where the thickness of the solder join layer is 0.15 mm. - A second embodiment of the present invention will be described hereinbelow referring to
FIG. 2 . In this embodiment, without using solder in a formation of a join between themetal base 1 and theceramic substrate 8, theceramic substrate 8 is integrally molded directly onto themetal base 1 using the method described below. - Specifically, by spray-forming a ceramic material such as alumina, aluminum nitride or silicon nitride onto the surface of the metal base 1 (one face thereof) by means of a plasma spray-forming method, a ceramic layer, which corresponds to the
ceramic plate 8 a and having thickness of 0.1 to 0.65 mm, is formed covering and adhering to the surface of themetal base 1. Next, copper is spray-formed, using the plasma spray-forming method, on this ceramic layer, where a copper layer, which corresponds to theupper circuit plate 8 b and has a thickness of 0.1 to 0.5 mm, is formed as a lamination layer thereon. Further, copper, aluminum or molybdenum, or a combination of these materials, may be employed for themetal base 1. - Further, the above-mentioned ceramic layer and copper layer, which are formed on the metal base using the plasma spray-forming method, correspond to the
ceramic plate 8 a of theceramic substrate 8, and theupper circuit plate 8 b, respectively. Apower semiconductor chip 9, for example, is mounted using solder on thisupper circuit plate 8 b. It is also possible to form a bonding pad by spray-forming an alumina layer on the copper layer. - By means of such a constitution, since there is no solder layer interposed between the
metal base 1 and theceramic substrate 8, thermal resistance is diminished by an amount representing this solder or the like, and the heat radiation is thereby improved. In addition, since no solder join is employed, the soldering process and the solder material are omitted, and the problems of an increase in the thermal resistance attributable to voids in the solder layer, and of the solder join layer burning out as a result of thermal strain therein, are also resolved. - The ceramic layer, which is spray-formed on the
metal base 1, is not restricted to one particular kind of ceramic material. Alumina, for example, may be spray-formed on themetal base 1, and, subsequently, aluminum nitride, silicon nitride or another insulating material may be spray-formed on the resultinglaminated metal base 1 to form lamination layers. - Next, a third embodiment of the present invention, will be described through reference to
FIG. 2 . In this embodiment, aceramic substrate 8, which has no lower plate and in which anupper circuit plate 8 b is made using copper foil or the like, is joined to the surface of aceramic plate 8 a, and has ametal base 1 integrally molded with the underside of theceramic plate 8 a using a casting method. Themetal base 1 is made from aluminum (melting point: 500 to 700° C.), which has a lower melting point than copper (melting point: 1085° C.). - In this casting method, the underside of the
ceramic plate 8 a of theceramic substrate 8 is set in a mold. The mold is full of molten metal that is to be the material of the metal base, such that the underside of this ceramic plate is soaked with this molten metal, and themetal base 1 is cast in these conditions alone. Ametal base 1 is thus formed that is integrally connected to theceramic substrate 8. - In this embodiment, similarly to the second embodiment described above, because no solder layer is interposed between the
metal base 1 and theceramic substrate 8, the problems of an increase in the thermal resistance, and of the solder join layer burning out as a result of thermal strain therein, are also resolved. - As an applied example of this embodiment in which a casting method is employed, it is possible to use molten metal to integrally form an
upper circuit plate 8 b and ametal base 1 on the upper face and lower face of theceramic plate 8 a, respectively. - Next, a fourth embodiment of the present invention, will be described using
FIG. 3 . In this embodiment, ametal base 1 and aceramic substrate 8, which has no lower plate and in which anupper circuit plate 8 b has already been joined to aceramic plate 8 a, are combined usingsilver wax 13. This fixing operation using wax involves inserting silver wax in the form of a sheet or a cream between themetal base 1 and theceramic plate 8 a of theceramic substrate 8, and then introducing the resulting assembly into a reflow furnace to cause this fixing using wax. - In this constitution, the thermal conduction rate of the silver wax material is equal to or greater than 300 W/mK, which is at least six times higher than the thermal conduction rate of 40 to 50 W/mK of Sn—Pb solder. Therefore, in addition to being able to obtain a high degree of heat dissipation in comparison with the conventional structure shown in
FIG. 4 , a yield strength is high in comparison with that of solder, and reliability with respect to burn-out is also improved. Moreover, similarly to the first embodiment, the second through fourth embodiments described above may be applied to each of the different types of manufactured power semiconductor module shown inFIGS. 5 through 8 . - As described above, the following effects are afforded by the present invention:
- (1) The following are optimally set: the material of the ceramic substrate, which has a power semiconductor chip mounted thereon, and of the metal base for radiating heat, which is a heat sink; the dimensions thereof; the solder material, which joins the ceramic substrate and the metal base; and the thickness of the solder layer. Such a constitution makes it possible to obtain a high degree of heat radiation and to reduce thermal strain, which is generated between the ceramic substrate/metal base with successive heat cycles during electrification of the power semiconductor module. Further, the constitution ensures the required insulation resistance. It is thus possible to obtain a power semiconductor module that satisfies the conditions of high reliability and durability that are required for use, for example, in vehicles.
- (2) Further, in the embodiments in which no solder is employed in the joining together of the metal base and the ceramic substrate, and the lower plate of the ceramic substrate is omitted such that a direct join is made with the metal base, because there is nothing interposed between the metal base and the ceramic substrate, such as solder, the thermal resistance is reduced by an amount representing this solder or the like, and the heat radiation is thereby improved. In addition, because no solder join is employed, the soldering process and the solder material are omitted. Accordingly, the problems of an increase in the thermal resistance attributable to voids in the solder layer and of the solder join layer burning out as a result of thermal strain therein are also resolved.
- (3) Moreover, in the embodiments in which a metal base and a ceramic substrate are fixed together using silver wax material, it is possible to afford the module excellent heat radiation in comparison with a module which is joined together using solder, as well as high durability with respect to burn-out.
Claims (2)
1. A power semiconductor module, comprising:
a metal base comprising a heat sink;
a semiconductor chip;
a ceramic substrate;
a circuit assembly body comprising
a circuit assembly body comprising
an upper circuit plate,
a ceramic plate, and
the ceramic substrate, wherein the semiconductor chip is placed on the ceramic substrate which is then placed on the metal base; and
an outer case having terminals formed integrally therein,
wherein the ceramic substrate has no lower plate and in the ceramic substrate, a silver wax material brazes the upper circuit plate joined to the ceramic plate and the metal base.
2. The power semiconductor module according to claim 1 , wherein the power semiconductor module comprises placing at least one ceramic substrate on the metal base.
Priority Applications (1)
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US11/142,471 US20050218426A1 (en) | 2000-12-28 | 2005-06-02 | Power semiconductor module |
Applications Claiming Priority (4)
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JP2000402127A JP2002203942A (en) | 2000-12-28 | 2000-12-28 | Power semiconductor module |
JP2000-402127 | 2000-12-28 | ||
US10/028,263 US6690087B2 (en) | 2000-12-28 | 2001-12-28 | Power semiconductor module ceramic substrate with upper and lower plates attached to a metal base |
US11/142,471 US20050218426A1 (en) | 2000-12-28 | 2005-06-02 | Power semiconductor module |
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US10/028,263 Division US6690087B2 (en) | 2000-12-28 | 2001-12-28 | Power semiconductor module ceramic substrate with upper and lower plates attached to a metal base |
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US20050218426A1 true US20050218426A1 (en) | 2005-10-06 |
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US10/621,547 Expired - Lifetime US6914325B2 (en) | 2000-12-28 | 2003-07-18 | Power semiconductor module |
US11/142,471 Abandoned US20050218426A1 (en) | 2000-12-28 | 2005-06-02 | Power semiconductor module |
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US10/621,547 Expired - Lifetime US6914325B2 (en) | 2000-12-28 | 2003-07-18 | Power semiconductor module |
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Also Published As
Publication number | Publication date |
---|---|
US20020109152A1 (en) | 2002-08-15 |
JP2002203942A (en) | 2002-07-19 |
US6690087B2 (en) | 2004-02-10 |
US20040017005A1 (en) | 2004-01-29 |
DE10162966A1 (en) | 2002-07-04 |
US6914325B2 (en) | 2005-07-05 |
US20090166851A1 (en) | 2009-07-02 |
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