1. Field of the Invention
The present invention relates to a heatsink arrangement for a semiconductor device used in electric/electronic circuits.
2. Description of the Related Art
A semiconductor device used in an electric/electronic circuit generates heat due to power loss in the semiconductor device. Such a semiconductor device is typically provided with a heatsink for preventing the semiconductor device from breaking down due to heat generated therein. In a linear power amplifier for amplifying a small-power signal, e.g., an audio signal, into a large-power signal, a large amount of heat is generated due to power loss in the semiconductor device, and such a semiconductor device requires a heatsink with a large surface area and a large volume. A heatsink of a type that is placed in close contact with a semiconductor device is typically made of a metal such as aluminum, and radiates heat that has been generated in the semiconductor device.
An amplifier for amplifying a pulse-width-modulated small-power signal with a semiconductor switching device (typically a transistor or a MOSFET) generates less heat than a power amplifier as described above. However, with a high-output power amplifier, a large current flows through a semiconductor device performing the switching operation, thereby increasing the amount of heat generated due to power loss in the semiconductor device. Therefore, such an amplifier requires a heatsink.
Capacitive coupling occurs between a semiconductor device and a metal heatsink, which are placed in close contact with each other. As the semiconductor device performs the switching operation at a high frequency, high-frequency noise occurring due to a large current flows as a noise current into the heatsink via the capacitive coupling, and the high-frequency noise is radiated from the heatsink with a large surface area and a large volume functioning as an antenna. The radiated high-frequency noise should be reduced as it may adversely affect other electronic devices.
In the conventional art, a thermally-conductive spacer is provided between a semiconductor device and a heatsink to increase the distance therebetween and thus to reduce the capacitive coupling therebetween, in order to reduce high-frequency noise radiated from the heatsink. This however lowers the heat-radiating efficiency, and there is a certain limit to how much the distance between a semiconductor device and a heatsink can be increased by providing a spacer therebetween.
Another approach in the conventional art is to electrically connect a heatsink with a chassis of an electronic device so that a noise current flowing into the heatsink is passed to the grounded chassis, thereby reducing the radiation of high-frequency noise. According to still another approach in the conventional art, a dielectric material is provided between a semiconductor device (CPU) and a heatsink, while connecting the heatsink and the chassis of the electronic device with a conductive connection line. With the provision of the dielectric material, the semiconductor device and the heatsink are actively coupled together in capacitive coupling so as to flow the high-frequency noise current from the heatsink to the chassis (see pp. 1-3 and FIG. 1 of JP2853618B).
With such a heatsink arrangement, however, the high-frequency noise current flowing through the heatsink and the chassis increases as the current flowing through the semiconductor device increases. As a result, the flow of the noise current from the heatsink to the chassis via the connection line forms a mechanically large loop passing through the connection line and the chassis, thereby radiating substantial high-frequency noise. Thus, with the conventional heatsinks and heatsink arrangements, it is not possible to sufficiently reduce the high-frequency noise radiated by the heatsink.
It is therefore an object of the present invention to provide a heatsink arrangement for a semiconductor device used in an electric/electronic circuit that radiates less high-frequency noise even when a large current flows through the semiconductor device and that provides a high heat-radiating efficiency.
A heatsink arrangement for a semiconductor device of the present invention comprises: a first heatsink placed in close contact with the semiconductor device; and a second heatsink placed in close contact with the first heatsink, wherein the first heatsink and the second heatsink are connected to a power supply circuit for the semiconductor device via first connector and second connector, respectively.
In a preferred embodiment, an electric resistivity of a metal material of the first heatsink is smaller than that of a metal material of the second heatsink.
In a preferred embodiment, a thermal conductivity of a metal material of the first heatsink is larger than that of a metal material of the second heatsink.
In a preferred embodiment, a metal material of the first heatsink contains copper, and a metal material of the second heatsink contains aluminum or magnesium.
In a preferred embodiment, the first heatsink and the first connector are provided as an integral member.
In a preferred embodiment, the metal material of the first heatsink and the first connector contains copper; and the first connector is an extended and bent portion of the first heatsink.
In a preferred embodiment, the second connector comprises an attachment section provided in the second heatsink, via which the second heatsink is attached to a circuit board, and a copper foil pattern for electrically connecting the attachment section and the power supply circuit with each other.
In a preferred embodiment, the power supply circuit comprises a capacitor connected between a ground potential and a DC potential or between two DC potentials; and the capacitor is electrically connected to the first connector and the second connector and is provided in the vicinity of the semiconductor device.
In a preferred embodiment, an electrically-insulative and thermally-conductive intermediate member is provided between the semiconductor device and the first heatsink and/or between the first heatsink and the second heatsink.
In a preferred embodiment, the intermediate member is made of a material containing a silicon rubber, a resin or ceramics.
The function of the present invention will now be described.
The heatsink arrangement for a semiconductor device of the present invention comprises the first heatsink placed in close contact with the semiconductor device, and the second heatsink placed in close contact with the first heatsink. Capacitive coupling occurs in the first heatsink in close contact with the semiconductor device. As a result, high-frequency noise generated by a large current in the semiconductor device causes a noise current to flow through the first heatsink and similarly causes a noise current to flow also through the second heatsink. The first heatsink and the second heatsink of the present invention are connected to a power supply circuit for the semiconductor device via first connector and second connector, respectively. The power supply circuit for the semiconductor device herein refers to a circuit for supplying a power for turning ON/OFF a semiconductor switching device such as a MOSFET in a switching amplifier. The power supply circuit has the ground potential and a DC potential, and comprises a capacitor connected therebetween for bypassing high-frequency noise to provide a reference point for the switching operation. The capacitor is placed in the vicinity of the semiconductor switching device. In some cases, the capacitor may be connected between two DC potentials of the power supply circuit. Therefore, according to the present invention, noise currents flowing through the first heatsink and the second heatsink can be bypassed by the capacitor of the power supply circuit for the semiconductor device via the first connector and the second connector, thereby minimizing the length of the noise current loop and thus reducing the radiation of high-frequency noise.
In the heatsink arrangement for a semiconductor device of the present invention, the distance between the semiconductor device and the second heatsink can be increased, whereby the noise current occurring in the second heatsink can be made smaller than that in the first heatsink, which is in close contact with the semiconductor device. In addition, it is preferred that the electric resistivity of the metal material of the first heatsink is smaller than that of the metal material of the second heatsink. Therefore, it is possible to further reduce the noise current occurring in the second heatsink.
Furthermore, it is preferred that the thermal conductivity of the metal material of the first heatsink is larger than that of the metal material of the second heatsink. Therefore, the first heatsink can desirably transfer the heat generated in the semiconductor device to the second heatsink, which has a larger surface area and a larger volume than the first heatsink for radiating heat away into the surrounding environment.
Typically, the metal material of the first heatsink of the present invention contains copper, and the metal material of the second heatsink contains aluminum or magnesium. As a result, it is possible to reduce the radiation of high-frequency noise from the second heatsink, which is more likely to radiate high-frequency noise because the second heatsink has a larger surface area and a larger volume than the first heatsink for radiating heat away into the surrounding environment.
Furthermore, it is preferred that the first heatsink and the first connector of the present invention are provided as an integral member. Typically, in a case where the metal material of the first heatsink of the present invention contains copper, the first connector may be an extended and bent portion of a copper-containing metal plate, which is connected to the power supply circuit for the semiconductor device. As the first heatsink and the first connector of the present invention are provided as an integral member, the electrical impedance is reduced, thereby making it easier for a noise current to flow through the first heatsink while making it more difficult for a noise current to flow through the second heatsink. Thus, the radiation of high-frequency noise from the second heatsink can be further reduced.
Furthermore, it is preferred that an electrically-insulative and thermally-conductive intermediate member is provided between the semiconductor device and the first heatsink and/or between the first heatsink and the second heatsink. In a case where the semiconductor device is a MOSFET in which the drain substrate is exposed, an intermediate member such as an electrically-insulative and thermally-conductive sheet is provided between the semiconductor device and a heatsink made of a metal so that heat generated in the semiconductor device can be desirably transferred to the first heatsink while maintaining the electrical insulation therebetween. In addition, the provision of the intermediate member as described above appropriately increases the distance between the semiconductor device and the first heatsink or between the first heatsink and the second heatsink, thereby reducing the coupling capacitance therebetween and thus further reducing the radiation of high-frequency noise.
Heatsink arrangements for a semiconductor device according to preferred embodiments of the present invention will now be described. Note that the present invention is not limited to the following embodiments.
For the purpose of illustration, the circuit board 1 and the capacitor 2 are shown to be transparent, while using dotted lines to show a copper foil pattern 3 and first connector 21 for connecting the first heatsink 11 with the capacitor 2, which are provided on the reverse side of the circuit board 1. The semiconductor devices 10a and 10b are typically attached to the first heatsink 11 and the second heatsink 12 by screws (not shown) passed through holes in the semiconductor devices 10a and 10b.
The semiconductor devices 10a and 10b are typically semiconductor devices used in an electric/electronic circuit, such as switching devices used in power amplifiers, power supply circuits or motor driving circuits, or arithmetic devices used in electronic circuits. In the following description, it is assumed that the semiconductor devices 10a and 10b are MOSFETs in a switching amplifier. Note that the number of semiconductor devices used with the heatsink arrangement of the present invention is not limited to two, as shown in
Each of the MOSFETs 10a and 10b of
The term “electric resistivity” refers to the electrical impedance per unit volume, and a current flows through a substance more easily as the electric resistivity thereof is smaller. Moreover, the term “thermal conductivity” refers to the temperature change for an amount of heat moving inside a substance, and a larger thermal conductivity means better conduction of heat. The metal material of the first heatsink 11 or the second heatsink 12 is not limited to any particular metal material as long as the first heatsink 11 and the second heatsink 12 are in a relationship as described above in terms of electric resistivity and thermal conductivity. Typically, the metal material of the first heatsink 11 contains copper, and may be pure copper or a copper alloy. Moreover, the metal material of the second heatsink 12 typically contains aluminum or magnesium, and may be a pure metal or an alloy.
The first heatsink 11 in close contact with the MOSFETs 10a and 10b desirably transfers heat generated in the MOSFETs 10a and 10b to the second heatsink 12. Then, the heat is radiated from the second heatsink 12, which has a larger surface area and a larger volume than the first heatsink 11. As a result, even when a large current flows through the MOSFETs 10a and 10b, resulting in substantial power loss and substantial heat generation therein, it is possible to prevent the MOSFETs 10a and 10b from breaking down.
The first heatsink 11 and the second heatsink 12 are connected to the power supply circuit for the MOSFETs 10a and 10b via the first connector 21 and the second connector, respectively. In the present embodiment, the first heatsink 11 and the first connector 21 are provided as an integral member. For example, the first heatsink 11 and the first connector 21 are provided by shaping a copper-containing plate having a thickness of 0.1 to 5.0 mm (preferably 0.5 to 2.0 mm) into a square shape with an extended and bent portion that forms the first connector 21. More preferably, the copper-containing plate is a copper plate 1.0 mm thick, which is easily available and can easily be machined. The first connector 21 is connected to the capacitor 2 of the power supply circuit for the MOSFETs 10a and 10b, which is provided in the vicinity of the MOSFETs 10a and 10b. Moreover, the second heatsink 12 made of an aluminum-containing metal material, for example, includes a bent attachment section 22, via which the second heatsink 12 is attached to the circuit board 1, and the attachment section 22 is connected to the capacitor 2 of the power supply circuit for the MOSFETs 10a and 10b via the copper foil pattern 3. The attachment section 22 and the copper foil pattern 3 together form the second connector. The capacitor 2 of the power supply circuit for the MOSFETs 10a and 10b is connected between the ground potential and a DC potential of the power supply circuit for switching MOSFETs 10a and 10b, or between two DC potentials thereof, for bypassing high-frequency noise.
Capacitive coupling occurs between the MOSFETs 10a and 10b and the first and second heatsinks 11 and 12. Due to a large current that flows by the switching operation of the MOSFETs 10a and 10b, a high-frequency noise current occurs in the first heatsink 11 and a noise current similarly occurs also in the second heatsink 12, via the coupling capacitance. In the heatsink arrangement of the present invention, the noise currents flowing through the first heatsink 11 and the second heatsink 12 are bypassed by the capacitor 2 of the power supply circuit for the MOSFETs 10a and 10b, which is provided in the vicinity of the MOSFETs 10a and 10b, via the first connector 21 and the second connector, respectively, thereby minimizing the length of the noise current loop. Thus, it is possible to reduce the radiation of high-frequency noise from the first heatsink 11 and the second heatsink 12.
Furthermore, by providing the first heatsink 11 and the second heatsink 12 as in the embodiment of
In the embodiment of
Furthermore, in the embodiment of
Heatsinks used in the present invention are not limited to those described in the embodiments above. The first heatsink 11 is not limited to a square-shaped plate with an extended and bent portion, as illustrated in
Moreover, the first connector 21 and the second connector for connecting the first heatsink 11 and the second heatsink 12, respectively, with the power supply circuit for the MOSFET are not limited to those described in the embodiments above, i.e., connector integral with a heatsink or connector including an attachment section and a copper foil pattern. The first connector 21 and the second connector may be, for example, an electrical wire having a small electric resistivity, a copper foil pattern having a large width, a electrically-conductive metal component, or the like, as long as the first heatsink 11 and the second heatsink 12 can be connected to the power supply circuit for the MOSFET with a low electrical impedance.
The heatsink arrangement for a semiconductor device of the present invention is capable of reducing the radiation of high-frequency noise even when a large current flows through the semiconductor device used in an electric/electronic circuit. Furthermore, the heatsink arrangement of the present invention has a high heat-radiating efficiency, and can prevent the semiconductor device from breaking down even when a large amount of heat is generated in the semiconductor device.
The heatsink arrangement of the present invention can suitably be used in an audio amplifier, for example.
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2003-046449 | Feb 2003 | JP | national |
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