JP5029170B2 - Electronic circuit equipment - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an electronic circuit device with a flat plate type shunt resistance mounted on a substrate, wherein a temperature raise of the substrate is suppressed by devising a cooling structure for the shunt resistance. <P>SOLUTION: An electrode (12), a resistor (19), a resistance base material (14), and a heat radiator (15) are stacked on the substrate (11) in order from the side of the substrate (11). The resistance base material (14) and the heat radiator (15) are bonded and fixed using an adhesive (16) having predetermined heat conductivity characteristics. The heat radiator (15) comprises a flat plate portion (15a) and erected portions (15b, 15b) erected at both ends of the flat plate portion (15a) to constitute fin portions, and is sectioned in a nearly U shape on the whole. <P>COPYRIGHT: (C)2009,JPO&amp;INPIT

Description

  The present invention relates to an electronic circuit device in which a shunt resistor is surface-mounted.

  2. Description of the Related Art Conventionally, for example, an inverter device or the like includes an electronic circuit device as a part of a current detection circuit in which a DCCT or a shunt resistor is incorporated in order to detect a current flowing through a motor. That is, in recent years, high-efficiency and high-precision inverter motor control has been demanded to improve energy savings, and position sensorless vector control is used as one of such controls. Since it is necessary to detect the current flowing through the motor, as described above, the inverter device or the like is provided with a current detection circuit.

Here, as the configuration of the current detection circuit, the DCCT is connected to any two of the three phases of the inverter output, or a shunt resistor is connected to the lower arm of the inverter device as disclosed in Patent Document 1. A configuration in which a shunt resistor is connected to the DC portion of the inverter device, or the like is conceivable. Although the DCCT does not generate heat, the cost is very high, and the shunt resistor is inexpensive but generates heat.
JP 2000-134955 A

  When the shunt resistor is used in the current detection circuit, the amount of heat generated by the shunt resistor increases as the capacity of the inverter increases, and cooling thereof becomes a problem.

  In particular, in a flat and small shunt resistor such as a surface mount type used when a high frequency response is required, the heat generated by the shunt resistor is generally dissipated through the substrate. When the capacity increases, the amount of heat generated by the shunt resistor increases, causing a problem that the temperature of the substrate exceeds the upper limit value.

  The present invention has been made in view of such a point, and an object thereof is to devise a cooling structure for the shunt resistor in an electronic circuit device in which a flat shunt resistor is mounted on a substrate. Thus, an object of the present invention is to obtain a configuration capable of suppressing a temperature rise such that the temperature of the substrate exceeds the upper limit value.

To achieve the above object, the electronic circuit device according to the present invention (10), in a configuration in which plate-shaped shunt resistor (13) is mounted on the resin substrate (11), said shunt resistor (13) Resin By providing a radiator (15) on the opposite side of the substrate (11), the heat generated by the shunt resistor (13) was radiated from the radiator (15).

Specifically, the first invention is directed to an electronic circuit device in which a flat shunt resistor (13) is mounted on a resin substrate (11). On the opposite side of the shunt resistor (13) from the resin substrate (11), a radiator (15) for radiating heat generated by the shunt resistor (13) is provided, and the shunt resistor ( 13) is surface-mounted on the resin substrate (11), and the radiator (15) is configured to be larger than the shunt resistor (13) in plan view.

With this configuration, the heat generated by the shunt resistor (13) mounted on the resin substrate (11) is transmitted to the radiator (15), and therefore can be radiated from the radiator (15) to the outside. Thereby, the said shunt resistance (13) can be cooled efficiently and reliably, and it can prevent that the temperature of the said resin substrate (11) exceeds an upper limit.

Further, when the small shunt resistor (13) surface-mounted on the resin substrate (11) is used in the inverter device (1) having a large current capacity, the resin substrate is generated by heat generated by the shunt resistor (13). (11) is heated to a temperature exceeding the upper limit, but as in the first invention, a radiator (15) is provided and the shunt resistor (13) is connected to the radiator (15). By dissipating the generated heat, it is possible to suppress a temperature rise such that the temperature of the resin substrate (11) exceeds the upper limit value.

  In addition, the amount of heat released from the radiator (15) can thereby be increased, and the heat of the shunt resistor (13) can be radiated more efficiently by the radiator (15).

In the configuration in which the shunt resistor (13) is surface-mounted on the resin substrate (11) as described above, the shunt resistor (13) is made of a resistor (19) and an insulating material. substrate to be laminated on the opposite side of the resin substrate (11) of the resistive element antibodies 19) so as to reinforce (19) (14) and has the preferred're provided with. Generally, since the resistor (19) of the shunt resistor (13) mounted on the surface of the resin substrate (11) is small and thin, the shunt resistor is reinforced by the base material (14) as described above. (13) Even when the radiator (15) is provided on the top, it is possible to reliably prevent the resistor (19) from being deformed or damaged.

Moreover, for example, if the radiator (15) is made of a metal having good thermal conductivity (copper, aluminum, etc.), the heat dissipation characteristics of the radiator (15) can be improved, but such a metal is generally high. Since it has electrical conductivity, as described above, the radiator (15) is disposed on the shunt resistor (13) via the base material (14) made of an insulating material, thereby providing the radiator (15 ) Can be reliably prevented from flowing. Therefore, with the above-described configuration, it is possible to improve the heat dissipation characteristics of the radiator (15) while preventing current from flowing through the radiator (15) .

In the configuration of the above mentioned, the radiator (15) through the adhesive (16) having a predetermined thermal conductivity is assumed to be connected to the shunt resistor (13) (the first invention). Here, the predetermined heat conduction characteristic means that the heat generated by the shunt resistor (13) does not stay on the resin substrate (11) side than the adhesive (16), and the heat radiator (15) side efficiently. It means heat conduction characteristics that can be transmitted.

  As a result, the radiator (15) can be securely fixed to the shunt resistor (13), and the transfer of heat from the shunt resistor (13) to the radiator (15) can be controlled by the adhesive (16). Can be reliably performed. Therefore, with the above-described configuration, the heat generated by the shunt resistor (13) can be radiated more efficiently by the radiator (15), and the shunt resistor (13) can be cooled more efficiently.

The radiator (25) may be connected and fixed to the resin substrate (11) by a connection member (21) ( second invention). By doing so, the radiator (25) can be easily fixed to the resin substrate (11). That is, when the adhesive (16) is used as described above, application work and curing time of the adhesive (16) are required, but by fixing with the connecting member (21) as described above. The application work and curing time of the adhesive (16) become unnecessary, and the assembly work of the radiator (15) becomes easy.

Further, the radiator (15) preferably includes a plate-like base portion (15a) and a fin portion (15b) erected on the base portion (15a) ( third invention). ). By doing so, it is possible to radiate heat more efficiently from the fin portion (15b).

  According to the electronic circuit device (10) of the present invention, in the configuration in which the flat shunt resistor (13) is mounted on the substrate (11), the shunt resistor (13) is opposite to the substrate (11). Since the radiator (15) is provided in the radiator, the heat generated by the shunt resistor (13) can be radiated from the radiator (15) without being transmitted to the substrate (11) side. Thereby, the shunt resistor (13) can be cooled efficiently and reliably, and the temperature of the substrate (11) can be prevented from exceeding the upper limit value.

  Further, since the shunt resistor (13) is a small type that is surface-mounted on the substrate (11), a heat radiator (such as the first invention) is provided against such a shunt resistor (13). By providing 15), the shunt resistor (13) can be reliably cooled to lower the temperature of the substrate (11), which is more effective.

  In addition, since the radiator (15) is configured to be larger than the shunt resistor (13) in plan view, the heat generated by the shunt resistor (13) is more efficiently transmitted from the radiator (15). It can dissipate heat well.

Further, the upper Symbol shunt resistor (13) includes a resistor (19), and an insulating material is laminated on the opposite side of the substrate (11) of the resistive element antibodies to reinforce the resistive element antibodies (19) (19) And a base material (14) made from the above, so that when the radiator (15) is provided on the shunt resistor (13), the resistor (19) can be prevented from being damaged, and the radiator (15) can be made of a metal material having high thermal conductivity, and the heat dissipation characteristics of the radiator (15) can be improved .

Also, according to the first invention, the radiator (15), because it is connected to the shunt resistor (13) via the adhesive (16) having a predetermined thermal conductivity, the heat radiating unit ( 15) can be securely fixed to the shunt resistor (13), and the heat of the shunt resistor (13) can be reliably transmitted to the radiator (15) via the adhesive (16). Therefore, the shunt resistor (13) can be cooled more efficiently, and the temperature of the substrate (11) can be more reliably prevented from exceeding the upper limit value.

In addition, according to the second invention, the radiator (25) is connected and fixed to the substrate (11) by the connecting member (21), so that the radiator is compared with the case where an adhesive or the like is used. (15) Easy installation work.

According to the third invention, the radiator (15) includes a plate-like base portion (15a) and a fin portion (15b) standing on the base portion (15a). The heat generated by the shunt resistor (13) can be dissipated more efficiently from the fin portion (15b), and the temperature of the substrate (11) can be more reliably prevented from exceeding the upper limit value.

  Embodiments according to the present invention will be described below in detail with reference to the drawings. It should be noted that the following description of the preferred embodiment is merely illustrative in nature and is not intended to limit the present invention, its application, or its use.

Embodiment 1
FIG. 1: shows an example of the circuit of the power converter device (1) provided with the electronic circuit device (10) which concerns on Embodiment 1 of this invention. This power converter (1) includes a converter unit (2) that converts an AC voltage into a DC voltage, and an inverter unit (3) that converts the DC voltage converted by the converter unit (2) into a three-phase AC voltage. The converter unit (2) is connected to an AC power source (not shown), and the inverter unit (3) is connected to a motor (4) as a load. In addition, the said power converter device (1) is used in order to supply electric power, for example with respect to the compressor of an air conditioning apparatus.

  The inverter unit (3) has a plurality of switching elements (5, 5,...), And is output from the converter unit (12) by the switching operation of the switching elements (5, 5,...). It is configured to convert a DC voltage into a three-phase AC voltage. Although not particularly illustrated, the converter unit (2) is also provided with a plurality of switching elements, and is configured such that a rectification operation from an AC voltage to a DC voltage is performed by the switching operation of the switching elements. .

  Specifically, the inverter unit (3) has six switching elements (5, 5,...), Which are three-phase bridge-connected. In other words, the inverter unit (3) has switching legs (leg1, leg2, leg3) composed of two switching elements (5, 5) connected in series to each other and connected in parallel. The middle point of leg2, leg3) is connected to the three phases of the motor (4).

  Each said switching element (5) is comprised, for example by IGBT as shown in FIG. The switching element (5) may be a unipolar transistor MOSFET or the like as long as it can perform a switching operation. Each switching element (5) is provided with a diode (6) in antiparallel.

  In addition, the power converter (1) is provided with an electronic circuit device (10) including a shunt resistor (13) in the direct current portion (connection portion with the converter portion) in order to detect the current of the motor (4). It has been. The current flowing through the shunt resistor (13) in the electronic circuit device (10) is detected by the current detection circuit (7), and the output signal is sent to the controller (8) to be connected to the inverter unit (3). The current flowing through the motor (4) can be detected. The controller (8) controls the operation of each switching element (5, 5,...) Of the inverter unit (3) based on the current value detected by the current detection circuit (7). A control signal (PWM signal) is output.

  Next, the structure of the electronic circuit device (10) including the shunt resistor (13) will be described with reference to FIG. FIG. 2 is a cross-sectional view schematically showing the configuration of the electronic circuit device (10).

  The electronic circuit device (10) includes, on a resin substrate (11), in order from the substrate (11) side, a metal electrode (12) of a shunt resistor (13) (for example, copper), a resistor ( 19), a resistance substrate (14) (substrate) and a radiator (15) are laminated. That is, the electronic circuit device (10) is a device in which a shunt resistor (13) in which a chip-like resistor (19) is covered with a resistor base (14) is surface-mounted on a substrate (11). On the resistance base (14), a heat radiator (15) as a heat radiating means is provided.

  The shunt resistor (13) includes a resistor (19) formed in a thin film, and a resistor base (14) laminated on the resistor (19) so as to reinforce the resistor (19). And an electrode (12) connected to the resistor (19). And the resistor (19) is connected to the direct current | flow part of the said power converter device (1) through this electrode (12). The resistance base (14) is made of a ceramic material such as alumina, and is provided so as to cover the resistor (19). Thus, the resistor (19) can be reinforced by configuring the resistor base (14) with a material having high rigidity such as a ceramic material. Thereby, even if a heat radiator (15) is provided on the resistance base (14), the resistor (19) can be prevented from being deformed or damaged.

  As shown in FIG. 2, the radiator (15) is a metal (for example, copper or aluminum) heat sink formed in a substantially U-shaped cross section. The radiator (15) is opened upward, that is, the flat plate portion (15a) is a plate-like base portion, and the upright portions (15b, 15b) located at both ends thereof are the base portion. Is disposed on the resistance base material (14) so as to be a fin portion that stands up against. Thus, by disposing the radiator (15) on the resistance base (14), the heat generated in the resistor (19) is transferred to the radiator (15) via the resistance base (14). ) Can be dissipated into the air, whereby the resistor (19) can be cooled.

  Moreover, the said heat radiator (15) is comprised so that it may become larger than the said shunt resistance (13) by planar view. That is, the area of the central portion (15a) of the radiator (15) is larger than the area of the shunt resistor (13). Thereby, the heat generated by the shunt resistor (13) can be efficiently radiated by the radiator (15).

  Furthermore, in this embodiment, the upper surface of the resistance base (14) and the lower surface of the flat plate portion (15a) of the radiator (15) are bonded by an adhesive (16) having predetermined heat conduction characteristics. Yes. The adhesive (16) is made of, for example, rubber or epoxy resin containing boron nitride, aluminum nitride, or the like.

  Thus, by fixing the resistance base (14) and the radiator (15) with the adhesive (16), the radiator (15) is securely fixed to the shunt resistor (13). be able to. Further, by using an adhesive (16) having a predetermined heat conduction characteristic as an adhesive, the heat generated by the shunt resistor (13) is transferred to the radiator (15) side through the adhesive (16). The heat dissipation effect of the radiator (15) can be improved.

-Effect of Embodiment 1-
As described above, according to this embodiment, on the substrate (11), the electrode (12), the resistor (19), and the resistance base material (14) are laminated in this order from the substrate (11) side, and the resistance is further increased. Since the radiator (15) is provided on the substrate (14), the heat generated by the resistor (19) can be radiated from the radiator (15), and the resistor (19) is cooled. Can do.

  In particular, since the resistor (19) is of a type that is surface-mounted on the substrate (11), when used in a power converter having a large power capacity, the amount of heat generated by the resistor (19) is small. There is a possibility that the temperature of the substrate (11) increases and exceeds the upper limit. However, by providing the radiator (15) as described above, the radiator (15) can efficiently dissipate heat, and the substrate (11) can be reliably protected.

  Further, as described above, by providing a resistance base (14) as an insulating member between the resistor (19) and the radiator (15), the radiator (15) can be provided as in this embodiment. Even when a metal material having a high thermal conductivity is used, it is possible to prevent electricity from flowing from the resistor (19) to the radiator (15). Furthermore, by providing the resistance base (14), the rigidity of the resistor (19) can be improved. Even if a radiator (15) is provided on the resistor (19), the resistor (19) Can be prevented from being damaged.

  Moreover, since the resistance base (14) and the radiator (15) are bonded and fixed by an adhesive (16) having a predetermined heat conduction characteristic, the radiator (15) is connected to the shunt resistor (13 ) And reliably transfer the heat generated by the resistor (19) of the shunt resistor (13) to the radiator (15) through the resistance base (14) and the adhesive (16). be able to. Therefore, the heat generated in the resistor (19) can be efficiently radiated by the radiator (15), and the shunt resistor (13) can be efficiently cooled.

  Further, since the radiator (15) is configured to be larger than the shunt resistor (13) in a plan view, the heat generated by the shunt resistor (13) is more generated by the radiator (15). Heat can be radiated efficiently. Therefore, the shunt resistor (13) can be cooled more efficiently.

  Further, the radiator (15) has the raised portions (15b, 15b) located at both ends thereof as fin portions that stand up with respect to the flat plate portion (15a), so that heat can be efficiently radiated from the fin portions. The heat dissipation performance of the radiator (15) as a whole can be improved. Therefore, the shunt resistor (13) can be cooled more efficiently.

-Modification 1 of Embodiment 1-
As shown in FIG. 3, the first modification is that a base material (17) for reinforcing the resistor (19) is provided between the resistor (19) and the substrate (11). Is different from the first embodiment. In addition, the same code | symbol is attached | subjected to the same part as the said Embodiment 1, and only a different part is demonstrated.

  That is, a base material (17) made of an insulating material is provided between the resistor (19) and the substrate (11). This base material (17) has such rigidity that the resistor (19) can be reinforced so that the thin flat resistor (19) is not deformed and damaged. Thus, since the base material (17) is disposed between the resistor (19) and the substrate (11), the electrode (18) of the shunt resistor (13) is connected to the base material (17). It is formed on the side. As a matter of course, the electrode (18) is formed to have a height that can be connected to the resistor (19) of the shunt resistor (13).

  In the case of the configuration as described above, since the rigidity of the resistor (19) can be secured by the base material (17), it is disposed between the resistor (19) and the radiator (15). The resistance substrate (14) may be a film-like insulating member.

-Modification 2 of Embodiment 1
As shown in FIG. 4, the second modification is different from the first embodiment in the fixing method of the radiator (25). In addition, the same code | symbol is attached | subjected to the same part as the said embodiment, and only a different part is demonstrated.

  That is, the radiator (25) has through holes (not shown) at both ends of the flat plate portion (25a). A nut (22) is fixed on the substrate (11) so as to correspond to the through hole, and the tip of the bolt (21) (connection member) inserted through the through hole is connected to the nut (22). It is designed to be screwed together. This eliminates the need to bond and fix the resistance substrate (14) and the radiator (15) with the adhesive (16) as in the first embodiment, so that the application of the adhesive (16) is unnecessary. In addition, it is not necessary to secure the curing time of the adhesive (16). Therefore, the mounting operation of the radiator (25) is facilitated, and the assembly workability of the electronic circuit device (10) can be improved.

  In the second modification, the radiator (25) and the substrate (11) are connected by bolts (21). However, the present invention is not limited to this. For example, the radiator (25) and the substrate ( Any structure may be used as long as the radiator (25) and the substrate (11) can be connected to each other, such as joining both ends of the rod member to 11).

-Modification 3 of Embodiment 1-
As shown in FIG. 5, the modified example 3 is different from the above embodiment in the configuration of the radiator. In addition, the same code | symbol is attached | subjected to the same part as the said embodiment, and only a different part is demonstrated.

  That is, the radiator (35) is provided with a plurality of plate-like fin portions (35b, 35b,...) Standing on a flat plate portion (35a) (base portion) serving as a base. The flat plate portion (35a) is attached to the electronic circuit device (10) so as to be positioned on the resistance base material (14).

  Thus, since the surface area of the radiator (35) can be increased by providing the plurality of fin portions (35b, 35b,...), The fin portions (35b, 35b,...) Are more efficient. It can dissipate heat well. Therefore, a heat radiator (35) that can cool the shunt resistor (13) more efficiently can be obtained.

-Modification 4 of Embodiment 1
Similar to the third modification, the fourth modification differs from the above embodiment in the configuration of the radiator, as shown in FIG. In addition, the same code | symbol is attached | subjected to the same part as the said embodiment, and only a different part is demonstrated.

  In other words, the radiator (45) is formed in a square shape in cross section, and is attached to the electronic circuit device (10) so that one of its outer surfaces is positioned on the resistance base (14).

  Thus, by making the said heat radiator (45) hollow, it can radiate also from the surface inside this heat radiator (45), and the improvement of the heat dissipation performance of this heat radiator (45) can be aimed at. Therefore, the heat radiator (45) capable of efficiently cooling the shunt resistor (13) can be obtained. In the above-described configuration, for example, air can be radiated from the radiator (45) more efficiently by flowing air inside the radiator (45) with a fan or the like.

-Modification 5 of Embodiment 1
As shown in FIG. 7, the modified example 5 is different from the above embodiment in the connection position of the shunt resistor (13) in the power converter (1 ′). In addition, the same code | symbol is attached | subjected to the same part as the said embodiment, and only a different part is demonstrated.

  That is, the electronic circuit device (10) including the shunt resistor (13) includes the switching element (5,5,5) of the lower arm of each switching leg (leg1, leg2, leg3) and the switching leg (leg1, leg2, leg3). ) Between the connection points of each other. That is, in this modification, shunt resistors (13, 13, 13) are connected to each of the three phases. The current detection circuit (7) is configured to detect the current flowing through each of the shunt resistors (13, 13, 13).

  As described above, by configuring so as to detect the current of each of the three phases, the current is generated with one shunt resistance as compared with the case where the current is detected with one shunt resistance as in the first embodiment. Since the amount of heat can be reduced, the heat generated on the substrate (11) can be dispersed. Thereby, it can prevent more reliably that the temperature of this board | substrate (11) exceeds an upper limit.

  In the fifth modification, the shunt resistor (13) is connected to each of the three phases of the inverter unit (3). However, the present invention is not limited to this, and the shunt resistor (13) is connected to two of the three phases. It may be connected to detect the current of the motor (4).

《 Related technology 》
As shown in FIG. 8, the electronic circuit device (50) according to this related technique is different from the first embodiment in the shape of the shunt resistor (53), and the radiator (15) is non-conductive. Is different. Therefore, only differences from the first embodiment will be described, and the same portions will be denoted by the same reference numerals and description thereof will be omitted.

  Specifically, as shown in FIG. 8, both ends of a flat metal member (metal plate) are bent in the same direction to form a shunt resistor (53) having a substantially U-shaped cross section. Thereby, the bent both ends of the shunt resistor (53) become leg portions (53a, 53a) and are inserted into the through holes (11a, 11a) formed in the substrate (11). The legs (53a, 53a) of the shunt resistor (53) are fixed to the substrate (11) by soldering or the like in a state of passing through the substrate (11).

  On the flat plate portion (53b) of the shunt resistor (53), the flat plate portion (55a) of the radiator (55) having a substantially U-shaped cross section is formed by an adhesive (16) having predetermined heat conduction characteristics. Bonded and fixed.

The radiator (55) is made of a non-conductive member such as ceramics or epoxy resin in which boron nitride, aluminum nitride, or the like is blended, for example. Therefore, electricity is transmitted from the shunt resistor (53) to the radiator (55). It can be prevented from flowing. This eliminates the need to provide a resistance base material as an insulating member between the shunt resistor (53) and the first embodiment. In this related technology , the radiator (55) is a non-conductive member. However, the present invention is not limited to this, and a member having high thermal conductivity and high conductivity such as copper or aluminum may be used. In this case, as in the first embodiment, an insulating member is required between the shunt resistor (53).

  Here, also in the configuration as described above, as in the second modification of the first embodiment, as shown in FIG. 9, the radiator (65) is fixed to the substrate (11) with bolts (21). It may be. Moreover, as a radiator, you may apply the structure of the radiator (35,45) like the modification 3 and 4 of the said Embodiment 1, and like a modification 5 with respect to a power converter device (1). The electronic circuit device (50) may be connected to any position.

-Effects of related technologies-
As described above, according to this related art , even in the configuration in which the leg portions (53a, 53a) extending from the flat plate portion (53b) of the shunt resistor (53) are inserted into the substrate (11) and fixed, the flat plate portion (53b ) By providing the radiator (55) on the top, the heat generated by the shunt resistor (53) can be radiated from the radiator (55), and the shunt resistor (53) can be reliably cooled. it can. Therefore, it is possible to reliably prevent the temperature of the substrate (11) on which the shunt resistor (53) is mounted from exceeding the upper limit value.

-Modifications of related technology-
As shown in FIG. 10, the electronic circuit device (60) according to this modification is different from the related technology in the configuration of the shunt resistor (63). In addition, the same code | symbol is attached | subjected to the same part as the said embodiment, and only a different part is demonstrated.

  That is, the shunt resistor (63) bends both ends of a flat metal member (metal plate) in the same direction, and bends the end side outward so as to be substantially parallel to the substrate (11). Thus, it is formed in a trapezoidal shape. Thereby, the said both ends comprise the leg part (63a, 63a), and the center part each comprises the flat plate part (63b). And the said leg part (63a, 63a) is joined on the said board | substrate (11).

  As a result, the shunt resistor (63) made of a metal plate can be surface-mounted on the substrate (11), and the legs (63a, 63a) can replace the electrodes, thereby simplifying the structure. .

<< Other Embodiments >>
The present invention may be configured as follows for each of the above embodiments.

  In each of the above embodiments, the radiator (15, 25, 35, 45, 55, 65) is a heat sink that dissipates heat into the air, but is not limited to this. For example, it is cooled by a liquid such as water or a refrigerant. Any configuration may be used.

Moreover, in the said Embodiment 1, the heat radiator (15) is made into metal, However, It is not this limitation, You may comprise with a nonelectroconductive member similarly to related technology .

In the related art , both end portions of the flat metal member are bent to form the leg portions (53a, 53a) of the shunt resistor (53). Any configuration may be used as long as the leg portion extends from the flat plate portion (53b) to the substrate (11) side, such as a configuration joined to 53b).

  As described above, the electronic circuit device according to the present invention is particularly useful when, for example, a plate-like shunt resistor for detecting a current in a power conversion device is mounted on a substrate.

It is a circuit diagram which shows schematic structure of the power converter device provided with the electronic circuit device which concerns on Embodiment 1 of this invention. It is sectional drawing which shows schematic structure of an electronic circuit apparatus. FIG. 3 is a diagram corresponding to FIG. FIG. 9 is a view corresponding to FIG. It is sectional drawing which shows schematic structure of the heat radiator which concerns on the modification 3. FIG. 10 is a diagram corresponding to FIG. FIG. 10 is a view corresponding to FIG. FIG. 3 is a diagram corresponding to FIG. 2 according to related technology . FIG. 9 is a diagram corresponding to FIG. 2 when the configuration of Modification 2 of Embodiment 1 is applied to the configuration of the related art . Is 2 corresponding view according to a modification of the related art.

10,50,60 Electronic circuit equipment
11 Board
12 electrodes
13,53,63 Shunt resistor
14 Resistance substrate (insulating material)
15,25,35,45,55,65 radiator
15a, 25a, 35a, 55a Flat plate (base)
15b, 35b Fin part (fin part)
16 Adhesive
17 Base material
18 electrodes
19 Resistor
21 bolt (connecting member)
53a, 63a Leg
53b, 63b Flat plate

Claims (3)

An electronic circuit device in which a flat shunt resistor (13) is mounted on a resin substrate (11),
On the opposite side of the shunt resistor (13) from the resin substrate (11), a radiator (15) for dissipating heat generated by the shunt resistor (13) is provided,
The shunt resistor (13) is surface mounted on the resin substrate (11),
The radiator (15) is configured to be larger than the shunt resistor (13) in plan view,
The shunt resistor (13) is made of an insulating material and a resistor (19), and is laminated on the opposite side of the resistor (19) from the resin substrate (11) so as to reinforce the resistor (19). A base material (14)
The electronic circuit device, wherein the radiator (15) is connected to the shunt resistor (13) through an adhesive (16) having predetermined heat conduction characteristics. An electronic circuit device in which a flat shunt resistor (13) is mounted on a resin substrate (11),
On the opposite side of the shunt resistor (13) from the resin substrate (11), a radiator (15) for dissipating heat generated by the shunt resistor (13) is provided,
The shunt resistor (13) is surface mounted on the resin substrate (11),
The radiator (15) is configured to be larger than the shunt resistor (13) in plan view,
The shunt resistor (13) is made of an insulating material and a resistor (19), and is laminated on the opposite side of the resistor (19) from the resin substrate (11) so as to reinforce the resistor (19). A base material (14)
The radiator (25) is connected and fixed to the resin substrate (11) by a connection member (21), and sandwiches the shunt resistor (13) together with the resin substrate (11). Electronic circuit device. Oite to claim 1 or 2,
The radiator (15) includes a plate-like base portion (15a) and a fin portion (15b) erected on the base portion (15a).

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