JP6662262B2 - Electronic devices and insulation displacement terminals - Google Patents

Description

  The present invention relates to an electronic device including an electric wire and a press contact terminal that presses against the electric wire, and a press contact terminal.

  BACKGROUND ART Conventionally, as described in Patent Literature 1, a stator including a wire (electric wire) and a press contact terminal has been known. A conduction groove for conduction with the wire is formed in the press contact terminal. By inserting the wire into the conduction groove, the insulating layer (covering portion) of the wire is removed, and the wire and the press contact terminal are conducted.

  The press contact terminal forms a conduction groove and has a pair of holding portions for holding the wire. When the wire is not inserted into the conduction groove, the opposing distance between the holding portions is constant. However, in a state where the wire is inserted into the conduction groove, the facing distance between the holding portions becomes longer toward the side opposite to the insertion direction of the wire, and the holding portion may be opened.

  When the holding portion is opened, only the portion where the facing distance between the holding portions is short contacts the wire, and the portion where the facing distance is long does not contact the wire. That is, the contact area between the press contact terminal and the wire is reduced. Therefore, the press contact terminal of Patent Document 1 has a three-pronged shape in which two conduction grooves are formed in order to secure a contact area with the wire.

JP 2005-130586 A

  However, in the above-described configuration, since the pressure contact terminal has a three-pronged shape, the width of the holding portion may be increased. That is, there is a possibility that the space for disposing the press contact terminals is increased.

  The present invention has been made in view of such a problem, and while suppressing the contact area between the electric wire and the press contact terminal to be reduced, an electronic device that suppresses an increase in the space for disposing the press contact terminal, and An object is to provide a press contact terminal.

  The present invention employs the following technical means to achieve the above object. In addition, the code | symbol in a parenthesis shows the correspondence with the specific means in the following embodiment as one aspect, and does not limit a technical range.

One of the present inventions
An electronic device comprising: an electric wire (60); and a press-connecting terminal (42) for inserting the electric wire in a direction orthogonal to a longitudinal direction of the electric wire and holding the electric wire to establish an electrical connection,
The electric wire has a conductor (62) and a covering (64) covering the conductor.
The press-connecting terminal has a pair of holding portions (42b) that face each other and hold the wire in a state where the wire is inserted into the facing region (44), and a bottom portion (42e) that connects the holding portions.
Each of the holding portions includes a removing portion (42d) for removing at least a part of the covering portion to expose the conductor portion from the covering portion, and a conductor portion formed between the removing portion and the bottom portion and exposed by the removing portion. And a pressure contact portion (42c) that presses the surface by applying a spring reaction force to the
In a state where the electric wire is not inserted in the facing region, the facing distance (L1) between the press contact portions is increased from the removed portion toward the bottom ,
The removal portion has a recess (42k) that is recessed in the direction in which the pressure contact portions are opposed to each other,
The dent has, as an open end, a first corner (42m) for positioning the electric wire, and a second corner (42n) formed on the press-contact portion side of the first corner.
The second corner removes the coating in a state where the electric wire is positioned by the first corner,
The opposing distance (L5) between the first corners is longer than the opposing distance (L6) between the second corners .

  In the above configuration, in a state where the electric wire is not inserted in the facing region, the facing distance between the press contact portions is increased from the removed portion toward the bottom. According to this, in a state where the electric wire is inserted into the opposing region, it is possible to suppress the opposing distance between the press contact portions from increasing from the bottom toward the removing portion. That is, it is possible to suppress the holding portion from being opened while the electric wire is inserted in the facing region.

  Therefore, it is possible to suppress a decrease in the contact area between the electric wire and the press contact terminal without forming the press contact terminal in a three-pronged shape. According to this, it is possible to suppress an increase in the width of the holding portion. That is, it is possible to suppress an increase in the space for disposing the press contact terminals.

One of the other inventions invented is
An electric connection is established by holding the electric wire while inserting the electric wire in a direction orthogonal to the longitudinal direction of the electric wire (60) having the conductor portion (62) and the covering portion (64) covering the conductor portion. A pressure contact terminal (42);
A pair of holding portions (42b) that face each other and hold the wire in a state where the wire is inserted into the facing region (44);
A bottom portion (42e) connecting the holding portions to each other,
Each of the holding portions includes a removing portion (42d) for removing at least a part of the covering portion to expose the conductor portion from the covering portion, and a conductor portion formed between the removing portion and the bottom portion and exposed by the removing portion. And a pressure contact portion (42c) that presses the surface by applying a spring reaction force to the
In a state where the electric wire is not inserted in the facing region, the facing distance (L1) between the press contact portions is increased from the removed portion toward the bottom ,
The removal portion has a recess (42k) that is recessed in the direction in which the pressure contact portions are opposed to each other,
The dent has, as an open end, a first corner (42m) for positioning the electric wire, and a second corner (42n) formed on the press-contact portion side of the first corner.
The second corner removes the coating in a state where the electric wire is positioned by the first corner,
The opposing distance (L5) between the first corners is longer than the opposing distance (L6) between the second corners .

  With this press contact terminal, the same effect as the above-described electronic device can be obtained.

FIG. 2 is a cross-sectional view illustrating a schematic configuration of the electronic device according to the first embodiment. It is sectional drawing which shows the shape of an electric wire. It is sectional drawing which shows the shape of an insulation displacement terminal and an electric wire in a connection state. FIG. 4 is a sectional view taken along the line IV-IV in FIG. 3. It is sectional drawing for demonstrating the connection process of an insulation displacement terminal and an electric wire. It is sectional drawing for demonstrating the connection process of an insulation displacement terminal and an electric wire. It is sectional drawing for demonstrating the connection process of an insulation displacement terminal and an electric wire. FIG. 13 is a cross-sectional view for explaining a step of connecting a press contact terminal and an electric wire in the electronic device according to the second embodiment. It is sectional drawing which shows the shape of an insulation displacement terminal and an electric wire in a connection state. FIG. 13 is a cross-sectional view illustrating a step of connecting an insulation displacement terminal and an electric wire in the electronic device according to the third embodiment. It is sectional drawing for demonstrating the connection process of an insulation displacement terminal and an electric wire. It is sectional drawing for demonstrating the connection process of an insulation displacement terminal and an electric wire. It is sectional drawing for demonstrating the connection process of an insulation displacement terminal and an electric wire. It is sectional drawing which shows the shape of an insulation displacement terminal and an electric wire in a connection state. FIG. 13 is a cross-sectional view illustrating a shape of a press contact terminal in a non-connection state in an electronic device according to a fourth embodiment. It is sectional drawing for demonstrating the connection process of a press contact terminal and an electric wire in the electronic device which concerns on 5th Embodiment. It is sectional drawing which shows the shape of a press contact terminal and an electric wire in a connection state, when an electric wire is made into a normal position. It is sectional drawing which shows the shape of a press contact terminal and an electric wire in a connection state, when an electric wire is made into an abnormal position. It is a figure which shows the value of the load with respect to the displacement of an electric wire. FIG. 9 is a cross-sectional view illustrating a shape of an electric wire in an electronic device according to a first modification.

  This will be described with reference to the drawings. Note that, in a plurality of embodiments, common or related elements are given the same reference numerals. The direction in which the press contact terminal extends is referred to as a Z direction, a specific direction perpendicular to the Z direction is referred to as an X direction, and a direction perpendicular to the Z direction and the X direction is referred to as a Y direction.

(1st Embodiment)
First, a schematic configuration of the electronic device 100 will be described with reference to FIGS.

  As shown in FIG. 1, the electronic device 100 includes a substrate 10, an electronic component 20, a case 30, press-contact terminals 40 and 42, a housing 50, and an electric wire 60. In the present embodiment, the electronic device 100 is an ECU (Electronic Control Unit) for a vehicle. Specifically, the electronic device 100 is a motor ECU that controls a motor for a vehicle.

  The board 10 is a printed board. The substrate 10 has a flat plate shape whose thickness direction is along the Z direction. The substrate 10 has a front surface 10a and a back surface 10b opposite to the front surface 10a. The front surface 10a and the back surface 10b are planes orthogonal to the Z direction. The substrate 10 has a through hole 12 formed therein.

  The through hole 12 is a through hole of the substrate 10 formed for connecting the substrate 10 to the press contact terminals 40 and 42. The through hole 12 is formed in the substrate 10 from the front surface 10a to the back surface 10b. Electrodes to be electrically connected to the press contact terminals 40 and 42 are formed on the peripheral portion of the opening of the through hole 12 on the front surface 10a and the back surface 10b, and on the inner wall surface of the through hole 12.

  Electrodes for mounting the electronic component 20 are formed on at least one of the front surface 10a and the back surface 10b. The electronic component 20 forms an electronic circuit together with the substrate 10. As the electronic component 20, for example, a diode, a coil, a capacitor, a resistor, an IC chip, a microcomputer, and an ASIC can be adopted.

  The substrate 10 is fixed to at least one of a case 30 and a housing 50 described below. As a method for fixing the substrate 10, for example, screw fastening can be adopted. The case 30 constitutes a housing member that accommodates the substrate 10, the electronic component 20, a part of the press contact terminal 40, the press contact terminal 42, and a part of the electric wire 60, and also constitutes a connector housing of the electronic device 100. is there.

  The case 30 has a bottom 32, and has a box-like shape in which one surface opposite to the bottom 32 is open. The bottom 32 has a flat plate shape whose thickness direction is along the Z direction. The opening of the case 30 is closed by the housing 50. The substrate 10 and the electronic component 20 mounted on the substrate 10 are covered by a case 30. The inner surface 32a of the bottom 32 on the substrate 10 side faces the surface 10a in the Z direction. The case 30 is formed using a resin material.

  The case 30 further has a cylindrical portion 34 extending from the bottom portion 32 to the opposite side of the substrate 10 in the Z direction. The tubular portion 34 has a tubular shape extending in the Z direction. The cylindrical portion 34 and the bottom portion 32 form a connector housing.

  The press contact terminal 40 is a connector terminal. The press contact terminal 40 is formed integrally with the bottom 32 by insert molding, press fitting, or the like. That is, the press contact terminal 40 is held on the bottom 32. A connector for external connection in the electronic device 100 is configured by the connector housing formed by the case 30 and the press contact terminal 40. When the connector of the external device is fitted into the connector housing formed by the case 30, the terminal of the connector of the external device is electrically connected to the press contact terminal 40, and thus the external device is electrically connected to the electronic device 100. You.

  The press contact terminal 40 is formed to extend in the Z direction. One end of the press contact terminal 40 is located in a hollow surrounded by the cylindrical portion 34. At the other end of the press contact terminal 40, a press contact portion 40a that presses against an electrode formed on the inner wall surface of the through hole 12 is formed.

  The press contact portion 40a is press-fitted into the through hole 12 from the front surface 10a side. When the press contact terminal 40 is press-fitted, the press contact portion 40a causes a spring reaction force to act on an electrode formed on the inner wall surface of the through hole 12. Thereby, the press contact terminal 40 and the substrate 10 are held together and are mechanically and electrically connected.

  The press contact terminal 42 electrically relays the board 10 and the electric wire 60. The press contact terminal 42 is formed to extend in the Z direction similarly to the press contact terminal 40. At one end in the Z direction of the press contact terminal 42, a press contact portion 42a that presses against an electrode formed on the inner wall surface of the through hole 12 is formed. The press contact portion 42a is press-fitted into the through hole 12 from the back surface 10b side. When the press contact terminal 42 is press-fitted, the press contact portion 42 a causes a spring reaction force to act on the electrode formed on the inner wall surface of the through hole 12. Thereby, the press contact terminal 42 and the substrate 10 are held together and are mechanically and electrically connected.

  The pressing terminal 42 has a holding portion 42b for holding the electric wire 60 at the other end opposite to the one end where the pressing portion 42a is formed. The press contact terminal 42 holds the electric wire 60 and establishes electrical connection with the electric wire 60 by the holding portion 42b. The connection structure between the press contact terminal 42 and the electric wire 60 will be described in detail below.

The press contact terminal 42 is formed using a metal material having an electrical conductivity of 40% or more in IACS. In other words, the press contact terminal 42 is formed using a metal material having a conductivity of 40% IACS or more. Specifically, the base material of the press contact terminal 42 is formed using a copper alloy having an electrical conductivity of 40% or more and IACS. The base material of the press contact terminal 42 is formed using, for example, a Corson copper alloy. % IACS, which is a unit of conductivity, is a ratio of conductivity when the conductivity of 1.7241 × 10 ⁻² μΩm, which is the conductivity of annealed standard soft copper, is 100%.

  The housing 50, together with the case 30, constitutes a housing member that houses the board 10, the electronic component 20, a part of the press contact terminal 40, the press contact terminal 42, and a part of the electric wire 60. That is, the housing 50 forms a housing space together with the case 30.

  The housing 50 has a flat plate shape whose thickness direction is along the Z direction. The inner surface 50a of the housing 50 on the substrate 10 side faces the back surface 10b in the Z direction. The inner surface 50a closes the opening of the case 30. The housing 50 is formed using a resin material.

  In the present embodiment, the housing 50 forms a part of a motor case that houses the motor on the side opposite to the case 30. The housing 50 has a hole 52 formed to be recessed from the inner surface 50a by a predetermined depth in the Z direction. A part of the press contact terminal 42 and a part of the electric wire 60 are arranged in the hole 52.

  The electric wire 60 is electrically connected to the motor. The board 10 is electrically connected to the motor via the press contact terminals 42 and the electric wires 60. As shown in FIG. 2, the electric wire 60 has a conductor 62 and a covering 64 covering the conductor 62. The covering portion 64 is formed using an electrically insulating material.

  FIG. 2 shows the electric wire 60 that is not inserted in the following opposing region 44. When not inserted into the facing region 44, the conductor portion 62 is not exposed from the covering portion 64.

  In the present embodiment, the cross-sectional shape of the electric wire 60 is rectangular. That is, the cross-sectional shape of the electric wire 60 is square. Specifically, the cross-sectional shape of the electric wire is rectangular. The cross-sectional shape of the conductor portion 62 has a rectangular shape. The cross-sectional shape of the covering portion 64 is an annular shape in which the inner peripheral end and the outer peripheral end form a rectangular shape. By making the cross-sectional shape of the electric wires 60 rectangular, the gap between the electric wires 60 in the motor can be reduced. Therefore, the occupancy of the electric wire 60 in the motor can be improved.

  Next, a connection structure between the press contact terminal 42 and the electric wire 60 will be described with reference to FIGS.

  As shown in FIG. 3, one end of the press contact terminal 42 on the side of the holding portion 42b has a forked shape, and has a Y-shaped cross section in the XZ plane. The press contact terminal 42 has a bottom portion 42e in addition to the holding portion 42b.

  The press contact terminal 42 has a pair of holding portions 42b facing each other in the X direction. The X direction corresponds to the facing direction described in the claims. The holding portion 42b has a substantially flat plate shape whose thickness direction is along the X direction. Hereinafter, a region formed between the holding portions 42b is referred to as a facing region 44.

  Each holding portion 42b has a pressing portion 42c and a removing portion 42d. In FIG. 3, the boundary between the press contact portion 42c and the removal portion 42d and the boundary between the press contact portion 42c and the bottom portion 42e are indicated by broken lines.

  When the electric wire 60 is clamped by the clamping portion 42b, the press contact terminal 42 and the electric wire 60 are mechanically and electrically connected. Hereinafter, a state in which the press contact terminal 42 and the electric wire 60 are mechanically and electrically connected is referred to as a connection state. A state where the electric wire 60 is not inserted into the facing region 44 is referred to as a non-connection state. In the connected state, the holding portion 42b exerts a spring reaction force on the electric wire 60 along the X direction.

  Each press contact portion 42c has a press contact surface 42f that presses against the electric wire 60 in a connected state. The press contact surfaces 42f of the respective press contact portions 42c face each other in the X direction. In the connected state, each press contact surface 42f is a substantially flat surface orthogonal to the X direction. That is, in the connection state, the facing distance L1 between the press contact portions 42c in the X direction is substantially constant in the Z direction.

  As shown in FIG. 4, the longitudinal direction of the connection portion of the electric wire 60 with the press contact portion 42c is set to the Y direction. The cross-sectional shape in the XZ plane of the connection portion of the electric wire 60 with the press contact portion 42c has a rectangular shape with the long side along the Z direction and the short side along the X direction.

  In the connected state, the covering portions 64 on both sides of the electric wire 60 in the X direction are removed by the removing portion 42d. Therefore, the conductor portion 62 is exposed at both end surfaces in the X direction of the electric wire 60. The press contact surface 42f of each press contact portion 42c is in contact with the exposed conductor portion 62. Thereby, each press contact portion 42c presses against the conductor portion 62. One removing portion 42d is connected to each press contact portion 42c in the Z direction.

  The respective removal portions 42d face each other in the X direction. Each removed portion 42d has a corner 42i formed by the first surface 42g and the second surface 42h. The removing portion 42d removes the covering portion 64 by the corner portion 42i, and exposes the conductor portion 62 of the electric wire 60 inserted into the facing region 44. The corner 42i can also be called a removal edge. The first surface 42g and the second surface 42h are planes along the Y direction. One end of the first surface 42g in the Z direction is connected to the second surface 42h, and the other end is connected to the press contact surface 42f.

  The bottom part 42e is connected to the opposite side of the press contact part 42c from the removal part 42d in the Z direction. The press contact portions 42c are connected to each other via the bottom portion 42e. The bottom portion 42e has a flat plate shape whose thickness direction is along the Z direction. The bottom 42e has a bottom surface 42j that forms the facing region 44. The bottom surface 42j is a plane orthogonal to the Z direction. Both ends in the X direction of the bottom surface 42j are connected to the press contact surface 42f.

  Next, a connection process between the press contact terminal 42 and the electric wire 60 will be described with reference to FIGS.

  As shown in FIG. 5, in the non-connection state, the facing distance L1 becomes longer from the removal part 42d to the bottom part 42e in the Z direction. That is, in the disconnected state, the press contact portions 42c are separated from each other in the X direction as going from the removal portion 42d to the bottom portion 42e in the Z direction. In other words, each press contact surface 42f is inclined at a predetermined angle from the YZ plane. The angle between each press contact surface 42f and the bottom surface 42j is an acute angle.

  In the non-connection state, the shortest distance L1min of the opposing distance L1 is equal to the opposing distance L2 between the first surfaces 42g in the X direction. In the non-connection state, the longest distance L1max of the facing distance L1 is equal to the width of the bottom surface 42j in the X direction.

  In the present embodiment, the facing distance L2 in the disconnected state is shorter than the width L3 of the short side in the cross-sectional shape of the electric wire 60. In the non-connection state, the facing distance L2 is shorter than the width L4 of the short side of the cross-sectional shape of the conductor portion 62. The longest distance L1max is set to be substantially the same as the width L4.

  In the connection step, first, the insulation displacement terminal 42 and the electric wire 60 are arranged such that the electric wire 60 is located on the opposite side to the bottom 42 e in the Z direction with respect to the facing region 44. At this time, the longitudinal direction of the electric wire 60 is defined as the Y direction. More specifically, the short side of the cross-sectional shape in the XY plane of the electric wire 60 is set along the X direction, and the long side is set along the Z direction.

  Next, the electric wire 60 and the press contact terminal 42 are brought closer to each other in the Z direction, and the electric wire 60 is brought closer to the facing region 44. The white arrow in FIG. 5 indicates the direction in which the electric wire 60 moves relative to the facing region 44. By moving the electric wire 60 to the bottom portion 42e side, as shown in FIG. 6, the covering portion 64 of the electric wire 60 comes into contact with the second surface 42h. And even after the covering part 64 contacts the 2nd surface 42h, the electric wire 60 is moved to the bottom part 42e side.

  Thereby, as shown in FIG. 7, the covering portions 64 on both sides in the X direction of the electric wire 60 can be removed so as to be scraped off. That is, the conductor portions 62 are exposed at both end surfaces of the electric wire 60 in the X direction. The electric wire 60 approaches the bottom portion 42e side while contacting the first surface 42g, and contacts the press contact surface 42f. Then, the electric wire 60 or the press contact terminal 42 is moved until the electric wire 60 is arranged at a predetermined position in the facing region 44. As described above, the electric wire 60 and the press contact terminal 42 can be connected. In the connection state, the entire exposed portion of the conductor portion 62 is in contact with a part of the press contact surface 42f.

  Next, effects of the electronic device 100 will be described.

  In the non-connection state of the present embodiment, the facing distance L1 between the press contact portions 42c increases from the removal portion 42d to the bottom portion 42e in the Z direction. According to this, in the connection state, it is possible to suppress the opposing distance L1 from becoming longer from the bottom 42e toward the removing portion 42d. That is, it is possible to prevent the holding portion 42b from opening in the connected state.

  Therefore, a reduction in the contact area between the electric wire 60 and the press contact terminal 42 can be suppressed without forming the press contact terminal 42 in a three-pronged shape. According to this, it is possible to suppress an increase in the width of the holding portion 42b. That is, it is possible to suppress an increase in the arrangement space of the press contact terminals 42.

  In the present embodiment, in order to improve the occupancy of the electric wire 60 in the motor, the electric wire 60 has a rectangular cross section. According to this, as compared with the configuration in which the cross-sectional shape of the electric wire 60 is a perfect circle, the holding portion 42b is more easily opened in the connected state, and the contact area between the electric wire 60 and the press contact terminal 42 is more likely to be reduced. On the other hand, in the present embodiment, even if the cross-sectional shape of the electric wire 60 is rectangular, it is possible to prevent the holding portion 42b from opening in the connected state due to the shape of the press contact terminal 42. Therefore, a decrease in the contact area between the electric wire 60 and the press contact terminal 42 can be suppressed while improving the occupancy of the electric wire 60 in the motor.

  By the way, conventionally, phosphor bronze has been adopted as a constituent material of the press contact terminal 42. In this case, the conductivity of the press contact terminal 42 is about 13% IACS. On the other hand, in the present embodiment, the conductivity of the press contact terminal 42 is set to 40% IACS or more.

  Here, the magnitude of the current that can flow through the press contact terminal 42 is determined according to the resistivity of the press contact terminal 42. Resistivity is inversely proportional to conductivity. When the conductivity is increased from 13% IACS to 40% IACS, the resistivity can be significantly reduced. More specifically, the resistivity can be reduced to 1/4. In contrast, when the conductivity is further increased from 40% IACS, the decrease in the resistivity is smaller than when the conductivity is increased from 13% IACS to 40% IACS.

  According to the above, by setting the conductivity of the press contact terminal 42 to 40% or more, a large current can flow without increasing the physical size of the press contact terminal 42 as compared with the conventional configuration. Therefore, it is possible to effectively suppress an increase in the arrangement space of the press contact terminals 42.

(2nd Embodiment)
In the present embodiment, the description of the portions common to the electronic device 100 described in the first embodiment will be referred to the description of the first embodiment.

  As shown in FIG. 8, the center in the Z direction of both end surfaces in the X direction of the electric wire 60 is defined as a center C1. The center in the Z direction of the press contact surface 42f is defined as a center C2. In the present embodiment, the length twice as long as the shortest distance L1min in the non-connection state is equal to or less than the longest distance L1max.

  As shown in FIG. 9, in the connection state, the entire both end surfaces in the X direction of the electric wire 60 are in contact with the press contact surface 42f. In the connected state, the center C1 and the center C2 are at substantially the same position. That is, the electric wire 60 is inserted into the facing region 44 such that the center C1 and the center C2 are located at substantially the same position. According to the above, in the connection state, the center in the Z direction of the contact portion of the press contact surface 42f with the electric wire 60 is substantially the same as the center C1 and the center C2.

  By the way, as the electric wire 60 is located closer to the removed portion 42d in the facing region 44, the spring reaction force acting on the electric wire 60 from the press contact portion 42c becomes smaller, and the electric wire 60 is more easily removed from the facing region 44. Therefore, when the center C1 of the electric wire 60 is located closer to the removal portion 42d than the center C2 of the press-contact surface 42f in the Z direction, the electric wire 60 is easily removed from the facing region 44. On the other hand, in the present embodiment, since the center C1 coincides with the center C2 in the Z direction, the electric wire 60 is positioned in the opposite region 44 in comparison with the configuration in which the center C1 is located closer to the removing portion 42d than the center C2. Can be suppressed.

  Further, as the electric wire 60 is located closer to the bottom portion 42e in the facing region 44, the stress acting on the connecting portion between the press contact portion 42c and the bottom portion 42e increases, and the connection reliability between the electric wire 60 and the press contact terminal 42 increases. Easy to fall. Therefore, if the center C1 of the electric wire 60 is located closer to the bottom portion 42e than the center C2 of the press contact surface 42f in the Z direction, the connection reliability between the electric wire 60 and the press contact terminal 42 tends to decrease. On the other hand, in the present embodiment, since the center C1 coincides with the center C2 in the Z direction, the electric wire 60 and the press-connecting terminal 42 are compared with the configuration in which the center C1 is located closer to the bottom 42e than the center C2. Can be suppressed from decreasing in connection reliability.

(Third embodiment)
In the present embodiment, the description of the portions common to the electronic device 100 described in the first embodiment will be referred to the description of the first embodiment.

  As shown in FIG. 10, a dent 42k is formed in each removal portion 42d. The recess 42k is recessed in the X direction from a portion of each removal portion 42d facing each other. The inner wall surface of the recess 42k has a curved shape.

  The removal part 42d has a corner 42m and a corner 42n as an opening end of the recess 42k. The corner portion 42m is formed at a position farther from the press contact portion 42c than the corner portion 42n in the Z direction. The facing distance L5 between the corners 42m in the X direction is longer than the facing distance between the corners 42n in the X direction. The corner 42m corresponds to a first corner described in the claims. The corner 42n corresponds to a second corner described in the claims.

  The angle of the corner 42n is about 90 °. The corner 42n is connected to the inner wall surface of the recess 42k and the third surface 42p. The third surface 42p is a plane extending from the corner 42n toward the press contact portion 42c in the Z direction. The third surface 42p is orthogonal to the X direction. The third surface 42p corresponds to a connecting surface described in the claims.

  The facing distance L6 between the third surfaces 42p in the X direction is constant in the Z direction. The facing distance L6 is equal to the facing distance between the corners 42n in the X direction. Further, the facing distance L6 is equal to the width L4 of the conductor portion 62. The length of the third surface 42p in the Z direction is longer than the width L7 which is the length of the long side of the cross-sectional shape of the electric wire 60.

  The press contact terminal 42 further has an intervening portion 42q interposed between each of the removal portion 42d and the press contact portion 42c. 10 to 14, the boundary between the interposed portion 42q and the removal portion 42d and the boundary between the interposed portion 42q and the press contact portion 42c are indicated by broken lines. The intervening portion 42q opens the holding portion 42b so that the electric wire 60 comes into contact with the electric wire 60 before coming into contact with the press contact surface 42f so that the electric wire 60 can come into contact with the press contact surface 42f.

  Each interposed portion 42q has a fourth surface 42r connecting the third surface 42p and the press contact surface 42f. The fourth surface 42r is a plane along the Y direction. In the non-connection state, the distance L8 between the fourth surfaces 42r in the X direction becomes shorter as going from the removing part 42d to the pressure contact part 42c in the Z direction. In the non-connection state, the angle between the fourth surfaces 42r is about 60 °. The fourth surface 42r corresponds to a flat surface described in the claims.

  When the electric wire 60 is brought closer to the bottom portion 42e in the connection step, as shown in FIG. 11, each of both end surfaces in the X direction of the electric wire 60 comes into contact with the corner portion 42m. That is, the electric wire 60 is sandwiched between the pair of corners 42m in the X direction. Thereby, the position in the X direction of the electric wire 60 is determined by the corner 42m. Therefore, the corner portion 42m can also be referred to as a positioning portion.

  When the electric wire 60 is further brought closer to the bottom portion 42e, one end surface of the electric wire 60 in the Z direction comes into contact with the corner portion 42n of the recess 42k. In a state where the electric wire 60 is in contact with the corner 42n of the recess 42k, the covering portion 64 overlaps the corner 42n and the conductor 62 overlaps the facing region between the third surfaces 42p in the projection view in the Z direction.

  When the electric wire 60 is further brought closer to the bottom portion 42e, as shown in FIG. 12, the coating portions 64 on both sides in the X direction of the electric wire 60 are shaved and removed by the corners 42n. That is, the conductor portions 62 are exposed at both end surfaces in the X direction of the electric wire 60 by the corners 42n. The electric wire 60 approaches the bottom part 42e while the exposed conductor part 62 is in contact with the third surface 42p. By approaching the bottom 42e, the electric wire 60 is disposed in the region where the third surfaces 42p face each other while the covering portion 64 is removed by the corner 42n.

  Since the opposing distance L6 between the third surfaces 42p is equal to the width L4 of the conductor portion 62, even when the electric wire 60 is arranged in the opposing region between the third surfaces 42p, the electric wire 60 is not connected to the fourth surface 42p. The length of the facing distance L6 does not change until it comes into contact with the surface 42r. According to this, while the covering portion 64 is being removed by the corner portion 42n, the removing portion 42d does not move, and the holding portion 42b does not open.

  When the electric wire 60 is brought closer to the bottom portion 42e, the electric wire 60 comes into contact with the fourth surface 42r as shown in FIG. By this contact, the holding portion 42b is opened so that the interposed portions 42q are separated from each other in the X direction. The closer the electric wire 60 is to the bottom part 42e, the larger the opening of the holding part 42b. When the holding portions 42b are opened so that the intervening portions 42q are separated from each other, the press contact portions 42c are also separated in the X direction.

  Then, when one end of the electric wire 60 on the bottom 42e side in the Z direction reaches the boundary between the fourth surface 42r and the press contact surface 42f in the Z direction, the press contact surface 42f becomes a surface orthogonal to the X direction. That is, the facing distance L1 has a length substantially equal to the width L4 and is constant in the Z direction. Thereby, the press contact terminal 42 is in a state where the electric wire 60 can be inserted into the region where the press contact portions 42c face each other.

  When the electric wire 60 is further brought closer to the bottom portion 42e, the exposed conductor portion 62 comes into contact with the press contact surface 42f as shown in FIG. Then, the electric wire 60 is arranged at a predetermined position, and the electric wire 60 and the press contact terminal 42 are connected.

  A recess 42k having a corner 42m and a corner 42n is formed in the removal section 42d of the present embodiment. According to this, since the two corners 42m and 42n are formed by the recess 42k, the covering portion 64 can be removed by the corners 42n while positioning the electric wire 60 by the corners 42m in the connection process. Therefore, the covering portion 64 can be reliably removed in the connecting step.

  In the present embodiment, the opposing distance L6 between the third surfaces 42p is substantially equal to the width L4 of the conductor portion 62 and is constant in the Z direction. Further, the length of the third surface 42p in the Z direction is longer than the width L7 of the electric wire 60. According to this, in the connecting process, while the covering portion 64 is being removed by the corner portion 42n, the removing portion 42d does not move, and the holding portion 42b does not open. Therefore, when the covering portion 64 is removed, the removing portion 42d does not separate from the electric wire 60, and the covering portion 64 can be reliably removed.

  Further, in the present embodiment, in the interposed portion 42q, the facing distance L8 between the fourth surfaces 42r decreases from the removal portion 42d to the pressure contact portion 42c in the Z direction. According to this, in the connection step, the holding portion 42b can be opened by contacting the electric wire 60 from which the covering portion 64 has been removed with the fourth surface 42r. Thereby, the electric wire 60 can be reliably brought into contact with the press contact surface 42f.

(Fourth embodiment)
In the present embodiment, the description of the portions common to the electronic device 100 described in the first embodiment will be referred to the description of the first embodiment.

  As shown in FIG. 15, the connecting portion between the press contact portion 42c and the bottom portion 42e of the surface forming the facing region 44 in the press contact terminal 42 has a curved surface shape. That is, the bottom surface 42j and the press contact surface 42f are smoothly connected without forming a corner at the connection portion.

  The bottom surface 42j of the present embodiment has a curved shape so that no corner is formed at a portion connected to the press contact surface 42f. In other words, the bottom surface 42j is continuously bent so that no corner is formed at the connection portion with the press contact surface 42f. Specifically, the bottom surface 42j has a curved surface shape recessed in the Z direction from the facing region 44. The cross-sectional shape of the bottom surface 42j in the XZ plane has a semicircular shape.

  In the present embodiment, the concentration of stress on the connecting portion between the press contact portion 42c and the bottom portion 42e in the connected state can be suppressed as compared with the configuration in which the connecting portion between the press contact portion 42c and the bottom portion 42e has an angle. Therefore, the connection reliability between the electric wire 60 and the press contact terminal 42 can be improved.

(Fifth embodiment)
In the present embodiment, the description of the portions common to the electronic device 100 described in the first embodiment will be referred to the description of the first embodiment.

  As shown in FIG. 16, the press contact terminal 42 further has a protruding portion 42s that protrudes in the X direction from the press contact surface 42f of each press contact portion 42c. 16 to 18, the boundary between the protruding portion 42s and the press contact portion 42c is indicated by a broken line. The protrusion 42s suppresses the electric wire 60 from moving from a normal position in the facing region 44 toward the bottom 42e.

  The protrusion 42s has a fifth surface 42t connected to the press contact surface 42f. The fifth surface 42t is a plane orthogonal to the Z direction. One end of the fifth surface 42t in the X direction is connected to the press contact surface 42f. The shortest distance L9 between the fifth surfaces 42t in the X direction is shorter than the shortest distance L1min of the facing distance L1 between the press contact surfaces 42f.

  In the connection step of the present embodiment, it is determined whether the position of the electric wire 60 in the connection state is normal. In order to perform this determination, a sensor that measures a load acting between the electric wire 60 and the press contact terminal 42, and a determination device that determines whether the position of the electric wire 60 in the connected state is normal based on an output signal of the sensor. Is used.

  In the connection step, the electric wire 60 is inserted into the facing region 44 until the electric wire 60 does not contact the fifth surface 42t. FIG. 17 shows a case where the position of the electric wire 60 is normal in the connection state.

  On the other hand, as shown in FIG. 18, the electric wire 60 may be inserted until the electric wire 60 contacts the fifth surface 42t by mistake. In FIG. 19, the horizontal axis indicates the position of the electric wire 60 with respect to the facing region 44 in the Z direction, and the vertical axis indicates the load acting between the electric wire 60 and the press contact terminal 42. The measuring device compares a sensor signal indicating the magnitude of the load with a threshold. Hereinafter, a load acting between the electric wire 60 and the press contact terminal 42 is simply referred to as a load.

  In the connection step, the load is zero until the electric wire 60 comes into contact with the press contact terminal 42. When the electric wire 60 reaches the position Z0, the electric wire 60 comes into contact with the press contact terminal 42 to generate a load. The closer the electric wire 60 is to the bottom portion 42e than the position Z0, the larger the contact area between the electric wire 60 and the press contact terminal 42, and the greater the load.

  When the electric wire 60 is moved closer to the bottom portion 42e, the covering portion 64 of the electric wire 60 is removed, and the entire exposed conductor portion 62 comes into contact with the press contact surface 42f. In a state where the entire exposed conductor portion 62 is in contact with the press contact surface 42f, the load is substantially constant even when the position of the electric wire 60 changes. In FIG. 19, a normal position of the electric wire 60 in the connection state is indicated by a position Z1.

  When the electric wire 60 is further moved from the position Z1 to the bottom portion 42e side, the electric wire 60 comes into contact with the fifth surface 42t at the position Z2, and the load rapidly increases. The determination device determines that the position of the electric wire 60 is abnormal.

  In the present embodiment, the protrusion 42s suppresses the insertion of the electric wire 60 toward the bottom 42e in the connection step. According to this, in the connection state, it is possible to prevent the electric wire 60 from being inserted to the far side of the facing region 44. Therefore, it is possible to suppress the holding portion 42b from being greatly opened, and it is possible to improve the connection reliability between the electric wire 60 and the press contact terminal 42.

  Incidentally, the value of the load greatly differs depending on whether or not the electric wire 60 is in contact with the fifth surface 42t. On the other hand, in the present embodiment, the sensor detects the load, and the determination device determines that the position of the electric wire 60 is abnormal when the electric wire 60 is in contact with the fifth surface 42t. According to this, the determination device can easily determine whether the position of the electric wire 60 is normal.

(Other embodiments)
As described above, the preferred embodiments of the present invention have been described. However, the present invention is not limited to the above embodiments, and can be variously modified and implemented without departing from the gist of the present invention.

  In the above-described embodiment, the example in which the cross-sectional shape of the electric wire 60 is rectangular is shown, but the present invention is not limited to this. As shown in a first modified example of FIG. 20, an example in which the cross-sectional shape of the electric wire 60 is a perfect circle can be adopted.

DESCRIPTION OF SYMBOLS 10 ... board, 10a ... front surface, 10b ... back surface, 12 ... through hole, 20 ... electronic component, 30 ... case, 32 ... bottom part, 32a ... inner surface, 34 ... cylinder part, 40 ... press contact terminal, 40a ... press contact part, 42 ... Press-contact terminal, 42a ... Press-contact portion, 42b ... Nipping portion, 42c ... Press-contact portion, 42d ... Removal portion, 42e ... Bottom portion, 42f ... Press-contact surface, 42g ... First surface, 42h ... Second surface, 42i ... Corner portion, 42j: bottom surface, 42k: concave, 42m: corner, 42n: corner, 42p: third surface, 42q: intervening portion, 42r: fourth surface, 42s: projecting portion, 42t: fifth surface, 44: facing region Reference numeral 50, housing, 50a, inner surface, 52, hole, 60, electric wire, 62, conductor, 64, coating, 100, electronic device

Claims (9)

An electronic device comprising: an electric wire (60); and a press-connecting terminal (42) that inserts the electric wire in a direction orthogonal to a longitudinal direction of the electric wire and holds the electric wire to establish an electrical connection.
The electric wire has a conductor (62) and a covering (64) covering the conductor.
The press-contact terminals are opposed to each other, and a pair of holding portions (42b) for holding the electric wire in a state where the electric wire is inserted in the facing region (44); a bottom portion (42e) for connecting the holding portions to each other; Has,
Each of the holding portions is formed between the removing portion and the bottom portion, and a removing portion (42d) for removing at least a part of the covering portion to expose the conductor portion from the covering portion. A pressure contact portion (42c) that presses the conductor portion exposed by the above by applying a spring reaction force to the conductor portion,
In a state where the electric wire is not inserted in the facing region, the facing distance (L1) between the press contact portions is increased from the removal portion toward the bottom portion ,
The removal portion is formed with a recess (42k) that is recessed in the direction in which the press contact portions face each other,
The recess has, as an open end, a first corner (42m) for positioning the electric wire, and a second corner (42n) formed on the press-contact portion side of the first corner,
The second corner is configured to remove the covering portion in a state where the electric wire is positioned by the first corner,
The electronic device , wherein an opposing distance (L5) between the first corners is longer than an opposing distance (L6) between the second corners . An electronic device comprising: an electric wire (60); and a press-connecting terminal (42) that inserts the electric wire in a direction orthogonal to a longitudinal direction of the electric wire and holds the electric wire to establish an electrical connection.
The electric wire has a conductor (62) and a covering (64) covering the conductor.
The press-contact terminals are opposed to each other, and a pair of holding portions (42b) for holding the electric wire in a state where the electric wire is inserted in the facing region (44); a bottom portion (42e) for connecting the holding portions to each other; Has,
Each of the holding portions is formed between the removing portion and the bottom portion, and a removing portion (42d) for removing at least a part of the covering portion to expose the conductor portion from the covering portion. A pressure contact portion (42c) that presses the conductor portion exposed by the above by applying a spring reaction force to the conductor portion,
In a state where the electric wire is not inserted in the facing region, the facing distance (L1) between the press contact portions is increased from the removal portion toward the bottom portion ,
The removal portion is formed with a recess (42k) that is recessed in the direction in which the press contact portions face each other,
The recess has, as an open end, a first corner (42m) for positioning the electric wire, and a second corner (42n) formed on the press-contact portion side of the first corner,
The second corner is configured to remove the covering portion in a state where the electric wire is positioned by the first corner,
The electronic device , wherein the recess has a flat portion connected to the first corner portion and a flat portion connected to the second corner portion . Cross-sectional shape of the wire in a plane perpendicular to the longitudinal direction, electronic device according to claim 1 or 2 which is rectangular. Each holding portion is interposed between the removing portion and the press contact portion, has a flat surface (42r), and opens the holding portion when inserting the electric wire into the facing region ( 42q), and
Each removing portion forms a corner for removing the covering portion, and has a connecting surface (42p) connected to the flat surface,
The connection surfaces of the respective removal portions face each other, and a facing distance (L6) is constant from the corner to the interposition portion,
In the direction in which the electric wire is inserted into the facing region, the length of the connection surface is longer than the width (L7) of the electric wire,
The flat surface is connected to a press contact surface (42f) of the press contact portion that presses against the electric wire at the other end opposite to the one end connected to the connection surface,
4. The opposing distance (L <b> 8) between the flat surfaces is reduced from the removed portion toward the press contact portion in a state where the electric wire is not inserted into the opposed region. 5. An electronic device according to claim 1.   5. The electronic device according to claim 1, wherein a connecting portion between the press contact portion and the bottom portion of a surface forming the facing region in the press contact terminal has a curved surface shape. 6.   The pressure contact portion has a protrusion (42s) that protrudes toward the opposing region at a position closer to the bottom than the electric wire inserted into the opposing region and suppresses the electric wire from moving toward the bottom. The electronic device according to claim 1.   The electronic device according to any one of claims 1 to 6, wherein the press contact terminal is formed using a metal material having a conductivity of 40% IACS or more. Electrical connection by pinching the electric wire while inserting the electric wire in a direction orthogonal to the longitudinal direction of the electric wire (60) having the conductor portion (62) and the covering portion (64) covering the conductor portion A pressure contact terminal (42) for establishing
A pair of holding portions (42b) that face each other and hold the electric wire in a state where the electric wire is inserted into the opposing region (44);
A bottom portion (42e) connecting the holding portions to each other,
Each of the holding portions is formed between the removing portion and the bottom portion, and a removing portion (42d) for removing at least a part of the covering portion to expose the conductor portion from the covering portion. A pressure contact portion (42c) that presses the conductor portion exposed by the above by applying a spring reaction force to the conductor portion,
In a state where the electric wire is not inserted in the facing region, the facing distance (L1) between the press contact portions is increased from the removal portion toward the bottom portion ,
The removal portion is formed with a recess (42k) that is recessed in the direction in which the press contact portions face each other,
The recess has, as an open end, a first corner (42m) for positioning the electric wire, and a second corner (42n) formed on the press-contact portion side of the first corner,
The second corner is configured to remove the covering portion in a state where the electric wire is positioned by the first corner,
The press-contact terminal , wherein an opposing distance (L5) between the first corners is longer than an opposing distance (L6) between the second corners . Electrical connection by pinching the electric wire while inserting the electric wire in a direction orthogonal to the longitudinal direction of the electric wire (60) having the conductor portion (62) and the covering portion (64) covering the conductor portion A pressure contact terminal (42) for establishing
A pair of holding portions (42b) that face each other and hold the electric wire in a state where the electric wire is inserted into the opposing region (44);
A bottom portion (42e) connecting the holding portions to each other,
Each of the holding portions is formed between the removing portion and the bottom portion, and a removing portion (42d) for removing at least a part of the covering portion to expose the conductor portion from the covering portion. A pressure contact portion (42c) that presses the conductor portion exposed by the above by applying a spring reaction force to the conductor portion,
In a state where the electric wire is not inserted in the facing region, the facing distance (L1) between the press contact portions is increased from the removal portion toward the bottom portion ,
The removal portion is formed with a recess (42k) that is recessed in the direction in which the press contact portions face each other,
The recess has, as an open end, a first corner (42m) for positioning the electric wire, and a second corner (42n) formed on the press-contact portion side of the first corner,
The second corner is configured to remove the covering portion in a state where the electric wire is positioned by the first corner,
The press contact terminal , wherein the recess has a flat portion connected to the first corner portion and a flat portion connected to the second corner portion .

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