This application is a National Stage of International Application No. PCT/JP2013/054207, filed Feb. 20, 2013, the contents of which are incorporated herein by reference in its entirety.
The present invention relates to a cooling device and a power module equipped with the cooling device and, more particularly, to a cooling device for a power module on which power semiconductor chips are mounted.
Conventionally, a technique has been disclosed in which the motor drive is mainly controlled by configuring an inverter circuit from a power module on which power semiconductor chips are mounted and by performing a switching operation on direct-current power and thereby converting the direct-current power into alternating-current power (Patent Literature 1). An electric current instantaneously flows to only a few specific chips in the power module to generate heat. However, the heat-generating chips are instantaneously switched; therefore, usually, the chips generate heat equally. On the other hand, in particular, in driving of a servomotor, there are many cases, such as a case of holding a heavy object, where electric power is supplied to the motor without involving rotation of the motor. In such cases, an electric current concentratedly flows to a few specific chips in a module and the amount of heat generation locally increases. There is a demand for a cooling device having high heat radiation properties that can efficiently and quickly diffuse and radiate heat even in such cases.
As such a cooling device, conventionally, there is a cooling device in which a material having a high thermal conductivity is used to obtain a structure having high heat radiation properties. For example, in Patent Literature 1, a heat radiation plate is configured from two graphite layers. A high thermal conductivity is obtained in the horizontal direction in the first layer and obtained in the vertical direction in the second layer, thereby increasing the heat radiation properties.
Patent Literature 1: Japanese Patent Application Laid-Open No. 2012-069670
However, according to the conventional technique described above, there is a problem in that, when the module is reduced in size by, for example, use of a wide band gap semiconductor and a few chips having a large amount of heat generation are disposed close to one another, heat interference among the chips occurs and the temperature of the chips rises.
In Patent Literature 1, because the thermal conductivity in the vertical direction of the first graphite layer is low, the thickness in the vertical direction of the first layer has to be reduced. Therefore, the thermal conduction properties in the horizontal direction are also deteriorated and thus it is difficult to immediately uniformly diffuse heat to the end of a heat sink. Because directions in which the thermal conductivity is high are limited to the two directions in this way, there is a problem in that it is difficult to diffuse heat to the entire heat sink.
The present invention has been devised in view of the above and it is an object of the present invention to obtain a cooling device that can immediately diffuse heat to the entire heat sink without causing heat interference among heat chips that generate heat and to obtain a power module including the cooling device.
In order to solve the above problems and achieve the object, an aspect of the present invention is a cooling device for cooling a power module including first and second chips that generate heat, the cooling device comprising a heat sink including a base surface on which the power module is closely attached and mounted, wherein the heat sink includes: a main body including the base surface; and first and second high heat conductors that have a thermal conductivity higher than a thermal conductivity of the main body, and the first and second chips are respectively in contact with one ends of the first and second high heat conductors and respectively connected to independent heat dispersion routes via the first and second high heat conductors.
The cooling device according to the present invention attains an effect that, even when the amount of heat generation locally increases in a few specific chips, the first chip having the largest amount of heat generation can be cooled without substantially being affected by the second chip having the second largest amount of heat generation and thus it is possible to immediately uniformly diffuse heat to the entire heat sink.
Exemplary embodiments of a cooling device and a power module equipped with the cooling device according to the present invention are explained in detail below with reference to the drawings. Note that the present invention is not limited to the embodiments and can be modified as appropriate without departing from the scope of the invention. In the drawings explained below, for easier understanding, scales of respective members may be shown differently from those of actual products.
First Embodiment.
The cooling device 10 includes the heat sink 2 configured from a plurality of flat fins 3 made of, for example, aluminum and the main body 1. The power module 20 is provided on the base surface 1A, which is a surface opposite to a formation surface 1B of the flat fins 3 of the main body 1. The power module 20 configures, for example, an inverter circuit and performs a switching operation on direct-current power to convert the direct-current power into alternating-current power, thereby controlling the motor drive. In the power module 20, six chips made of power semiconductors functioning as heat generating bodies are mounted on a wiring board 21. Usually, an electric current instantaneously flows to only a few specific chips in the power module 20 to generate heat. However, the heat-generating chips are instantaneously switched; therefore, the chips generate heat equally. On the other hand, for example, in driving of a servomotor, there are cases, such as a case of holding a heavy object, where electric power is supplied to the motor without involving rotation of the motor. In such cases, an electric current concentratedly flows to a few specific chips in a module and the amount of heat generation locally increases. The power module 20 is configured from six chips, i.e., a first chip 22a having the largest amount of heat generation when heat generation is locally concentrated, second chips 22b1 and 22b2 having the second largest amount of heat generation, and third chips 22c1, 22c2, and 22c3 having the smallest amount of heat generation.
The chip layout is such that the first chip 22a and the second chip 22b1 and the second chip 22b2 are disposed not to be adjacent to each other and the first chip 22a is disposed adjacent to the third chip 22c1 and the third chip 22c3. The second chip 22b1 and the second chip 22b2 are not disposed along the row in the y direction in which the first chip 22a is included.
The first anisotropic high heat conductor 2a1 and the first anisotropic high heat conductor 2b1 are provided immediately below the region including the first chip 22a. The second anisotropic high heat conductor 2a2 and the second anisotropic high heat conductor 2b2 are provided immediately below the region including the second chip 22b1 and the second chip 22b2. Note that the first anisotropic high heat conductor 2a1 and the second anisotropic high heat conductor 2a2 having a high thermal conductivity in the y direction and the z direction and having a low thermal conductivity in the x direction are disposed immediately below the power module 20. The first anisotropic high heat conductor 2b1 and the second anisotropic high heat conductor 2b2 having a high thermal conductivity in the x direction and the z direction and having a low thermal conductivity in the y direction are disposed under the first anisotropic high heat conductor 2a1 and the second anisotropic high heat conductor 2a2 and are closely attached to the heat sink 2. As the anisotropic high heat conductors, for example, a graphite material having a thermal conductivity equal to or higher than 1000 W/mK in a direction in which the thermal conductivity is high can be used.
In such the cooling device 10, when the electric current concentratedly flows to a few specific chips as explained above, the first chip 22a instantaneously and locally has the largest amount of heat generation, the second chip 22b1 and the second chip 22b2 have the second largest amount of heat generation, and the third chip 22c1, the third chip 22c2, and the third chip 22c3 hardly generate heat. Therefore, the generated heat of the first chip 22a is transferred to the first anisotropic high heat conductor 2a1 through the wiring board 21 of the power module 20, diffused in the y direction and the z direction, and further diffused in the x direction and the z direction by the first anisotropic high heat conductor 2b1 and transferred to the heat sink 2. Therefore, it is possible to suppress an instantaneous temperature rise of the first chip 22a. The generated heat of the second chip 22b1 and the second chip 22b2 is transferred to the second anisotropic high heat conductor 2a2 through the wiring board 21 of the power module 20, diffused in the y direction and the z direction, and further diffused in the x direction and the z direction by the second anisotropic high heat conductor 2b2 and transferred to the heat sink 2. Therefore, it is possible to suppress an instantaneous temperature rise of the second chip 22b1 and the second chip 22b2.
The high heat conductor immediately below the first chip 22a and the high heat conductor immediately below the second chip 22b1 and the second chip 22b2 are separated from each other to configure independent two groups of heat dispersion routes. Therefore, when the amount of heat generation instantaneously increases according to the switching operation, the heat of the second chip 22b1 and the second chip 22b2 is mainly diffused inside the second anisotropic high heat conductor 2a2 and the second anisotropic high heat conductor 2b2. If the high heat conductors are not separated from each other, because two chips, i.e., the second chip 22b1 and the second chip 22b2, generate heat and thus the heat generation area is large, the heat is easily diffused to the region immediately below the first chip 22a and this affects cooling of the first chip 22a. In contrast, in the present embodiment, because the high heat conductors are separated from each other, the heat of the second chip 22b1 and the second chip 22b2 less easily flows into the region immediately below the first chip 22a. Therefore, the generated heat of the first chip 22a is efficiently diffused inside the first anisotropic high heat conductor 2a1 and the first anisotropic high heat conductor 2b1. Consequently, it is possible to suppress an instantaneous temperature rise of the first chip 22a.
Note that the total amount of heat generation of the second chip 22b1 and the second chip 22b2 and the amount of heat generation of the first chip 22a are approximately the same. Therefore, heat quantities transferred to the separated high heat conductors are equivalent. Consequently, it is possible to uniformly diffuse heat to the entire heat sink 2 and thus it is possible to efficiently perform cooling.
Second Embodiment.
In such the cooling device 10, the generated heat of the first chip 22a is transferred to the first anisotropic high heat conductor 2b1 through the wiring board 21 of the power module 20, diffused in the x direction and the z direction, and further diffused in the y direction and the z direction by the first anisotropic high heat conductor 2a1 and transferred to the heat sink 2. Therefore, it is possible to suppress an instantaneous temperature rise of the first chip 22a. The generated heat of the second chip 22b1 and the second chip 22b2 is transferred to the second anisotropic high heat conductor 2b2 through the wiring board 21 of the power module 20, diffused in the x direction and the z direction, and further diffused in the y direction and the z direction by the second anisotropic high heat conductor 2a2 on the lower layer side and transferred to the heat sink 2. Therefore, it is possible to suppress an instantaneous temperature rise of the second chip 22b1 and the second chip 22b2.
As in the first embodiment, the high heat conductor immediately below the first chip 22a and the high heat conductor immediately below the second chip 22b1 and the second chip 22b2 are separated from each other. Therefore, the heat of the second chip 22b1 and the second chip 22b2 less easily flows into the region immediately below the first chip 22a. Thus, the generated heat of the first chip 22a is efficiently diffused inside the first anisotropic high heat conductor 2b1 and the first anisotropic high heat conductor 2a1. Consequently, it is possible to suppress an instantaneous temperature rise of the first chip 22a.
Note that the layout arrangement of the heat-generating chips is not limited to the configuration shown in
Third Embodiment.
In such the cooling device 10, as in the cooling device 10 in the second embodiment, the generated heat of the first chip 22a is transferred to the first anisotropic high heat conductor 2b1 through the wiring board 21 of the power module 20, diffused in the x direction and the z direction, and further diffused in the y direction and the z direction by the first anisotropic high heat conductor 2a1 and transferred to the heat sink 2. Therefore, it is possible to suppress an instantaneous temperature rise of the first chip 22a. The generated heat of the second chip 22b1 and the second chip 22b2 is transferred to the second anisotropic high heat conductor 2b2 through the power module 20, diffused in the x direction and the z direction, and further diffused in the y direction and the z direction by the second anisotropic high heat conductor 2a2 and transferred to the heat sink 2. Therefore, it is possible to suppress an instantaneous temperature rise of the second chip 22b1 and the second chip 22b2.
As in the second embodiment, the high heat conductor immediately below the first chip 22a and the high heat conductor immediately below the second chip 22b1 and the second chip 22b2 are separated from each other. Therefore, the heat of the second chip 22b1 and the second chip 22b2 less easily flows into the region immediately below the first chip 22a. Thus, the generated heat of the first chip 22a is efficiently diffused inside the first anisotropic high heat conductor 2b1 and the first anisotropic high heat conductor 2a1. Consequently, it is possible to suppress an instantaneous temperature rise of the first chip 22a.
In this case, the first anisotropic high heat conductor 2b1 and the second anisotropic high heat conductor 2b2 have a role of spreading heat in the x direction. Therefore, even if the length in the y direction corresponds to the size of the power module 20, the ability of spreading heat in the x direction is not hindered. Thus, the amount of high heat conductors to be used is reduced and therefore it is possible to reduce costs.
Note that, in the present embodiment as well, the layout arrangement of the heat-generating chips in the power module 20 is not limited to the configuration shown in
Fourth Embodiment.
In such the cooling device 10, as in the cooling device 10 in the first embodiment, the generated heat of the first chip 22a is transferred to the first anisotropic high heat conductor 2a1 through the wiring board 21 of the power module 20, diffused in the y direction and the z direction, and further diffused in the x direction and the z direction by the first anisotropic high heat conductor 2b1 and transferred to the heat sink 2. Therefore, it is possible to suppress an instantaneous temperature rise of the first chip 22a. The generated heat of the second chip 22b1 and the second chip 22b2 is transferred to the second anisotropic high heat conductor 2a2 through the power module 20, diffused in the y direction and the z direction, and further diffused in the x direction and the z direction by the second anisotropic high heat conductor 2b2 and transferred to the heat sink 2. Therefore, it is possible to suppress an instantaneous temperature rise of the second chip 22b1 and the second chip 22b2.
As in the first embodiment, the high heat conductor immediately below the first chip 22a and the high heat conductor immediately below the second chip 22b1 and the second chip 22b2 are separated from each other. Therefore, the heat of the second chip 22b1 and the second chip 22b2 less easily flows into the region immediately below the first chip 22a. Thus, the generated heat of the first chip 22a is efficiently diffused inside the first anisotropic high heat conductor 2a1 and the first anisotropic high heat conductor 2b1. Consequently, it is possible to suppress an instantaneous temperature rise of the first chip 22a.
In this case, the first anisotropic high heat conductor 2a1 and the second anisotropic high heat conductor 2a2 have a role of spreading heat in the y direction. Therefore, even if the length in the x direction is set in accordance with the size of the wiring board 21 of the power module 20, the ability of spreading heat in the y direction is not hindered. Thus, the amount of high heat conductors to be used is reduced and therefore it is possible to reduce costs.
Note that, in the present embodiment as well, the layout arrangement of the heat-generating chips in the power module 20 is not limited to the configuration shown in
In the embodiments explained above, the anisotropic high heat conductor is configured to have a two-layer structure. However, it goes without saying that the anisotropic high heat conductor can be configured to have a multilayer structure having three or more layers, and with this configuration, it is possible to obtain more highly efficient heat radiation properties.
Fifth Embodiment.
As in the first embodiment, six power semiconductor chips functioning as heat generating bodies are mounted on the power module 20. The power module 20 is configured from the first chip 22a having the largest amount of heat generation when heat generation is locally concentrated, the second chip 22b1 and the second chip 22b2 having the second largest amount of heat generation, and the third chips 22c1, 22c2, and 22c3 having the smallest amount of heat generation.
The chip layout is such that the first chip 22a and the second chip 22b1 and the second chip 22b2 are disposed not to be adjacent to each other and the first chip 22a is disposed adjacent to the third chips 22c1 and 22c3. The second chip 22b1 and the second chip 22b2 are not disposed along the row in the y direction in which the first chip 22a is included.
A first flat heat pipe 31 having a size equivalent to that of the wiring board 21 of the power module 20 in the y direction is provided immediately below the region including the first chip 22a. A second flat heat pipe 32 having a size equivalent to that of the power module 20 in the y direction is provided immediately below the region including the second chips 22b1 and 22b2 and closely attached to the heat sink 2.
In such the cooling device 10, as in the first embodiment, according to the switching operation, the first chip 22a instantaneously and locally has the largest amount of heat generation, the second chip 22b1 and the second chip 22b2 have the second largest amount of heat generation, and the third chips 22c1, 22c2, and 22c3 hardly generate heat. Therefore, the generated heat of the first chip 22a is transferred to the first flat heat pipe 31 through the wiring board 21 of the power module 20, diffused in all of the x, y, and z directions, and transferred to the heat sink 2. Therefore, it is possible to suppress an instantaneous temperature rise of the first chip 22a. The generated heat of the second chip 22b1 and the second chip 22b2 is transferred to the second flat heat pipe 32 through the power module 20, diffused in all of the x, y, and z directions, and transferred to the heat sink 2. Therefore, it is possible to suppress an instantaneous temperature rise of the second chips 22b1 and 22b2.
The first and second flat heat pipes 31 and 32 immediately below the first chip 22a and immediately below the second chip 22b1 and the second chip 22b2, respectively, are separated from each other. Therefore, when the amount of heat generation is instantaneously increases according to the switching operation, the heat of the second chip 22b1 and the second chip 22b2 is mainly diffused inside the second flat heat pipe 32. If the first and second flat heat pipes 31 and 32 are not separated from each other, because two chips, i.e., the second chip 22b1 and the second chip 22b2, generate heat and thus the heat generation area is large, the heat is easily diffused to the region immediately below the first chip 22a and this affects cooling of the first chip 22a. However, because the flat heat pipes are separated from each other, the heat of the second chip 22b1 and the second chip 22b2 less easily flows into the region immediately below the first chip. Therefore, the generated heat of the first chip 22a is efficiently diffused inside the first flat heat pipe 31. Consequently, it is possible to suppress an instantaneous temperature rise of the first chip 22a.
Note that the total amount of heat generation of the second chip 22b1 and the second chip 22b2 and the amount of heat generation of the first chip 22a are approximately the same. Therefore, heat quantities transferred to the separated flat heat pipes 31 and 32 are equivalent. Consequently, it is possible to uniformly diffuse heat to the entire heat sink 2 and thus it is possible to efficiently perform cooling.
Note that, in the present embodiment as well, the layout arrangement of the heat-generating chips in the power module 20 is not limited to the configuration shown in
Sixth Embodiment
In this case, when the power module 20 is fixed to the heat sink 2 by screws, attachment holes 34 are provided avoiding steam channels 33 of the first flat heat pipe 31 and the second flat heat pipe 32 as shown in
In such a cooling device 10, the generated heat of the first chip 22a is transferred to the first flat heat pipe 31 through the wiring board 21 of the power module 20, diffused in all of the x, y, and z directions, and transferred to the heat sink 2. Therefore, it is possible to suppress an instantaneous temperature rise of the first chip 22a. The generated heat of the second chip 22b1 and the second chip 22b2 is transferred to the second flat heat pipe 32 through the wiring board 21 of the power module 20, diffused in all of the x, y, and z directions, and transferred to the heat sink 2. Therefore, it is possible to suppress an instantaneous temperature rise of the second chip 22b1 and the second chip 22b2.
As in the fifth embodiment, the flat heat pipes immediately below the first chip 22a and immediately below the second chip 22b1 and the second chip 22b2, respectively, are separated from each other. Therefore, the heat of the second chip 22b1 and the second chip 22b2 less easily flows into the region immediately below the first chip 22a. Thus, the generated heat of the first chip 22a is efficiently diffused inside the first flat heat pipe 31. Consequently, it is possible to suppress an instantaneous temperature rise of the first chip 22a.
The size of the first flat heat pipe 31 and the second flat heat pipe 32 in the y direction is approximately equal to the size of the heat sink 2. Therefore, it is possible to diffuse the heat to the entire heat sink 2 and thus it is possible to efficiently perform cooling.
Note that, in the present embodiment as well, the layout arrangement of the heat-generating chips in the power module 20 is not limited to the configuration shown in
The first to sixth embodiments are the configuration in which the number of power semiconductor chips of the power module 20 is six. However, even when the number of power semiconductor chips is four or eight or more, it is satisfactory if the chip layout is such that a chip having the largest heat generation and a chip having the second largest heat generation are disposed not to be adjacent to each other, the chip having the largest heat generation and a chip having the smallest heat generation are disposed adjacent to each other, and the chip having the second largest heat generation is not disposed along the row in the y direction in which the chip having the largest heat generation is included.
Furthermore, the semiconductor chips only have to be designed to be grouped for each of the semiconductor chips having a large amount of heat generation such that the groups having a large amount of heat generation have heat diffusion routes independently from one another.
In the embodiments, an example has been explained in which the flat fins are mounted on the heat sink.
However, the shape or the presence or absence of the heat radiation fins can be selected as appropriate. It goes without saying that the configuration of the high heat conductors in the heat sink can also be changed. For example, the high heat conductors can be configured to have an integrated structure using an embedded structure of graphite or partially configured to have a modified structure to adjust the layout of a thermal conductive region.
As explained above, according to the present embodiment, it is possible to cool instantaneously generated heat in the entire heat sink; therefore, it is possible to suppress a temperature rise of the chips. Moreover, it is possible to disperse locally generated heat along the heat dispersion routes, such as right to left; therefore, it is possible to suppress interference among the chips. Furthermore, local heat generation does not occur between adjacent chips; therefore, it is possible to suppress an instantaneous temperature rise. Because of these characteristics, the cooling device is useful for mounting on a power module in which the amount of heat generation is likely to instantaneously increase.
1 main body, 1A base surface, 1B flat fin formation surface, 2 heat sink, 3 flat fin, 10 cooling device, 20 power module, 21 wiring board, 22a first chip, 22b1, 22b2 second chip, 22c1, 22c2, 22c3 third chip, 2a1, 2b1 first anisotropic high heat conductor, 2a2, 2b2 second anisotropic high heat conductor, 31 first flat heat pipe, 32 second flat heat pipe, 33 steam channel, 34 attachment hole, 35 screw.
Filing Document | Filing Date | Country | Kind |
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PCT/JP2013/054207 | 2/20/2013 | WO | 00 |
Publishing Document | Publishing Date | Country | Kind |
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WO2014/128868 | 8/28/2014 | WO | A |
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