JP6895705B2 - Power supply terminal structure, electrical junction box, and wire harness - Google Patents

Description

The present invention relates to a power supply terminal structure, an electrical junction box, and a wire harness.

As a conventional power supply terminal structure applied to a wire harness or the like of a vehicle, for example, Patent Document 1 discloses a booster cable holding structure having a holding connection portion which is a portion sandwiched by a clip portion of the booster cable. .. This sandwiching connection portion includes a rescue terminal portion and a resin terminal support portion. The rescue terminal portion is projected in a plate shape from the structural main body portion made of insulating resin. The resin terminal support portion is projected from the structural main body portion in a plate shape so as to overlap the surface of the rescue terminal portion.

Japanese Unexamined Patent Publication No. 2016-025706

By the way, in the booster cable holding structure described in Patent Document 1 described above, for example, even when an interfering object or the like exists in the vicinity of the rescue terminal portion, the clip portion of the booster cable is properly attached to the rescue terminal portion. A configuration that can be connected and supply power is desired.

The present invention has been made in view of the above circumstances, and an object of the present invention is to provide a power supply terminal structure, an electric junction box, and a wire harness capable of appropriately supplying power.

In order to achieve the above object, the power supply terminal structure according to the present invention includes a power supply terminal that is sandwiched and conducted by a clip portion of a booster cable and a power supply terminal that is sandwiched between the clip portion and the clip portion. It is characterized by including a support wall portion that abuts on the side surface side in the extending direction and supports the clip portion by inclining it in the horizontal direction and the vertical direction.

Further, in the power feeding terminal structure, the clip portion is supported by the support wall portion, and the clip portion is provided with an abutting wall portion that contacts the tip surface side of the clip portion in the extending direction and positions the clip portion. Can be.

Further, the power feeding terminal structure includes a holding wall portion that is sandwiched together with the feeding terminal by the clip portion, and the holding wall portion has a locking rib portion to which the claw portion of the clip portion is locked. can do.

In order to achieve the above object, the electric junction box according to the present invention includes a housing for accommodating electronic components inside and a power supply terminal structure housed inside the housing, and the power supply terminal structure is provided. With the power supply terminal sandwiched and conducted by the clip portion of the booster cable and the power supply terminal sandwiched by the clip portion, the clip portion abuts on the side surface side in the extending direction of the clip portion and the clip portion is held in the horizontal direction and in the horizontal direction. It is characterized by including a support wall portion that is inclined and supported in the vertical direction.

In order to achieve the above object, the wire harness according to the present invention includes a conductive wiring material, a housing for accommodating an electronic component electrically connected to the wiring material, and the housing. The power supply terminal structure includes an electric junction box including a power supply terminal structure housed inside the body, and the power supply terminal structure has a power supply terminal sandwiched and conducted by a clip portion of a booster cable and the power supply terminal sandwiched by the clip portion. In this state, the clip portion is provided with a support wall portion that abuts on the side surface side in the extending direction and supports the clip portion by inclining it in the horizontal direction and the vertical direction.

In the power supply terminal structure, the electric junction box, and the wire harness according to the present invention, the support wall portion abuts on the side surface side in the extending direction of the clip portion in a state where the power supply terminal is sandwiched by the clip portion of the booster cable. With this configuration, the power supply terminal structure, the electric junction box, and the wire harness can be supported by the support wall portion by inclining the clip portion in the horizontal direction and the vertical direction. As a result, the power supply terminal structure, the electric junction box, and the wire harness are clipped to the power supply terminal even when the clip portion cannot be connected to the power supply terminal from the upper side in the vertical direction, for example. The portion can be supported in an inclined posture. As a result, the power supply terminal structure, the electric junction box, and the wire harness can ensure an appropriate connection state between the power supply terminal and the clip portion, so that the power supply can be properly performed. ..

FIG. 1 is a partial perspective view showing a schematic configuration of an electrical junction box according to an embodiment. FIG. 2 is a partial perspective view showing a schematic configuration of the electrical junction box according to the embodiment. FIG. 3 is a partial perspective view showing a schematic configuration of a power supply terminal structure in the electrical junction box according to the embodiment. FIG. 4 is a partial perspective view showing a schematic configuration of a power supply terminal structure in the electrical junction box according to the embodiment. FIG. 5 is a partial side view showing a schematic configuration of a power supply terminal structure in the electrical junction box according to the embodiment. FIG. 6 is a partial perspective view showing the positional relationship between the locking rib portion of the power supply terminal structure and the clip portion of the booster cable in the electrical junction box according to the embodiment. FIG. 7 is a partial perspective view showing the positional relationship between the locking rib portion of the power supply terminal structure and the clip portion of the booster cable in the electrical junction box according to the embodiment.

Hereinafter, embodiments according to the present invention will be described in detail with reference to the drawings. The present invention is not limited to this embodiment. In addition, the components in the following embodiments include those that can be easily replaced by those skilled in the art, or those that are substantially the same.

In FIG. 1, which will be described below, a part of the electronic component, the wiring material, the upper cover, and the lower cover are omitted by a two-dot chain line, and the other figures are the electronic component, the wiring material, the upper cover, and the lower cover. The illustration itself is omitted. Further, in the following description, of the first direction, the second direction, and the third direction that intersect each other, the first direction is referred to as "height direction X", and the second direction is referred to as "first width direction Y". The third direction is called "second width direction Z". Here, the height direction X, the first width direction Y, and the second width direction Z are orthogonal (intersect) with each other. Typically, when the wire harness is mounted on the vehicle and the vehicle is located on the horizontal plane, the height direction X is along the vertical direction, and the first width direction Y and the second width direction Z are along the horizontal direction. .. The height direction X typically corresponds to the stacking direction of the frame, the upper cover, and the lower cover constituting the housing. Unless otherwise specified, the directions used in the following description are such that the parts are assembled to each other, the power supply terminal structure, the electric junction box, and the wire harness are mounted on the vehicle, and the vehicle is located on a horizontal plane. It will be explained as the direction of.

[Embodiment]
The power supply terminal structure 1 according to the present embodiment shown in FIGS. 1 and 2 is applied to an electric junction box 100 mounted on a vehicle such as an automobile, and is used when charging the battery of the vehicle from a power supply source outside the vehicle. It is a thing. Here, the power supply source outside the vehicle is, for example, a power source, a charger, a generator, or the like of another vehicle serving as a rescue vehicle. The electric junction box 100 is mounted on a vehicle and incorporated into a wire harness WH. In the wire harness WH, for example, for connection between each device mounted on a vehicle, a plurality of wiring materials W used for power supply and signal communication are bundled into a collective part, and a plurality of wirings are arranged by a connector or the like. The material W is connected to each device. The wire harness WH includes a conductive wiring material W and an electrical connection box 100 that is electrically connected to the wiring material W. The wiring material W is composed of, for example, a metal rod, an electric wire, a bundle of electric wires, and the like. The metal rod is formed by covering the outside of a conductive rod-shaped member with an insulating covering portion. An electric wire is formed by covering the outside of a conductor portion (core wire) made of a plurality of conductive metal strands with an insulating covering portion. The electric wire bundle is a bundle of the electric wires. In the wire harness WH, a plurality of wiring materials W are bundled and aggregated, and the electric junction box 100 is electrically connected via a connector or the like provided at the terminal of the bundled wiring materials W. The wire harness WH may also include a grommet, a protector, an exterior material, a fixture, and the like.

The electrical junction box 100 collectively houses electrical components such as connectors, fuses, relays, capacitors, branch parts, IPS (Intelligent Power Switch), and electronic control units. The electric junction box 100 is installed, for example, in the engine room or the vehicle interior of the vehicle. The electric junction box 100 is connected to a power source such as a battery and various electronic devices mounted in the vehicle via a wiring material W or the like. The electric junction box 100 distributes the electric power supplied from the power source to various electronic devices in the vehicle. The electrical junction box 100 may also be referred to as a junction box, a fuse box, a relay box, or the like, but in the present embodiment, these are collectively referred to as an electrical junction box. Hereinafter, the configuration of the electrical junction box 100 will be described in detail with reference to each figure.

Specifically, as shown in FIGS. 1 and 2, the electrical junction box 100 includes various electronic components 101 and a housing 102. In the electrical connection box 100, the electronic component 101 is housed in the housing 102, and the wiring material W is electrically connected to the electronic component 101.

The electronic component 101 is an element that exhibits various functions. The electronic component 101 is, for example, a connector, a fuse, a relay, a capacitor, a branch portion, an IPS, an electronic control unit, or the like.

The housing 102 houses various electronic components 101 inside. The housing 102 includes, for example, a frame 103, an upper cover 104, a lower cover 105, and the like. The frame 103, the upper cover 104, and the lower cover 105 are formed of an insulating synthetic resin. The frame 103 is formed in a tubular frame shape having openings on two surfaces facing each other along the height direction X. The upper cover 104 is a lid-shaped (cover-shaped) member that closes one opening of the frame 103 in the height direction X. The lower cover 105 is a dish-shaped (tray-shaped) member that closes the other opening of the frame 103 in the height direction X. In the housing 102, the frame 103, the upper cover 104, and the lower cover 105 are laminated and assembled to each other along the height direction X. In the housing 102, the upper cover 104 is assembled on one side of the frame 103 in the height direction X, and the lower cover 105 is assembled on the other side of the frame 103 in the height direction X. With this configuration, the housing 102 is formed into a hollow box shape as a whole by combining the frame 103, the upper cover 104, and the lower cover 105. In the housing 102, an internal space portion partitioned by the frame 103, the upper cover 104, and the lower cover 105 constitutes the accommodation space portion 106.

In the electrical junction box 100, the electronic component 101 is mounted on the component mounting portion 107 formed in the accommodation space portion 106. The component mounting portion 107 may be formed integrally with the frame 103. Further, the component mounting portion 107 may form a so-called block formed separately from the frame 103 and locked to the frame 103. Various circuit bodies such as a bus bar made of a conductive metal material are assembled to the component mounting portion 107. Various circuit bodies such as the bus bar electrically connect each electronic component 101 mounted on the component mounting portion 107 to form a part of the electric circuit, and are arranged in the accommodation space portion 106. The material W is electrically connected. The wiring material W is arranged in the accommodation space 106 through, for example, an insertion port 108 formed in a mating surface between the frame 103 and the lower cover 105. The electronic component 101 and the wiring material W are electrically connected to each other via the circuit body, terminals, or the like in a state of being assembled and mounted on the component mounting portion 107 to form a required electric circuit.

Further, as shown in FIGS. 1, 2, 3, 4, and 5, the electrical junction box 100 of the present embodiment includes a power supply terminal structure 1 housed inside the housing 102. A configuration is realized in which power can be appropriately supplied to the vehicle via the power supply terminal structure 1.

Specifically, the power supply terminal structure 1 includes a power supply terminal 2, a holding wall portion 3, a support wall portion 4, a contact wall portion 5, and a rotating cover 6. The power feeding terminal 2 is formed of a conductive metal material separately from the above-mentioned component mounting portion 107, and is assembled to the component mounting portion 107. The holding wall portion 3, the supporting wall portion 4, and the abutting wall portion 5 are integrally formed with the above-mentioned component mounting portion 107 by a synthetic resin having an insulating property. The rotating cover 6 is formed of an insulating synthetic resin separately from the above-mentioned component mounting portion 107, and is assembled to the component mounting portion 107.

The power supply terminal 2 is a member that is sandwiched and conducted by the clip portion 201 of the booster cable 200. The power supply terminal 2 typically constitutes a so-called rescue terminal used when charging the vehicle battery from a power supply source outside the vehicle. The power supply terminal 2 is electrically connected to the battery of the vehicle via various circuits such as a bus bar and a wiring material W assembled to the component mounting portion 107.

Here, the clip portion 201 electrically connected to the power feeding terminal 2 is an electrical connection portion provided at the terminal of the booster cable 200. The clip portion 201 is configured to include a pair of sandwiching members 202 formed of a conductive metal material (see also FIGS. 6, 7 and the like). Each of the pair of sandwiching members 202 has a plurality of claws (tooth portions) 202a formed on surfaces facing each other (holding surfaces for sandwiching the power feeding terminal 2) (see also FIGS. 6 and 7). Here, the claw portion 202a is formed at the end of the side surface 202b in the extending direction of each holding member 202. In other words, the side surface 202b is a wall surface on which the claw portion 202a is formed in each holding member 202. In each holding member 202, the side surfaces 202b on which the claw portion 202a is formed are provided in pairs facing each other. Each of the sandwiching members 202 is formed so that each side surface 202b is substantially orthogonal to the tip surface 202c in the extending direction. Each side surface 202b of each holding member 202 constitutes a side surface of the clip portion 201 in the extending direction. Each tip surface 202c of each holding member 202 constitutes a tip surface in the extending direction of the clip portion 201. Then, the clip portion 201 sandwiches and sandwiches the power supply terminal 2 which is the object to be connected by the pair of sandwiching members 202. In the clip portion 201, in a state where the power feeding terminal 2 is sandwiched by the pair of holding members 202, some of the plurality of claws (tooth portions) 202a come into contact with the feeding terminal 2 and are electrically connected to the feeding terminal 2. Form a contact point. The end of the booster cable 200 opposite to the clip portion 201 is connected to the power supply source described above. As a result, the booster cable 200 electrically connects the power supply terminal 2 and the power supply source via the clip portion 201 to conduct electricity.

The power supply terminal 2 of the present embodiment is formed in a plate shape, and is assembled to the component mounting portion 107 so that the plate thickness direction is along the second width direction Z. The power feeding terminal 2 is provided so as to project from the component mounting portion 107 to one side of the height direction X (the side where the upper cover 104 is located) and exposed. In the power feeding terminal 2, a portion exposed from the component mounting portion 107 is formed in a polygonal shape. More specifically, the power feeding terminal 2 has an inclined surface 2a formed at one end of the first width direction Y in a portion exposed from the component mounting portion 107. The inclined surface 2a is inclined with respect to the height direction X (vertical direction) and the first width direction Y (horizontal direction). The inclined surface 2a is inclined so that the amount of protrusion from the component mounting portion 107 along the height direction X gradually decreases toward one end of the first width direction Y. The exposed portion of the power feeding terminal 2 is sandwiched by the clip portion 201 and conducted.

The sandwiching wall portion 3 is a wall portion sandwiched together with the power feeding terminal 2 by the clip portion 201. The holding wall portion 3 is formed in a plate shape, and is integrally formed with the component mounting portion 107 so that the plate thickness direction is along the second width direction Z. The holding wall portion 3 is provided so as to project from the component mounting portion 107 to one side (the side where the upper cover 104 is located) in the height direction X. The holding wall portion 3 is formed at a position adjacent to the power feeding terminal 2 in the second width direction Z. The sandwiching wall portion 3 is provided so as to face and overlap one surface of the power feeding terminal 2 in the second width direction Z along the second width direction Z. The sandwiching wall portion 3 is formed in a polygonal shape in which a portion protruding from the component mounting portion 107 has substantially the same shape as the power feeding terminal 2, or a polygonal shape slightly larger than the power feeding terminal 2. More specifically, in the holding wall portion 3, the feeding terminal 2 has an inclined surface 3a formed at one end of the first width direction Y at a portion protruding from the component mounting portion 107. The inclined surface 3a is inclined in substantially the same direction as the above-mentioned inclined surface 2a. That is, the inclined surface 3a is inclined with respect to the height direction X (vertical direction) and the first width direction Y (horizontal direction). The inclined surface 3a is inclined so that the amount of protrusion from the component mounting portion 107 along the height direction X gradually decreases toward one end of the first width direction Y.

Further, the holding wall portion 3 of the present embodiment has a locking rib portion 31 (see also FIGS. 6 and 7). The locking rib portion 31 is a portion of the holding wall portion 3 where the claw portion 202a of the clip portion 201 is locked. A plurality of locking rib portions 31 are provided on the holding wall portion 3. The locking rib portion 31 is formed on the surface of the holding wall portion 3 opposite to the power supply terminal 2 side in the second width direction Z. The locking rib portion 31 projects from the surface of the holding wall portion 3 opposite to the power supply terminal 2 side along the second width direction Z and is formed in a protruding shape. Here, a total of three locking rib portions 31, a locking rib portion 31a, a locking rib portion 31b, and a locking rib portion 31c, are provided. The locking rib portion 31a is formed linearly along the inclined surface 3a on the edge of the holding wall portion 3 on the inclined surface 3a side. The locking rib portion 31b and the locking rib portion 31c are formed linearly along the height direction X (vertical direction). The locking rib portion 31b is located at substantially the center of the first width direction Y in the holding wall portion 3. The locking rib portion 31c is located at the other end portion of the holding wall portion 3 opposite to the end portion on the inclined surface 3a side in the first width direction Y. The locking rib portion 31b and the locking rib portion 31c are in a state where the rib-to-rib pitch P (see FIG. 2) along the first width direction Y is sandwiched between the feeding terminal 2 and the holding wall portion 3 by the clip portion 201. The claw portions 202a are formed so as to have a pitch so as not to ride on the locking rib portions 31b and 31c. In the following description, the locking rib portion 31a, the locking rib portion 31b, and the locking rib portion 31c may be simply referred to as the "locking rib portion 31" when it is not necessary to distinguish them. is there.

The support wall portion 4 abuts on the side surface 202b side in the extending direction of the clip portion 201 in a state where the power feeding terminal 2 and the sandwiching wall portion 3 are sandwiched by the clip portion 201, and the clip portion 201 is placed in the horizontal direction and in the horizontal direction. , A wall part that is tilted and supported in the vertical direction. Here, the support wall portion 4 supports the clip portion 201 by inclining it with respect to the component mounting surface of the component mounting portion 107. The component mounting surface of the component mounting portion 107 is a surface along the horizontal direction in a state where the power supply terminal structure 1, the electric junction box 100, and the wire harness WH are mounted on the vehicle and the vehicle is located on a horizontal plane. The support wall portion 4 is integrally formed with the component mounting portion 107 so as to project from the component mounting portion 107 to one side (the side where the upper cover 104 is located) in the height direction X. The support wall portion 4 has a support surface 4a that abuts and supports the side surface 202b of the clip portion 201, and the support surface 4a is formed in a triangular shape forming an inclined surface. The support wall portions 4 of the present embodiment are provided in pairs at intervals along the second width direction Z. One support wall portion 4 is formed integrally with the holding wall portion 3 on the surface of the holding wall portion 3 adjacent to the power feeding terminal 2. The one support wall portion 4 is formed so as to be continuous with the inclined surface 3a at one end of the holding wall portion 3 in the first width direction Y. The other support wall portion 4 is formed at intervals from the holding wall portion 3 in the second width direction Z, and is integrally formed with the reinforcing wall portion 4b erected on the component mounting portion 107. In the pair of support wall portions 4, one support wall portion 4 is formed to be slightly smaller than the other support wall portion 4. Then, each support surface 4a of each support wall portion 4 is formed at substantially the same position when viewed along the second width direction Z (hereinafter, may be referred to as "second width direction view") (hereinafter, may be referred to as "second width direction view"). (See FIG. 5). Each support surface 4a is inclined in a direction opposite to the inclined surfaces 2a and 3a with respect to the height direction X (vertical direction) and the first width direction Y (horizontal direction). That is, each support surface 4a is inclined so that the amount of protrusion from the component mounting portion 107 along the height direction X gradually decreases toward the other end in the first width direction Y. Each support surface 4a is formed at an angle that intersects (orthogonally) substantially perpendicularly with the inclined surfaces 2a and 3a in the second width direction view. The inclination angle of each support surface 4a is geometrically determined according to the positional relationship between the position where the power feeding terminal 2 is installed and the surrounding structure 300 (see FIG. 5). The inclination angle of each support surface 4a is typically such that the clip portion 201 does not interfere with the other structure 300 in a state where the clip portion 201 is supported by each support surface 4a at the installation position of the power feeding terminal 2. Set to angle. Here, each support surface 4a is formed at an angle of about 45 degrees with respect to the horizontal direction (in other words, with respect to the component mounting surface of the component mounting portion 107) in the second width direction view. Each support surface 4a has a side surface 202b in the extending direction of the clip portion 201 from the lower side in the vertical direction (height direction X) in a state where the power supply terminal 2 and the sandwiching wall portion 3 are sandwiched by the clip portion 201. To support.

In the abutting wall portion 5, the power feeding terminal 2 and the holding wall portion 3 are sandwiched by the clip portion 201, and the side surface 202b of the clip portion 201 is supported by the support surface 4a of the support wall portion 4, and the clip portion 201 It is a wall portion that comes into contact with the tip surface 202c side in the extending direction and positions the clip portion 201. The abutting wall portion 5 is integrally formed with the component mounting portion 107 so as to project from the component mounting portion 107 to one side (the side where the upper cover 104 is located) in the height direction X. The abutting wall portion 5 has a positioning surface 5a that abuts and positions the tip surface 202c of the clip portion 201, and the positioning surface 5a is formed in a triangular shape forming an inclined surface. The abutting wall portions 5 of the present embodiment are provided in pairs at intervals along the second width direction Z. One of the abutting wall portions 5 is formed integrally with the sandwiching wall portion 3 on the surface of the sandwiching wall portion 3 adjacent to the power feeding terminal 2. The one abutting wall portion 5 is formed at the other end portion of the holding wall portion 3 on the opposite side to the inclined surface 3a side end portion in the first width direction Y. The one abutting wall portion 5 is formed at a distance from the above-mentioned one supporting wall portion 4 in the first width direction Y. The other abutting wall portion 5 is formed at a distance from the holding wall portion 3 in the second width direction Z, and is integrally formed with the reinforcing wall portion 5b erected on the component mounting portion 107. The other abutting wall portion 5 is formed at a distance from the other supporting wall portion 4 described above in the first width direction Y. In the pair of abutting wall portions 5, one abutting wall portion 5 is formed to be slightly smaller than the other abutting wall portion 5. Then, each positioning surface 5a of each abutting wall portion 5 is formed at substantially the same position in the second width direction view (see FIG. 5). Each positioning surface 5a is inclined in the same direction as the inclined surfaces 2a and 3a and in the direction opposite to each supporting surface 4a with respect to the height direction X (vertical direction) and the first width direction Y (horizontal direction). There is. That is, each positioning surface 5a is inclined so that the amount of protrusion from the component mounting portion 107 along the height direction X gradually decreases toward one end of the first width direction Y. Each positioning surface 5a is formed at an angle substantially parallel to the inclined surfaces 2a and 3a and perpendicular to each supporting surface 4a in the second width direction view. Here, each positioning surface 5a faces each support surface 4a along the first width direction Y, and in the second width direction, the component mounting portion 107 is mounted in the horizontal direction (in other words, the component mounting portion 107 is mounted). It is formed at an angle of about 45 degrees (with respect to the surface).

The rotation cover 6 is a protective member that is rotatably assembled to the component mounting portion 107. The rotating cover 6 is rotatable between a protective position and a used position. The protection position of the rotating cover 6 means that the power feeding terminal 2, the holding wall portion 3, the supporting wall portion 4, and the abutting wall portion 5 are covered with the rotating cover 6 in a state where the feeding terminal 2 is not used. It is a position to protect. The position where the rotating cover 6 is used is a position where the power feeding terminal 2 and the like are exposed to the outside of the rotating cover 6 when the power feeding terminal 2 is used.

In the power supply terminal structure 1 described above, as shown in FIGS. 4 and 5, the power supply terminal 2 is exposed to the outside of the rotation cover 6 in a state where the rotation cover 6 is rotated to the used position. In this state, in the power supply terminal structure 1, the power supply terminal 2 is sandwiched by the clip portion 201 of the booster cable 200 and electrically connected, so that the booster cable 200, the clip portion 201, and the power supply terminal 2 are electrically connected from the power supply source outside the vehicle. It becomes possible to charge the battery of the vehicle via the above. In this case, in the power feeding terminal structure 1, the support surface 4a of the support wall portion 4 comes into contact with the side surface 202b side in the extending direction of the clip portion 201 while the feeding terminal 2 is sandwiched by the clip portion 201. With this configuration, the power supply terminal structure 1 makes the clip portion 201 in the horizontal direction and the vertical direction (in other words, with respect to the component mounting surface of the component mounting portion 107) by the support surface 4a of the support wall portion 4. It can be tilted and supported. Here, the power feeding terminal structure 1 supports the side surface 202b of one of the holding members 202 (the holding member 202 located on the power feeding terminal 2 side) constituting the clip portion 201 by the support surface 4a.

For example, as shown in FIG. 5, the power supply terminal 2 may be provided at a position where various structures 300 exist on the upper side in the vertical direction in the engine room or the like, and the clip portion 201 may be provided from directly above the power supply terminal 2. You may be in a situation where you cannot connect. However, even in such a case, the power supply terminal structure 1 of the present embodiment is in a posture in which the clip portion 201 is tilted with respect to the power supply terminal 2 by the support surface 4a of the support wall portion 4 as described above. Can be supported. With this configuration, the power supply terminal structure 1 suppresses interference between the structure 300 directly above the power supply terminal 2 and the clip portion 201, and then regulates the clip portion 201 from falling off from the power supply terminal 2 by its own weight. Can be done. As a result, the power supply terminal structure 1, the electric junction box 100, and the wire harness WH can ensure an appropriate connection state between the power supply terminal 2 and the clip portion 201, so that power can be supplied appropriately.

Further, in the power supply terminal structure 1 described above, in a state where the power supply terminal 2 is sandwiched by the clip portion 201 and the clip portion 201 is supported by the support wall portion 4, the positioning surface 5a of the abutting wall portion 5 is the clip portion 201. It abuts on the tip surface 202c side in the extending direction. With this configuration, the power feeding terminal structure 1 can position the tip surface 202c of the clip portion 201 in a state of being supported by the support wall portion 4 at an appropriate position by the positioning surface 5a of the abutting wall portion 5. As a result, the power supply terminal structure 1, the electric connection box 100, and the wire harness WH can secure a more appropriate connection state after positioning the positional relationship between the power supply terminal 2 and the clip portion 201 in an appropriate positional relationship. Therefore, it is possible to supply power more appropriately.

Further, in the power feeding terminal structure 1 described above, the locking rib portion 31 is provided on the holding wall portion 3 sandwiched together with the feeding terminal 2 by the clip portion 201. With this configuration, in the power supply terminal structure 1, as shown in FIGS. 6 and 7, the power supply terminal 2 and the claw portion 202a of the clip portion 201 sandwiching the sandwiching wall portion 3 are engaged with the locking rib portion 31. Since it is stopped, it is possible to prevent the clip portion 201 from falling off from the power feeding terminal 2. In particular, the power supply terminal structure 1 includes, as the locking rib portion 31, a locking rib portion 31a located substantially perpendicular to the clip portion 201 in a state where the feeding terminal 2 and the holding wall portion 3 are sandwiched, so that the booster cable is included. It is possible to improve the holding force of the clip portion 201 when the 200 is pulled. As a result, the power supply terminal structure 1, the electric junction box 100, and the wire harness WH can more reliably secure the proper connection state between the power supply terminal 2 and the clip portion 201, so that the power supply can be performed more appropriately. Can be done.

Further, here, the tip surface of the abutting wall portion 5 is such that the feeding terminal 2 and the holding wall portion 3 are sandwiched by the clip portion 201, and the claw portions 202a do not ride on the locking rib portions 31b and 31c. It is provided at a position where the 202c can be positioned. In this respect as well, the power supply terminal structure 1, the electric junction box 100, and the wire harness WH can more reliably secure an appropriate connection state between the power supply terminal 2 and the clip portion 201, so that power can be supplied more appropriately. be able to.

The power supply terminal structure, the electric junction box, and the wire harness according to the above-described embodiment of the present invention are not limited to the above-described embodiment, and various changes can be made within the scope of the claims. is there.

In the above description, the power supply terminal structure 1 has been described as being applied to the electric connection box 100, but the present invention is not limited to this, and the power supply terminal structure 1 may be provided in the vehicle separately from the electric connection box 100.

In the above description, the holding wall portion 3 has been described as having the locking rib portion 31, but the present invention is not limited to this.

In the above description, the power supply terminal structure 1 has been described as including the holding wall portion 3, the abutting wall portion 5, and the rotating cover 6, but the present invention is not limited to this.

In the above description, the support wall portion and the abutting wall portion 5 have been described as being provided in pairs at intervals along the second width direction Z, but the present invention is not limited to this.

1 Power supply terminal structure 2 Power supply terminal 2a Inclined surface 3 Holding wall part 3a Inclined surface 4 Support wall part 4a Support surface 5 Butt wall part 5a Positioning surface 31, 31a, 31b, 31c Locking rib part 100 Electrical connection box 101 Electronic component 102 Housing 200 Booster cable 201 Clip part 202a Claw part 202c Tip surface 202b Side surface W Wire distribution material WH Wire harness

Claims (5)

A power supply terminal that is sandwiched and conducted by the clip part of the booster cable,
With the power feeding terminal sandwiched by the clip portion, a support wall portion that abuts on the side surface side in the extending direction of the clip portion and supports the clip portion by inclining it in the horizontal direction and the vertical direction. It is characterized by having
Power supply terminal structure. With the clip portion supported by the support wall portion, the abutting wall portion that abuts on the tip surface side in the extending direction of the clip portion and positions the clip portion is provided.
The power supply terminal structure according to claim 1. A holding wall portion that is sandwiched by the clip portion together with the power feeding terminal is provided.
The holding wall portion has a locking rib portion to which the claw portion of the clip portion is locked.
The power supply terminal structure according to claim 1 or 2. A housing that houses electronic components inside,
It has a power supply terminal structure housed inside the housing.
The power supply terminal structure is
A power supply terminal that is sandwiched and conducted by the clip part of the booster cable,
With the power feeding terminal sandwiched by the clip portion, a support wall portion that abuts on the side surface side in the extending direction of the clip portion and supports the clip portion by inclining it in the horizontal direction and the vertical direction. It is characterized by having
Electrical junction box. Conductive wiring material and
It is provided with a housing that houses electronic components that are electrically connected to the wiring material, and an electrical connection box that includes a power supply terminal structure that is housed inside the housing.
The power supply terminal structure is
A power supply terminal that is sandwiched and conducted by the clip part of the booster cable,
With the power feeding terminal sandwiched by the clip portion, a support wall portion that abuts on the side surface side in the extending direction of the clip portion and supports the clip portion by inclining it in the horizontal direction and the vertical direction. It is characterized by having
Wire harness.

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