JP2008171894A - Power device equipment - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To surely and appropriately diffuse heat from a power device that is mounted on a printed board. <P>SOLUTION: A power transistor 110 is arranged in an opening 121 of a circuit board 120 to be mounted, and a first heat slinger 130 wherein the power transistor 110 is screwed by a screwing member 151 in freely attachable/detachable manner is arranged under the circuit board 120. A second heat slinger 140 arranged between the first heat slinger 130 and the circuit board 120 is provided on the upper surface of the first heat slinger 130 while the power transistor 110 is inserted into a square hole 142 as a communicating hole. The thermal expansion coefficient of the second heat slinger 140 is approximate to that of the circuit board 120 than the first heat slinger 130. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to a power device device in which a power device such as a power transistor is mounted on a printed board.

  A power amplifier module (a high frequency power amplification module, hereinafter referred to as a “power amplifier”) including a power device such as a power transistor is used in a transmission unit of a wireless base station or a relay station that constitutes a wireless infrastructure.

  Particularly, since a predetermined amount (for example, 10 W to 50 W) of transmission power is always consumed in a radio base station, a power transistor that flows current generates heat in the power amplifier in the transmission unit of the radio base station.

  For this reason, a heat dissipation plate that dissipates heat generated by a power device such as a power transistor is attached to a conventional electronic circuit using a power transistor.

For example, in Patent Document 1 and Patent Document 2, a heat sink is attached to the lower surface of a printed circuit board on which a power transistor is mounted, and the power transistor disposed in the opening of the printed circuit board is directly bonded to the heat sink by soldering. Dissipates the heat generated by the transistor.
Japanese Patent Laid-Open No. 7-135291 JP-A-9-232715

  By the way, the printed circuit board is formed by attaching wiring with copper foil to a resinous substrate such as bakelite or epoxy resin as an insulating material, and the heat sink is made of a metal material having conductivity such as iron or copper. It is common to be made of materials that are formed and have different coefficients of thermal expansion.

  Therefore, in the structure in which the heat sink is arranged directly below the circuit board on which the power device is mounted as in the conventional patent document 1 and patent document 2, when the heat sink receives heat generated by the power device, the printed board And the thermal expansion coefficient of the heat radiating plate are different, there is a problem in that a thermal stress is applied to the circuit board to adversely affect it.

  Further, in the conventional power device mounting structure, the heat dissipation and conductivity of the power device are improved by directly bonding the power device to the heat dissipation plate by soldering. For this reason, in the conventional structure, when it is necessary to replace the power device, there is a problem in that it takes troublesome work to remove the power device.

  This invention is made | formed in view of this point, and it aims at providing the power device apparatus which dissipates suitably the heat_generation | fever of the power device mounted in the printed circuit board suitably. It is another object of the present invention to provide a power device device that can easily remove the power device even when the power device needs to be replaced.

  The power device device of the present invention includes a power device, a circuit board on which an opening in which the power device is disposed, a first heat sink to which the power device is attached, the circuit board, and the first heat sink. And the second heat radiating plate having a coefficient of thermal expansion closer to the circuit board than the first heat radiating plate.

  According to the present invention, the heat of the power device mounted on the circuit board is received by the first heat radiating plate and then transferred to the second heat radiating plate having a coefficient of thermal expansion closer to the circuit board than the first heat radiating plate. The heat generated by the power device mounted on the circuit board can be reliably and suitably dissipated without the substrate being subjected to thermal stress due to the heat generated by the power device.

  Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. Here, a high-frequency power amplification module will be described as an example of the power device device according to the present invention. The power device device is not limited to the high frequency power amplification module, and may be any device as long as it has a structure in which a power device that generates heat during operation is mounted on a circuit board.

  1 is a plan view of a high-frequency power amplification module as an example of a power device apparatus according to the present invention, FIG. 2 is a side view of the high-frequency power amplification module, and FIG. 3 is a power transistor that is a power device in the high-frequency power amplification module. FIG. 4 is an exploded perspective view showing a schematic configuration of the high frequency power amplification module.

  As shown in FIGS. 1 and 2, the high-frequency power amplification module 100 includes a power transistor 110 that is a power device, a circuit board 120 on which the power transistor 110 is mounted, and a first heat radiating plate that dissipates heat generated by the power transistor 110. 130 and a second heat radiating plate 140 disposed between the first heat radiating plate 130 and the circuit board. In addition, the 1st heat sink 130 is thicker than the 2nd heat sink 140, in order to improve thermal conductivity.

  As shown in FIGS. 1, 3, and 4, the circuit board 120 has an opening 121 in which the power transistor 110 to be mounted is disposed.

  The circuit board 120 has a pattern formed on an insulating base material, a main body substrate 122 in which an opening including an opening 121 communicating with the front and back surfaces is formed, and the power transistor 110 in the opening of the main body substrate 122. And an auxiliary substrate 124 arranged.

  The circuit board 120 is fixed to the first heat sink 130 with the second heat sink 140 interposed therebetween. Here, the main body substrate 122 is fixed to the first heat radiating plate 130 with the second heat radiating plate 140 sandwiched between the fastening members 170 (see FIGS. 1 and 4), and the auxiliary substrate 124 is interposed via a GND terminal portion (not shown). It is fixed to the second heat sink 140.

  In the circuit board 120, electronic parts such as an integrated circuit, a resistor, and a capacitor (not shown) are mounted on a main board 122 and an auxiliary board 124, which are printed boards, and a predetermined control is performed together with the mounted electronic parts. A circuit is configured.

  Land portions 122 a and 124 a (see FIG. 3) to which the terminal portions 112 and 114 of the power transistor 110 are connected are provided on the peripheral portion of the opening 121 of the circuit board 120.

  Among these land portions, the land portion 122a of the main body substrate 122 is connected to the primary side terminal portion 112 of the power transistor 110 disposed in the opening 121 as shown in FIG. 124 a is joined to the terminal portion 114 on the secondary side of the power transistor 110.

  The terminal portions 112 and 114 and the land portions 122a and 124a are joined by, for example, wire bonding or soldering. The land portions 122a and 124a are connected to the wiring patterns on the main board 122 and the auxiliary board 124, respectively.

  As described above, the power transistor 110 is mounted on the circuit board 120 by joining the terminal portions 112 and 114 of the power transistor 110 arranged in the opening 121 to the land portions of the main body substrate 122 and the auxiliary substrate 124. Yes.

  The auxiliary substrate 124 is formed of a material having a higher thermal conductivity than that of the main body substrate 122. Here, a ceramic printed board is applied and connected to the terminal portion 114 on the secondary side of the power transistor 110 as described above. Thus, the circuit board 120 ground is secured.

  The main substrate 122 and the auxiliary substrate 124 are arranged on the same plane, and the opening 121 where the power transistor 110 is arranged is mainly formed by three sides of the opening of the main substrate 122 and one side of the auxiliary substrate 124. Be regulated.

  The power transistor 110 disposed in the restricted opening 121 is inserted into the square hole 142 of the second heat radiating plate 140 disposed in the lower portion of the circuit board 120, and is formed in the lower portion of the second heat radiating plate 140. The first heat radiating plate 130 is detachably attached.

  The power transistor 110 is a power device made of a semiconductor that allows a large current to flow, and generates heat during operation. In the present embodiment, the power transistor 110 is used. However, any power device may be used, and a thyristor or the like may be applied.

  The power transistor 110 is arranged at a predetermined interval from the peripheral surface of the opening 121. Thereby, the heat generated by the power transistor 110 is not directly transferred to the main body substrate 122 and the auxiliary substrate 124.

  The first heat radiating plate 130 is made of a material having a high thermal conductivity, here, a copper plate, and the lower surface of the power transistor 110 inserted through the square hole 142 of the second heat radiating plate 140 is a grease or sheet having a high thermoelectric image rate. It is connected directly through the material.

  The power transistor 110 is detachably attached to the first heat radiating plate 130. Here, the power transistor 110 is fixed by screwing using a fixing member 151 (for example, a screw) with the lower surface thereof being in direct contact with the first heat radiating plate 130.

  Further, the fastening member 151 is inserted through the ground plate 118, and the power transistor 110 is grounded to the main body substrate 122 and the auxiliary substrate 124 via the ground plate 118.

  Specifically, the ground plate 118 is formed by bending a conductive belt-like material so that the central portion has a concave cross section, and is folded in a direction away from the upper end of the opposing wall surface forming the concave shape. It has a bent and extended arm. The ground plate 118 is fixed to the first heat radiating plate 130 of the power transistor 110 by the fixing member 151, so that one of the arms is in contact with the upper surface of the main body substrate 122 and the other is on the upper surface of the auxiliary substrate 124. Abut and press each one downward. As a result, the power transistor 110 itself is grounded to the main body substrate 122 and the auxiliary substrate 124 through the ground plate 118 together with the fastening member 151.

  Note that the power transistor 110 may be connected to the first heat radiating plate 130 as long as the power transistor 110 is detachably connected. For example, the power transistor 110 may be connected by pressing the power transistor 110 onto the first heat sink 130 using a biasing member that presses the power transistor 110 against the first heat sink 130.

  As described above, in the high-frequency power amplification module 100, the power transistor 110 is detachably attached. Therefore, even when the power transistor 110 itself needs to be replaced during maintenance, the power transistor 110 dissipates heat by solder as in the conventional case. Unlike the structure joined to the plate, it can be easily removed and replaced.

  The second heat radiating plate 140 has thermal conductivity, and the thermal conductivity is closer to the circuit board 120 than the first heat radiating plate 130.

  Here, the second heat sink 140 uses SPCC (cold rolled mild steel plate), which is a structural steel material, as a material having a lower thermal conductivity than the first heat sink 130 and close to the heat conductivity of the circuit board 120. Configured. In other words, the thermal expansion coefficient of the second heat radiating plate 140 is close to the thermal expansion coefficient of the circuit board 120 made of different materials here.

  A protrusion 144 for positioning the auxiliary substrate 124 disposed on the surface is formed on the surface of the second heat radiating plate 140, and the positioning hole 126 of the auxiliary substrate 124 is fitted into the protrusion 144. Thus, the auxiliary substrate 124 is positioned at a predetermined position.

  The positioned auxiliary substrate 124 is directly joined to the second heat radiating plate 140 by soldering via the GND terminal portion. As a result, the second heat radiating plate 140 is electrically and securely connected to the secondary side terminal portion 114 of the power transistor 110 and the auxiliary substrate 124 connected to the GND.

  Note that a coating layer made of nickel plating or the like is formed on the surface of the second heat radiation plate 140, and the coating layer improves solder wettability when the circuit board 120 including the auxiliary substrate 124 is electrically connected. Yes.

  The square hole 142 of the second heat radiating plate 140 is for inserting the power transistor 110. Here, the second heat radiating plate 140 has a shape similar to the outer peripheral shape of the power transistor 110 and penetrates the second heat radiating plate 140 in the vertical direction. Is formed. The square hole 142 is a portion of the opening in the circuit board 120 that is partitioned by the opening edge of the main body substrate 122 and one side of the auxiliary substrate 124, that is, a portion where the power transistor 110 is disposed, that is, an opening of the circuit board 120. It is formed in communication with the portion 121.

  As described above, in the high-frequency power amplification module 100 including the power transistor 110, the power transistor 110 is disposed in the opening formed in the circuit board 120, and the circuit board 120 is attached to the second heat radiating plate 140 disposed in the lower portion. It is fixed.

  Further, the second heat radiating plate 140 is fixed to the first heat radiating plate 130 which is disposed under the second heat radiating plate 140 and to which the power transistor 110 inserted through the second heat radiating plate 140 is screwed and joined. ing.

  In other words, the power transistor 110 mounted on the circuit board 120 is disposed in the opening 121 of the circuit board 120 and disposed below the second heat radiation plate 140 through the square hole 142 of the second heat radiation plate 140. The first heat radiating plate 130 is joined directly by screws.

  The circuit board 120 is fixed to the first heat radiating plate 130 with a fastening member (here, a screw) 170 with the second heat radiating plate 140 interposed, and the GND line on the circuit board 120 is formed by a through hole. The second heat sink 140 is electrically connected to the first heat sink 130.

  That is, the power transistor 110 fixed on the first heat sink 130 is mounted on the circuit board 120 via the second heat sink 140 on the first heat sink 130.

  As described above, in the high-frequency power amplification module 100, the heat of the power transistor 110 mounted on the circuit board 120 disposed on the upper side is dissipated by a plurality of heat radiating plates such as the first heat radiating plate 130 and the second heat radiating plate 140.

  Accordingly, when the power transistor 110 generates heat, the heat is conducted to the auxiliary substrate 124 and the first heat radiating plate 130 and is also transmitted to the second heat radiating plate 140.

  In the high-frequency power amplification module 100, when heat is conducted to the first heat radiating plate 130 and thermally expands, the thermal stress is not directly conducted to the circuit board 120, but rather to the circuit board 120 rather than the first heat radiating plate 130. After conducting to the second heat radiating plate 140 having a similar coefficient of thermal expansion, it is conducted to the circuit board 120.

  Thereby, the thermal stress due to the thermal expansion of the first heat radiating plate 130 that has generated heat is not directly applied to the circuit board 120, and there is no adverse effect such as deformation of the circuit board 120.

  Further, in the circuit board 120 to which the terminal portion of the power transistor 110 is connected, the terminal portion on the secondary side of the power transistor 110 has a higher thermal conductivity than the main body substrate 122 and is electrically connected to the second heat radiating plate 140. Connected to the auxiliary substrate 124.

  For this reason, the terminal part on the secondary side is electrically connected to the first heat radiating plate 130 via the second heat radiating plate 140, and the power transistor 110 can be grounded efficiently.

  The power transistor 110 is in contact with the main board 122 and the auxiliary board 124 of the circuit board 120 through the ground plate 118, and the main board 122 and the auxiliary board 124 together with the second heat sink 140 are the first heat sinks. 130 is fixed.

  As a result, the heat generated by the circuit board 120 can also be conducted to the first heat radiating plate 130 via the second heat radiating plate 140 and dissipated.

  As described above, the high-frequency power amplification module 100 according to the present embodiment is arranged below the circuit board 120 having the opening 121, the power transistor (power device) 110 arranged in the opening 121, and the circuit board 120. And a first heat radiating plate 130 joined to the power transistor 110.

  Between the circuit board 120 and the first heat radiating plate 130, the second heat radiating plate 140 having a thermal expansion coefficient closer to the circuit board 120 than the first heat radiating plate 130 is in the square hole 142 communicating with the opening 121. The power transistor 110 is inserted and inserted. The second heat radiating plate 140 is bonded onto the first heat radiating plate 130.

  As a result, after the heat of the power transistor 110 mounted on the circuit board 120 is received by the first heat radiating plate 130, the heat is transferred from the first heat radiating plate 130 to the second heat radiating plate 140 having a coefficient of thermal expansion closer to the circuit board 120. . As a result, the heat of the power transistor 110 is not directly transferred to the circuit board 120, and the circuit board 120 is not subjected to thermal stress due to the heat generated by the power transistor 110. The transistor 110 can be mounted so as to surely and suitably dissipate heat.

  In the present embodiment, the circuit board 120 includes the main body substrate 122 and the auxiliary substrate 124, and the terminal portion on the secondary side of the power transistor 110 is connected to the land portion on the auxiliary substrate 124 side.

  As a result, the GND of the power transistor 110 can be conducted to the second heat sink 140 and the first heat sink 130 via the auxiliary substrate 124 made of a base material such as ceramic having higher thermal conductivity than the main body substrate 122. , Can efficiently dissipate the ground and heat.

  According to the configuration of high-frequency power amplification module 100 in the present embodiment, when a power transistor having a shape different from that of power transistor 110 is attached, the auxiliary substrate 124 and 2 It can respond by changing only the heat sink 140.

  In the present embodiment, the second heat radiating plate 140 is formed by a single heat radiating plate. However, the present invention is not limited to this, and the second heat radiating plate 140 may be a plurality of plate-like members having thermal conductivity ( You may form by laminating | stacking a heat sink. In the case of this configuration, the thermal expansion coefficient of each of the plurality of plate-like members interposed between the circuit board 120 and the first heat radiating plate 130 as the second heat radiating plate 140 is located on the first heat radiating plate 130 side. It is desirable that the thermal expansion coefficient of the circuit board 120 is closer to the thermal expansion coefficient of the first heat radiating plate 130 as the plate-shaped member positioned closer to the circuit board 120 is approached.

  According to this configuration, the heat of the power transistor 110 mounted on the circuit board 120 is received by the first heat radiating plate 130 and then the second heat radiating plate 140 having a thermal expansion coefficient closer to the circuit board 120 than the first heat radiating plate 130. Then, the heat is transmitted to the heat sink laminated on the first heat sink 130. And in the 2nd heat sink 140 which consists of a several heat sink, heat | fever transfers to the heat sink which the thermal expansion coefficient of the circuit board 120 approaches in order toward the upper direction from the heat sink of the lowest layer. As a result, the heat of the power transistor 110 is not directly transferred to the circuit board 120, and the circuit board 120 is not subjected to thermal stress due to the heat generated by the power transistor 110. The heat generation of the transistor 110 can be implemented more effectively and reliably.

  The present invention can be variously modified without departing from the spirit of the present invention, and the present invention naturally extends to the modified ones.

  The power device apparatus according to the present invention has an effect of reliably and suitably dissipating heat generated by the power device without applying thermal stress due to heat generated by the power device to the circuit board on which the power device is mounted, such as a wireless infrastructure. It is useful as a transmission unit of a base station in

The top view of the high frequency power amplification module as an example of the power device apparatus which concerns on this invention Side view of the high-frequency power amplification module Side sectional view showing mounting structure of power transistor in high frequency power amplification module The principal part disassembled perspective view which shows schematic structure of the high frequency power amplification module as an example of the power device apparatus which concerns on this invention

Explanation of symbols

100 High frequency power amplification module (power device device)
110 Power transistor
112 Primary side terminal part 114 Secondary side terminal part 120 Circuit board 121 Opening part 122 Main body board 124 Auxiliary board 130 1st heat sink 140 2nd heat sink 142 Square hole 144 Protrusion 151,170 Fastening member

Claims (6)

Power devices,
A circuit board having an opening in which the power device is disposed;
A first heat sink to which the power device is attached;
The second heat radiating plate interposed between the circuit board and the first heat radiating plate and having a thermal expansion coefficient closer to the circuit board than the first heat radiating plate;
A power device device comprising:   The power device apparatus according to claim 1, wherein the power device is detachably attached to the first heat radiating plate.   The power device device according to claim 1, wherein the second heat radiating plate has a thermal expansion coefficient substantially the same as that of the circuit board.   The power device device according to claim 1, wherein the second heat radiating plate is formed by laminating a plurality of plate-like members having thermal conductivity.   The coefficient of thermal expansion of each of the plurality of plate-like members interposed between the circuit board and the first heat-radiating plate as the second heat-radiating plate is determined from the plate-like member located on the first heat-radiating plate side. 5. The power device device according to claim 4, wherein the thermal expansion coefficient of the circuit board is closer to that of the circuit board than the thermal expansion coefficient of the first heat radiating plate as the plate-like member positioned on the circuit board side is approached. The circuit board includes a main body board provided with wiring connected to a primary side terminal portion of the power device;
2. The power device according to claim 1, further comprising a wiring connected to a secondary side terminal portion of the power device and an auxiliary substrate having a higher thermal conductivity than a base material of the main body substrate. apparatus.

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