JP6658104B2 - Circuit device - Google Patents

Description

  The present invention relates to a circuit device including a lead frame and a fixed resin member that holds the lead frame.

  Conventionally, a circuit device including a lead frame and a resin member is known (for example, see Patent Document 1). This circuit device has a structure in which a lead frame is held by a resin member. In this circuit device, a lead frame to which a mounting element is joined by solder is held by a resin mold.

JP-A-2015-103790

  By the way, in the circuit device in which the lead frame is resin-molded as described above, the larger the difference between the coefficient of linear expansion of the lead frame and the coefficient of linear expansion of the resin member, the more the mounting element and the lead frame are joined during heating such as during use. Cracks and the like tend to occur due to stress acting on the solder to be formed.

  In order to reduce the influence of the difference in linear expansion coefficient between the lead frame and the resin member, it is conceivable to reduce the thickness of the resin member. However, if the thickness of the resin member is simply reduced, the rigidity of the entire circuit device decreases, and the strength of the circuit device against vibration decreases. For example, in a circuit device in which an acceleration sensor is mounted as a mounting element, the characteristics of the acceleration sensor are adversely affected, and a vehicle collision determination based on the detected acceleration may be erroneously performed.

  The present invention has been made to solve the above-described problem, and it is possible to suppress the occurrence of solder cracks and the like due to a difference in linear expansion coefficient between a lead frame and a resin member while securing the overall rigidity. It is an object to provide a possible circuit arrangement.

The invention according to claim 1, which has been made to solve the above-mentioned problem, provides a lead frame (16) to which a mounting element (14) is joined by solder (18) and a wire that holds the lead frame so as to surround the lead frame. A fixed resin member (20) having a coefficient of expansion larger than a linear expansion coefficient of the lead frame, wherein the fixed resin member is attached to the lead frame when used after manufacture. The thickness (ta) of the mounting surface side (20a) to which the mounting element is bonded is smaller than the thickness (tb) of the opposite surface side (20b) of the lead frame opposite to the mounting surface side. is formed such that, the lead frame is provided with a plurality, the fixing resin member, have a groove (22) for exposing the plurality of the lead frame to the mounting surface side , The mounting element, the are arranged so as to straddle the plurality of the lead frames in the groove, a circuit device which is joined by soldering to each of the lead frame.

According to a second aspect of the present invention, there is provided a lead frame (16) to which a mounting element (14) is joined by a solder (18), so as to surround the lead frame. A fixed resin member (20) having a coefficient of linear expansion larger than the coefficient of linear expansion of the lead frame. Opposite to the member, the thickness (ta) of the mounting surface side (20a) of the fixed resin member to which the mounting element is bonded to the lead frame is opposite to the mounting surface side of the lead frame. are arranged so as to be smaller than the thickness of the side (20b) (tb), the lead frame is provided with a plurality, the fixing resin member, said plurality to said mounting surface Has a groove (22) for exposing the lead frame, the mounting element, the are arranged so as to straddle the plurality of the lead frames in the groove, the circuit being bonded by soldering to each of said lead frame Device.

  According to these configurations, when the fixing resin member (20) generates a pulling force on the lead frame (16) due to the influence of heat, the strain acting on the solder (18) on the mounting surface side (20a) becomes a compression strain and Therefore, the occurrence of cracks and the like in the solder (18) is suppressed. Further, it is not necessary to simply reduce the thickness of the fixed resin member (20) in order to reduce the effect of the linear expansion coefficient difference between the fixed resin member (20) and the lead frame (16). Since the thickness (ta) of the mounting surface (20a) with respect to the lead frame (16) of (20) may be smaller than the thickness (tb) of the opposite surface (20b), the entire circuit device (10) can be formed. Rigidity is ensured.

  In addition, reference numerals in parentheses written after each component described in this column and in the claims indicate a correspondence relationship between each component and a component described in an embodiment described later.

It is a perspective view of the circuit device concerning one embodiment of the present invention. FIG. 2 is a cross-sectional view of the circuit device according to the embodiment. FIG. 3 is a cross-sectional view of the circuit device according to the embodiment when warpage occurs. It is a perspective view of the circuit device concerning the modification of the present invention.

  Hereinafter, specific embodiments of the circuit device of the present invention will be described with reference to the drawings.

  A circuit device 10 according to an embodiment of the present invention is a device housed in, for example, an electronic control unit mounted on a vehicle and performing a collision determination and the like, and is mounted on a printed circuit board 12 which is a circuit board as shown in FIG. The electronic component is mounted on the surface and mounted on the surface.

  As shown in FIGS. 1 and 2, the circuit device 10 includes a mounting element 14. The mounting element 14 includes, for example, a sensor element that outputs a signal corresponding to acceleration used for determining a vehicle collision, a sensor element that outputs a signal corresponding to angular velocity, a sensor element that outputs a signal corresponding to magnetism, a capacitor, a resistor, and the like. Element. The circuit device 10 is a device for inputting an external signal to the mounting element 14 or outputting a signal output from the mounting element 14 to the outside.

  The circuit device 10 also includes a lead frame 16. The mounting element 14 described above is electrically connected to the lead frame 16. The mounting element 14 is joined to the lead frame 16 by solder 18. The lead frame 16 is a lead terminal that functions as a power terminal, a ground terminal, or an output terminal of the mounting element 14. The lead frame 16 is connected to circuit wiring formed on the printed circuit board 12.

The lead frame 16 is a member formed by punching a conductive material into an elongated plate shape. The material of the lead frame 16 is, for example, a conductive metal material such as aluminum or copper. The linear expansion coefficient of the lead frame 16 is, for example, 15 (10 ⁻⁶ / K) to 25 (10 ⁻⁶ / K) determined according to the material. A plurality of lead frames 16 as a power terminal, a ground terminal, and an output terminal of the mounting element 14 are arranged in parallel on the same surface.

The circuit device 10 further includes a fixed resin member 20. The fixed resin member 20 is a member for holding the above-described lead frame 16. The fixing resin member 20 is made of a material such as a thermosetting epoxy resin or a thermoplastic LCP resin having excellent adhesiveness, corrosion resistance, heat resistance, and the like. The linear expansion coefficient of the fixed resin member 20 is larger than the linear expansion coefficient of the lead frame 16 and is, for example, 30 (10 ⁻⁶ / K) to 50 (10 ⁻⁶ / K) determined according to the material. . The circuit device 10 is formed in a rectangular shape by molding the lead frame 16 using the fixed resin member 20.

  The lead frame 16 is exposed to the outside at a portion where the mounting element 14 is joined by the solder 18, and is held by being surrounded by the fixed resin member 20 at other portions. That is, the fixing resin member 20 has the groove 22 corresponding to the part where the mounting element 14 is joined to the lead frame 16 by the solder 18, and except for the part where the groove 22 is provided, the lead frame 16 so as to surround it.

  The lead frame 16 has a predetermined thickness t0 between a mounting surface to which the mounting element 14 is bonded and an opposite surface opposite to the mounting surface. The fixed resin member 20 has a predetermined thickness t in the same direction as the thickness direction of the lead frame 16 over substantially the entire surface except for the portion where the groove 22 is provided. Note that the thickness t of the fixed resin member 20 is set to a value that ensures the strength of the circuit device 10 against vibrations equal to or less than a predetermined value. The thickness t of the fixing resin member 20 is the same as the thickness of the circuit device 10 except for the joint portion of the mounting element 14. The thickness t is desirably four times or more the thickness t0 of the lead frame 16 from the viewpoint of securing the rigidity of the entire circuit device 10.

  Further, the fixed resin member 20 has a thickness ta on the mounting surface side to which the mounting element 14 is joined at a portion sandwiching the lead frame 16 and a thickness tb on the opposite surface side opposite to the mounting surface side. It has been done. Hereinafter, the mounting surface side of the fixed resin member 20 is referred to as a mounting surface side 20a, and the opposite surface side is referred to as an opposite surface side 20b.

  The mounting surface side 20a of the fixed resin member 20 has a predetermined thickness ta in the same direction as the thickness direction of the lead frame 16. The opposite side 20 b of the fixed resin member 20 has a predetermined thickness tb in the same direction as the thickness direction of the lead frame 16. The predetermined thickness ta is set to be smaller than the predetermined thickness tb. That is, the fixing resin member 20 is formed such that the thickness ta on the mounting surface side 20a is smaller than the thickness tb on the opposite surface side 20b. The lead frame 16 is arranged and held with respect to the fixed resin member 20 such that the thickness ta of the mounting surface 20a is smaller than the thickness tb of the opposite surface 20b.

  By mounting the mounting element 14 to the lead frame 16 by the solder 18 and holding the lead frame 16 by the fixed resin member 20 in this manner, when the circuit device 10 having the above-described structure is manufactured, the mounting surface The lead frame 16 is held by the fixed resin member 20 in a state where the thickness ta of the side 20a is smaller than the thickness tb of the opposite side 20b.

  As described above, the coefficient of linear expansion of the fixed resin member 20 is larger than the coefficient of linear expansion of the lead frame 16. For this reason, in the circuit device 10 having the above structure, when the temperature shifts from the normal temperature state to the high temperature state during use after manufacturing or the like, a force of the fixed resin member 20 pulling the lead frame 16 is generated due to the influence of the heat. . Further, as described above, the thickness ta of the mounting surface 20a of the fixed resin member 20 is smaller than the thickness tb of the opposite surface 20b. For this reason, the pulling force of the fixing resin member 20 pulling the lead frame 16 is smaller on the mounting surface side 20a than on the opposite surface side 20b. In this case, as shown in FIG. 3, the circuit device 10 is warped such that the mounting surface side 20a is set to the inner peripheral side and the opposite surface side 20b is set to the outer peripheral side.

  In such a structure, when the above-described tensile force is generated, the strain acting on the solder 18 joining the mounting element 14 and the lead frame 16 on the mounting surface side 20a becomes a compressive strain. The solder strength against compressive strain is higher than the solder strength against tensile strain. For this reason, according to the circuit device 10, the thermal expansion coefficient of the fixed resin member 20 and the lead frame are smaller than those of the circuit device in which the thickness ta of the mounting surface 20a is equal to or greater than the thickness tb of the opposite surface 20b. It is possible to suppress the occurrence of solder cracks and the like caused by the difference from the coefficient of linear expansion of No. 16.

  Further, in the circuit device 10 of the present embodiment, it is not necessary to simply reduce the thickness of the fixed resin member 20 in order to reduce the effect of the linear expansion coefficient difference between the fixed resin member 20 and the lead frame 16. It is sufficient that the relationship between the thickness ta of the mounting surface 20a of the fixed resin member 20 sandwiching the lead frame 16 and the thickness tb of the opposite surface 20b as described above is sufficient. Specifically, the thickness ta of the mounting surface 20a may be smaller than the thickness tb of the opposite surface 20b. The thickness t of the fixed resin member 20 is set to a value that ensures the strength of the circuit device 10 against vibrations equal to or less than a predetermined value. For this reason, the rigidity of the entire circuit device 10 can be secured, and a decrease in the strength of the circuit device 10 due to vibration can be prevented.

  Therefore, according to the circuit device 10 of the present embodiment, it is possible to suppress the occurrence of solder cracks and the like due to the difference in linear expansion coefficient between the lead frame 16 and the fixed resin member 20 while securing the overall rigidity. Therefore, after the circuit device 10 is manufactured, the characteristics can be easily maintained at desired characteristics, and good bonding between the mounting element 14 and the lead frame 16 by the solder 18 can be ensured.

  As is apparent from the above description, the circuit device 10 includes the lead frame 16 to which the mounting element 14 is joined by the solder 18 and the lead frame 16 which is held around the lead frame 16. A fixing resin member 20 having a larger expansion coefficient than the expansion coefficient, wherein the fixing resin member 20 has a thickness ta of the mounting surface side 20a to which the mounting element 14 is joined to the lead frame 16 and the mounting surface side 20a of the lead frame 16 Is formed so as to be smaller than the thickness tb of the opposite surface side 20b which is the opposite side.

  Further, the circuit device 10 includes a lead frame 16 to which the mounting elements 14 are joined by the solder 18, and a fixed resin having a linear expansion coefficient larger than that of the lead frame 16 for holding the lead frame 16 so as to surround the lead frame 16. The lead frame 16 has a thickness ta on the mounting surface side 20a where the mounting element 14 of the fixed resin member 20 to the lead frame 16 is bonded to the fixed resin member 20. It is arranged so as to be smaller than the thickness tb of the opposite surface side 20b opposite to the surface side 20a.

  According to these configurations, when the fixing resin member 20 generates a pulling force on the lead frame 16 due to the influence of heat, the strain acting on the solder 18 on the mounting surface 20a becomes a compression strain, so that the crack in the solder 18 Is suppressed. Further, in order to reduce the effect of the linear expansion coefficient difference between the fixed resin member 20 and the lead frame 16, it is not necessary to simply reduce the thickness of the fixed resin member 20; May be smaller than the thickness tb of the opposite side 20b, so that the rigidity of the entire circuit device 10 is ensured.

  The circuit device 10 has an overall thickness that is four times or more the thickness of the lead frame 16. According to this configuration, the rigidity of the entire circuit device 10 can be ensured.

  Further, the circuit device 10 is mounted on the surface of the printed circuit board 12 on which circuit wiring to which the lead frame 16 is connected is formed. According to this configuration, the mounting element 14 can be connected to the printed board 12 via the lead frame 16.

  Note that the present invention is not limited to the above-described embodiments and modified examples, and various changes can be made without departing from the spirit of the present invention.

  For example, in the above embodiment, the circuit device 10 is mounted on the surface of the printed circuit board 12, and the lead frame 16 of the circuit device 10 is connected to the circuit wiring on the printed circuit board 12. However, the present invention is not limited to this. As shown in FIG. 4, the circuit device 10 is housed in the housing 30 and the lead frame 16 of the circuit device 10 is The connector 30 may extend to the external connector 32 provided on the side surface of the connector 30 and be connected to the external connector 32. In this modification, the circuit device 10 including the lead frame 16 may be overmolded via a resin cover, or the housing 30 may be formed by the overmolding. .

  In this modification, the circuit device 10 has the lead frame 16 connected to the external connection connector 32. According to this configuration, the mounting element 14 can be connected to the external control device that performs control based on the output signal of the mounting element 14 via the lead frame 16 and the external connection connector 32.

  Reference Signs List 10 circuit device, 12 printed circuit board, 14 mounting element, 16 lead frame, 18 solder, 20 fixing resin member, 20a mounting surface side, 20b opposite surface side, 30 housing, 32 external connection connector.

Claims (5)

A lead frame (16) to which a mounting element (14) is joined by solder (18); and a fixed resin member that holds the lead frame so as to surround the lead frame and has a linear expansion coefficient larger than that of the lead frame. (20) a circuit device (10) comprising:
At the time of use after manufacture, the fixing resin member has a thickness (ta) of a mounting surface side (20a) to which the mounting element is bonded to the lead frame, which is opposite to the mounting surface side of the lead frame. It is formed so as to be smaller than the thickness (tb) of the opposite surface side (20b),
The lead frame is provided in a plurality,
The fixing resin member has a groove (22) on the mounting surface side for exposing the plurality of lead frames,
The circuit device, wherein the mounting element is disposed in the groove so as to straddle the plurality of lead frames, and is bonded to each of the lead frames by solder . A lead frame (16) to which a mounting element (14) is joined by solder (18); and a fixed resin member that holds the lead frame so as to surround the lead frame and has a larger linear expansion coefficient than the linear expansion coefficient of the lead frame. (20) a circuit device (10) comprising:
When used after manufacture, the lead frame has a thickness (ta) on the mounting surface side (20a) of the fixed resin member on which the mounting element is bonded to the lead frame with respect to the lead frame. It is arranged to be smaller than the thickness (tb) of the opposite surface side (20b) of the frame opposite to the mounting surface side ,
The lead frame is provided in a plurality,
The fixing resin member has a groove (22) on the mounting surface side for exposing the plurality of lead frames,
The circuit device, wherein the mounting element is disposed in the groove so as to straddle the plurality of lead frames, and is bonded to each of the lead frames by solder .   3. The circuit device according to claim 1, wherein the total thickness is at least four times the thickness of the lead frame.   The circuit device according to any one of claims 1 to 3, wherein the circuit device is mounted on a surface of a printed circuit board (12) on which a circuit wiring to which the lead frame is connected is formed.   4. The circuit device according to claim 1, wherein the lead frame is connected to an external connector (32). 5.

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