JP2012131271A - Earth connection structure for wiring harness - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an earth connection structure for a wiring harness that can improve the work efficiency of connecting the earth while suppressing a cost increase of the wiring harness.SOLUTION: A mounting bracket 14a includes a mounting plate 50 for mounting the wiring harness and a tab 52 extending in a direction along and opposed to a mounting direction of the wiring harness 11 to the mounting plate 50. The wiring harness 11 is integrated by a foaming mold body 16 formed of a foaming resin and includes an earth terminal holding part 22 in the foaming mold body 16 for holding an earth terminal 34 in a posture opening forward in the mounting direction. The earth terminal 34 held by the earth terminal holding part 22 is connected to the tab 52 by mounting the wiring harness 11 to the mounting plate 50.

Description

  The present invention relates to a ground connection structure for a wire harness wired to an instrument panel, a door panel, or the like of a vehicle.

  Various electrical components are attached to an instrument panel or a door panel of a vehicle such as an automobile, and a wire harness is connected to these electrical components for power supply or the like.

  When attaching the earth terminal of the earth wire drawn out from such a wire harness to the vehicle body side for earth connection, it is common practice to use an earth bolt. In this case, the positioning of the ground terminal and the bolt hole, the bolt fastening operation, the bolt torque management, and the like are required for the ground portion. Therefore, the work efficiency is poor and takes time, resulting in an increase in cost.

  For this reason, it is known to facilitate the attachment to the vehicle body by devising the shape of the ground terminal (see, for example, Patent Documents 1 and 2).

  Also, there is a clamp that is attached to a bracket on the vehicle body side while holding a wire harness, and is provided with a ground attachment portion for attaching a ground terminal of a ground wire. In this clamp, when the ground terminal is attached to the ground attachment portion, the ground wire is electrically connected to the internal terminal. In this state, when the clamp is attached to the bracket, the internal terminal is electrically connected to the bracket. As a result, the ground wire can be grounded to the vehicle body without reducing the working efficiency (see, for example, Patent Document 3). In addition, when a clamp with a ground terminal attached is attached to a bracket, the bracket is directly connected to the ground terminal (for example, see Patent Document 4).

JP 2004-207077 A JP 2005-222865 A JP-A-8-9540 JP 2006-296050 A

  However, in the ones described in Patent Documents 1 and 2 described above, the work of connecting the ground terminal to the vehicle body has to be performed separately from the work of attaching the wire harness to the vehicle body, resulting in complicated operations. .

  On the other hand, the devices described in Patent Documents 3 and 4 can connect the ground terminal to the vehicle body by attaching the wire harness to the vehicle body, thereby simplifying the operation. However, it is necessary to position and attach the clamp provided with the ground attachment for attaching the ground terminal to a predetermined position of the wire harness, which complicates the production of the wire harness and increases the production cost.

  The present invention has been made in view of the above-described circumstances, and an object of the present invention is to provide a wire harness ground connection structure capable of improving the work efficiency of ground connection while suppressing the cost increase of the wire harness. It is in.

In order to achieve the above-described object, a ground connection structure for a wire harness according to the present invention is characterized by any one of (1) to (4) below.
(1) An earth connection structure in which an earth terminal provided at a terminal of an earth wire drawn out from a wire harness formed by bundling a plurality of cables and being integrated is grounded to a vehicle body side metal member,
The vehicle body side metal member has a harness attachment portion for attaching the wire harness, and a ground connection portion extending in the opposite direction along the attachment direction of the wire harness to the harness attachment portion,
The wire harness is integrated with the mold body, and has an earth terminal holding part integrally holding the earth terminal in a posture that opens forward in the attachment direction.
The earth terminal held by the earth terminal holding part is connected to the earth connecting part by attaching the wire harness to the harness attaching part.
(2) In the ground connection structure of the wire harness configured as described in (1) above, the mold body is a foam mold body obtained by foaming foam beads.
(3) In the ground connection structure of the wire harness configured as described in (1) or (2) above, the ground terminal holding portion extends the ground wire from the ground terminal to the rear in the mounting direction to thereby connect the ground terminal. To hold.
(4) In the ground connection structure of the wire harness having the structure according to any one of (1) to (3), the ground terminal is held by the ground terminal holding portion and is orthogonal to the mounting direction. And a pair of clamping plate portions that extend forward from the opposite position of the substrate portion in the mounting direction and sandwich the ground connection portion inserted between them.
(5) In the ground connection structure of the wire harness having the structure according to any one of (1) to (3), the ground terminal is in a state of being held by the ground terminal holding portion, and a contact portion along the attachment direction; A spring that presses the ground connection portion along the contact portion against the contact portion; and a lock protrusion that protrudes from the spring and locks the ground connection portion.

In the ground connection structure of the wire harness configured as described in (1) above, the wire harness is integrated with the mold body, and the ground terminal is held by the ground terminal holding portion provided integrally with the mold body. Compared with the case of attaching to the earth terminal and holding the ground terminal, it is possible to reduce the manufacturing cost of the wire harness by eliminating the complicated work of attaching the clamp.
In addition, when the wire harness is attached to the harness attachment portion of the vehicle body side metal member, the ground terminal is opened to the front in the attachment direction of the wire harness to the earth terminal holding portion of the molded body in which the wire harness is integrated. Is held by. Therefore, when the wire harness is attached to the harness attachment portion, the ground terminal is connected to the earth connection portion extending in the opposite direction along the attachment direction from the vehicle body side metal member. Therefore, if the ground terminal is held on the wire harness integrated with the mold body and attached to the vehicle body side metal member, the ground connection can be automatically performed. For this reason, the trouble at the time of a connection work decreases, and the work efficiency of earth connection can be improved.
In the ground connection structure of the wire harness having the configuration (2), the mold body is a foamed mold body in which foamed beads are foamed, so that the weight can be significantly reduced.
In the ground connection structure of the wire harness having the configuration (3), the ground terminal is held by the ground terminal holding portion by extending the ground wire to the rear in the mounting direction. For this reason, when the wire harness is attached to the harness attachment portion, the ground wire is not subjected to a shearing force.
In the ground connection structure of the wire harness configured as described in (4) above, the ground terminal has a structure having a substrate portion and a pair of sandwiching plate portions extending from the opposite positions of the substrate portion. Therefore, the ground terminal can be reliably electrically connected to the ground connection portion with a simple structure.
In the ground connection structure of the wire harness having the configuration (5), the ground terminal has a contact portion, a spring that presses the ground connection portion against the contact portion, and a lock protrusion that locks the ground connection portion. Therefore, the ground terminal can be reliably electrically connected to the ground connection portion with a simple structure. Further, it is possible to regulate the disconnection of the ground terminal from the ground connection portion.

  ADVANTAGE OF THE INVENTION According to this invention, the ground connection structure of the wire harness which can improve the work efficiency of earth connection can be provided, suppressing the cost increase of a wire harness.

  The present invention has been briefly described above. Further, details of the present invention will be further clarified by reading through the modes for carrying out the invention described below with reference to the accompanying drawings.

FIG. 1 is a schematic diagram illustrating a wire harness and a lean hose to which the ground connection structure according to the first embodiment is applied. 2 shows the ground connection structure according to the first embodiment. FIG. 2 (a) is a cross-sectional view before connection along the line II-II of FIG. 1, and FIG. 2 (b) is II-II of FIG. It is sectional drawing after the connection in a line. FIG. 3 is a partial perspective view of the back surface side of the foam mold body of the ground connection structure according to the first embodiment. FIG. 4 is a partial perspective view of the surface side showing a state before the ground connector is assembled to the foamed mold body of the ground connection structure according to the first embodiment. FIG. 5 is a partial perspective view of the surface side showing a state after the ground connector is assembled to the foamed mold body of the ground connection structure according to the first embodiment. FIG. 6 is a perspective view showing a ground connector and a ground wire of the ground connection structure according to the first embodiment. FIG. 7 is a perspective view showing a ground terminal of the ground connection structure according to the first embodiment. 8A and 8B show a ground connection structure according to the second embodiment. FIG. 8A is a cross-sectional view before connection, and FIG. 8B is a cross-sectional view after connection. FIG. 9 is a perspective view showing a ground connector and a ground wire of the ground connection structure according to the second embodiment. FIG. 10 is a cross-sectional perspective view showing the ground terminal of the ground connection structure according to the second embodiment. FIG. 11 is a partial perspective view of the surface side showing a state before the ground connector is assembled to the foam mold body of the ground connection structure according to the second embodiment. FIG. 12 is a partial perspective view on the surface side showing a state in the middle of assembling the ground connector to the foamed mold body of the ground connection structure according to the second embodiment. FIG. 13 is a partial perspective view on the back side showing a state after the ground connector is assembled to the foamed mold body of the ground connection structure according to the second embodiment. FIG. 14 is a partial perspective view showing a tab of the ground connection structure according to the second embodiment.

Hereinafter, examples of embodiments according to the present invention will be described with reference to the drawings.
(First embodiment)
First, the ground connection structure of the wire harness according to the first embodiment will be described.

  FIG. 1 is a schematic diagram showing a wire harness and a lean hose to which the ground connection structure according to the first embodiment is applied. FIG. 2 shows the ground connection structure according to the first embodiment. FIG. 2 is a cross-sectional view before connection at line II-II, FIG. 2B is a cross-sectional view after connection at line II-II in FIG. 1, and FIG. 3 is a diagram of the foamed mold body with the ground connection structure according to the first embodiment. FIG. 4 is a partial perspective view of the back side, FIG. 4 is a partial perspective view of the front side showing a state before the ground connector is assembled to the foamed mold body of the ground connection structure according to the first embodiment, and FIG. 5 is according to the first embodiment. FIG. 6 is a perspective view showing a ground connector and a ground wire in the ground connection structure according to the first embodiment, and FIG. 7 is a perspective view showing the ground connector and the ground wire in the ground connection structure according to the first embodiment. Is related to the first embodiment It is a perspective view showing a ground terminal over scan connecting structure.

  As shown in FIG. 1, the wire harness 11 has an electric wire connected to an instrument or the like around an instrument panel of an automobile, and is routed along the longitudinal direction of a lean hose R that is a vehicle body reinforcing member. . The lean hose R includes a lean hose body 13 made of a conductive steel pipe extending in the vehicle width direction and a plurality of brackets 14 fixed to the lean hose body 13. The wire harness 11 is integrated with a foamed mold body 16 made of foamed resin. The wire harness 11 has a plurality of branch lines 18 drawn from the foamed molded body 16, and various connectors 19 are provided on the branch lines 18. These connectors 19 are connected to instruments around the instrument panel. The foamed mold body 16 has a main body portion 21 extending along the lean hose R and a ground terminal holding portion 22 protruding from a plurality of locations on the surface side of the main body portion 21.

  As shown in FIG. 2A, FIG. 2B, and FIG. 3, the wire harness 11 includes a main line 24 and a plurality of wires 24 provided on the main line 24 (FIGS. 2A, 2B, and 3). And only one clamp 25). The trunk line 24 is embedded in the main body portion 21 of the foam mold body 16, and the clamp 25 protrudes from the back surface of the main body portion 21 of the foam mold body 16. Here, the trunk line 24 is composed of a plurality of cables 15 bundled together. The foamed mold body 16 is made of foamed polystyrene in which a plurality of foamed beads are foamed and integrated in a mold in which the cable 15 is set. The foamed molded body 16 is integrated into a state where a plurality of cables 15 constituting the wire harness 11 are bundled to form the wire harness 11.

  As shown in FIGS. 2 (a), 2 (b), and 4, the grounding terminal holding portion 22 of the foamed molded body 16 is formed with a housing recess 28 that is recessed downward from the upper surface. The housing recess 28 is aligned with the one clamp 25 at a position in the extending direction of the main body 21. On the wall portion of the housing recess 28 opposite to the main body 21, a wiring recess 29 is formed at the central position of the housing recess 28, which is narrower than the housing recess 28 and is recessed downward from the top surface and penetrates forward and backward. ing.

  As shown in FIGS. 2A, 2 </ b> B, and 3, the main body 21 of the foamed mold body 16 is formed with a bracket insertion opening 30 that communicates with the housing recess 28 and opens on the back surface. . The bracket insertion opening 30 is aligned with the clamp 25 at a position in the extending direction of the main body 21.

  As shown in FIG. 5, the ground connector 19 a at the end of the ground wire 18 a branched from the trunk line 24 is housed in the housing recess 28 on the surface side of the foamed mold body 16. At that time, the ground wire 18 a is inserted into the wiring recess 29. Here, the ground wire 18 a is a kind of branch line 18 drawn from the trunk line 24, and the ground connector 19 a is a kind of connector 19. The ground wire 18 a extends from the upper position of the housing recess 28 on the surface of the main body 21, with the housing recess 28 of the foamed mold body 16 and the position of the main body 21 extending in the same direction. Then, the ground wire 18 a extends from the upper position of the housing recess 28, is folded at the lower side, and passes through the wiring recess 29.

  As shown in FIG. 6, the ground connector 19 a includes a housing 33 and a ground terminal 34. The housing 33 is made of synthetic resin, and includes a substrate portion 36, a pair of extending plate portions 37, a side plate portion 38, a fixing protrusion 39, and a pair of front plate portions 40. The substrate part 36 has a rectangular shape. The pair of extending plate portions 37 extend in parallel to each other in the same direction from opposite edges of the substrate portion 36. The side plate portion 38 protrudes inward from the same edge portion of the substrate portion 36 and the pair of extending plate portions 37, and the fixing protrusion 39 extends from the side plate portion 38. The pair of front plate portions 40 protrude in a direction in which they are close to each other on the opposite side of the pair of extending plate portions 37 from the substrate portion 36. A slit 41 is formed between each of the pair of front plate portions 40 and the side plate portions 38.

  As shown in FIG. 7, the ground terminal 34 is formed by bending a conductive steel plate, and includes a substrate portion 44, a pair of sandwiching plate portions 45, and a wire connecting tongue piece 46. The pair of sandwiching plate portions 45 extends in the same direction from the edge portion of the substrate portion 44. Here, the pair of sandwiching plate portions 45 are inclined so that the shape from the substrate portion 44 side to the distal end side becomes closer to each other as the distance from the substrate portion 44 increases. Further, the shape of the tip portion is inclined so as to be separated from each other as the distance from the substrate portion 44 increases. The electric wire connecting tongue piece 46 is cut and raised from the center of the board portion 44 to the side opposite to the pair of sandwiching plate portions 45. A plurality of indents 47 along the extending direction of the sandwiching plate part 45 are formed for each sandwiching plate part 45 at positions close to each other between the pair of sandwiching plate parts 45.

  As shown in FIG. 6, in the ground terminal 34, the substrate portion 44 is press-fitted between the substrate portion 36 of the housing 33 and the fixing protrusion 39. In this press-fitted state, the pair of clamping plate portions 45 extend along the inside of the pair of extending plate portions 37 of the housing 33. In addition, the conductor portion of the ground wire 18a is connected to the wire connecting tongue 46 protruding from the board portion 36 of the housing 33 by welding or soldering.

  As shown in FIGS. 2A and 2B, in the lean hose R, a mounting bracket 14a that is a vehicle body side metal member is fixed to the lean hose body 13 by welding. The mounting bracket 14a includes a mounting plate portion 50 that is a harness mounting portion for mounting a wire harness, a support plate portion 51 that supports a wire harness, and a tab 52 that is a ground connection portion. The attachment plate part 50 has an upper end fixed to the back side of the lean hose body 13 and extends downward. The mounting plate portion 50 is formed with a mounting hole 53 through which the clamp 25 is fitted. The support plate portion 51 extends vertically from the attachment plate portion 50 to the lean hose body 13 side. The tab 52 further extends in the same direction from the tip of the support plate portion 51. The mounting bracket 14 a is a kind of the bracket 14.

  As shown in FIG. 2A, in the state before being attached to the lean hose R, the wire harness 11 has the ground connector 19a at the end of the ground wire 18a from the upper opening into the housing recess 28 of the ground terminal holding portion 22. Inserted. At that time, the ground wire 18 a is arranged in the wiring recess 29. At this time, the ground connector 19 a is inserted with the substrate portion 44 of the ground terminal 34 facing away from the bracket insertion opening 30. Moreover, the ground connector 19a is inserted with the pair of sandwiching plate portions 45 of the ground terminal 34 arranged vertically. As a result, the ground terminal 34 opens in the direction of the bracket insertion opening 30 of the foam mold body 16. The position of the ground terminal 34 of the ground connector 19 a disposed in the housing recess 28 in the extending direction of the main body portion 21 coincides with the clamp 25. Further, the connection position of the ground wire 18 a to the ground terminal 34 is also coincident with the clamp 25 in the extending direction of the main body portion 21.

  As shown in FIG. 2B, the wire harness 11 with the ground connector 19a held by the ground terminal holding portion 22 as described above is attached to the lean hose R of the vehicle body on the vehicle assembly line. . At that time, the wire harness 11 inserts the tab 52 and the support plate portion 51 of the mounting bracket 14a of the lean hose R into the bracket insertion opening 30 and attaches the clamp 25 on the back surface to the mounting hole of the support plate portion 51 of the mounting bracket 14a. 53. Thereby, the wire harness 11 is fixed to the mounting bracket 14a. At the time of attachment, the wire harness 11 moves along the support plate portion 51 and the tab 52 of the attachment bracket 14a. Therefore, the tab 52 extends in the opposite direction along the direction in which the wire harness 11 is attached to the support plate portion 51, and the ground terminal 34 is held by the ground terminal holding portion 22 in a posture that opens forward in the mounting direction. ing.

  Then, immediately before the clamp 25 is attached to the support plate portion 51, the tab 52 of the mounting bracket 14a is inserted into the slit 41 of the housing 33, and then the pair of clamping plate portions 45 of the ground terminal 34 are elastically deformed in the opposite direction. It will get in between these. At that time, since the pair of sandwiching plate portions 45 has a spring structure, an elastic force is generated toward the tab 52. Therefore, the edge part of the indent 47 (refer FIG. 7) of a pair of clamping board part 45 which contacts the tab 52 bites into the surface of the tab 52, scrapes an oxide film, and contacts with the new metal surface. In this way, the ground terminal 34 held by the ground terminal holding portion 22 is grounded to the tab 52 by attaching the wire harness 11 to the mounting plate portion 50. That is, the ground terminal 34 is grounded to the tab 52 by a collective operation including fixing the wire harness 11 to the mounting plate portion 50. The ground connector 19a is inserted into the housing recess 28 of the ground terminal holding portion 22 with a backlash in the vertical direction. For this reason, scooping of the tab 52 between the pair of clamping plate portions 45 of the ground terminal 34 can be performed smoothly.

  When attaching the wire harness 11 to the mounting plate portion 50, the ground terminal holding portion 22 extends the ground wire 18a from the ground terminal 34 to the rear in the mounting direction to the mounting plate portion 50 of the wire harness 11. A ground terminal 34 is held. Further, at the time of attachment, the ground terminal 34 is held by the ground terminal holding portion 22, the substrate portion 44 is orthogonal to the attachment direction, and the pair of sandwiching plate portions 45 are connected from the opposite positions of the substrate portion 44 to the wire. The tab 52 that extends forward in the direction of attachment to the attachment plate portion 50 of the harness and is inserted therebetween is sandwiched. Further, at the time of attachment, the ground terminal 34 and the tab 52 are located on the same straight line, and the center of the clamp 25 is included in a vertical plane including the straight line.

  As described above, according to the ground connection structure of the wire harness according to the first embodiment, the wire harness 11 is integrated with the foamed mold body 16 made of foamed resin, and is provided integrally with the foamed mold body 16. Since the ground terminal 34 is held by the ground terminal holding part 22, compared with the case where the clamp is attached to the wire harness and the ground terminal is held, complicated mounting work of the clamp is eliminated and the manufacturing cost of the wire harness 11 is suppressed. be able to.

  Further, since the foamed mold body 16 is obtained by foaming foamed beads, the weight can be significantly reduced as compared with a general resin mold.

  Since the foamed molded body 16 made of this foamed resin has a smaller adhering force to the cable 15 than a normal resin mold, the difference in thermal expansion coefficient between the cable 15 and the foamed molded body 16 during cooling curing after molding. Application of tension due to can be suppressed as much as possible. Thereby, the malfunction to the cable 15 and the foaming mold body 16 by the tension | tensile_strength at the time of cooling curing being provided can be eliminated.

  Moreover, since tension during cooling curing is suppressed, the foamed mold body 16 can be integrated along the longitudinal direction of the cable 15.

  In addition, since it is not necessary to consider the tension during cooling curing, it is possible to eliminate the need for complicated confirmation work of the compatibility between the cable 15 and the foamed resin, thereby facilitating the production.

  Further, when the wire harness 11 is attached to the attachment plate portion 50 of the attachment bracket 14a, the ground terminal 34 is attached to the earth terminal holding portion 22 of the foamed molded body 16 in which the wire harness 11 is integrated. It is held in a posture that opens forward in the direction. Therefore, when the wire harness 11 is attached to the attachment plate portion 50, the ground terminal 34 is connected to the tab 52 extending in the opposite direction along the attachment direction from the attachment bracket 14a. Therefore, in the vehicle body assembly line, if the ground terminal 34 is held on the wire harness 11 integrated with the foam molded body 16 and is attached to the mounting bracket 14a, the ground connection can be automatically performed. For this reason, the trouble at the time of a connection work decreases, and the work efficiency of earth connection can be improved. As a result, the working time on the vehicle body assembly line can be shortened, and the burden on the operator can be reduced.

  In addition, since the ground terminal 34 is accommodated in the foamed mold body 16, even if the insertion force necessary for inserting the tab 52 into the ground terminal 34 is increased, the mounting operation is facilitated by pushing the entire foamed mold body 16. It becomes. Therefore, even if the insertion force required for inserting the tab 52 into the ground terminal 34 is increased, the ground connection can be made without impairing workability.

  In addition, the ground terminal 34 is held by the ground terminal holding portion 22 by extending the ground wire 18a to the rear in the mounting direction. For this reason, when the wire harness 11 is attached to the attachment plate portion 50, the ground wire 18a is not subjected to a shearing direction force.

  Further, the ground terminal 34 has a structure having a substrate portion 44 and a pair of sandwiching plate portions 45 extending from the opposite positions of the substrate portion 44. Therefore, the ground terminal 34 can be reliably electrically connected to the tab 52 with a simple structure.

  An indent 47 is formed in the pair of clamping plate portions 45 that come into contact with the tab 52 with a spring force. For this reason, the edge part of the indent 47 bites into the surface of the tab 52, scrapes the oxide film, and comes into contact with the new metal surface. Therefore, the electrical contact is stabilized.

  When the insertion force required to insert the tab 52 into the ground terminal 34 is large, a low insertion force structure is added by adding a LIF (Low Insertion Force) lever to the ground connector 19a, and the hook 52 has a hook-shaped portion. If is added, the mounting work becomes easier.

(Second Embodiment)
Next, the ground connection structure of the wire harness according to the second embodiment will be described below with a focus on differences from the first embodiment.

  FIG. 8 shows a ground connection structure according to the second embodiment. FIG. 8A is a sectional view before connection, FIG. 8B is a sectional view after connection, and FIG. 9 is according to the second embodiment. 10 is a perspective view showing a ground terminal of the ground connection structure according to the second embodiment, and FIG. 11 is a foam mold of the ground connection structure according to the second embodiment. FIG. 12 is a partial perspective view of the surface side showing a state before the ground connector is assembled to the body, and FIG. 12 is a surface side portion showing a state during the assembly of the ground connector to the foamed mold body of the ground connection structure according to the second embodiment. FIG. 13 is a partial perspective view of the back side showing a state after the ground connector is assembled to the foamed mold body of the ground connection structure according to the second embodiment, and FIG. 14 is a perspective view of the ground connection structure according to the second embodiment. Show tab It is a partial perspective view.

  As shown in FIG. 8A and FIG. 8B, in the second embodiment, a ground connector 61 different from that in the first embodiment is used. A ground terminal holding part 62 different from the form is formed. Further, the mounting bracket 14 a has a tab 52 extending vertically from the lower end edge of the mounting plate portion 50 toward the lean hose body 13.

  As shown in FIG. 9, the ground connector 61 includes a housing 63 and a ground terminal 64 disposed in the housing 63. The housing 63 is made of a synthetic resin, and has a main body 66 having an insertion port 65 formed at one end in the length direction. A standing wall portion 67 projecting upward is formed at the center in the width direction of the upper surface of the main body portion 66, and a pair of flange portions 68 projecting on both sides in the width direction are formed at the upper end of the standing wall portion 67.

  As shown in FIGS. 8A and 8B, a substrate portion 70 is formed in the main body portion 66 along the length direction, and the substrate portion 70 has a lower surface on the insertion opening 65 side. A lever portion 71 is formed. The lever portion 71 has a cantilever shape extending in a direction away from the insertion port 65, and an operating piece portion 72 protruding upward is formed at an intermediate position thereof. The operating piece portion 72 passes through a passage hole 73 formed in the substrate portion 70 and protrudes upward from the substrate portion 70.

  As shown in FIG. 10, the ground terminal 64 is formed by bending a conductive steel plate, and has a tab connection portion 76 on one side in the length direction and a ground wire connection portion 77 on the other side in the length direction. Is formed. The tab connecting portion 76 includes a bottom plate portion 79, a side plate portion 80 rising from one edge portion of the bottom plate portion 79, a side plate portion 81 rising from the opposite edge portion of the bottom plate portion 79, and an upper spring of the bottom plate portion 79. And a plate portion 82.

  In the side plate portion 80, a slit 84 is formed along the length direction of the ground terminal 64 that opens to the side opposite to the ground wire connection portion 77. A pair of chamfers 85 are formed above and below the opening end of the slit 84. The side plate portion 81 aligns the vertical position and the front-back direction position of the upper edge portion with the lower edge portion of the slit 84. The lower edge portion of the slit 84 of the side plate portion 80 becomes a contact portion 86 that contacts the tab 52, and the upper edge portion of the side plate portion 81 also becomes the contact portion 87 that contacts the tab 52. The tip of the contact portion 87 is an edge 88 without chamfering.

  The spring plate portion 82 has a front end portion connected to the front end portion of the side plate portion 80 and extends rearward in a cantilever state. The spring plate portion 82 is stepped so that the intermediate plate portion 91 is close to the bottom plate portion 79, and the end plate portion 92 extends downward from the intermediate plate portion 91. A lock protrusion 93 protruding downward is formed at an intermediate position of the spring plate portion 82.

  As shown in FIGS. 8A and 8B, the conductor portion of the ground wire 18 a is crimped to the ground wire connecting portion 77. The ground wire 18a crimped to the ground wire connecting portion 77 extends from the ground terminal 64 along its length direction. At this time, the ground wire 18a is located at the center between the side plate portions 80 and 81, that is, at the center between the contact portions 86 and 87. Thus, the ground terminal 64 in a state where the ground wire 18 a is connected to the ground wire connecting portion 77 is fitted into the housing 63. In this fitted state, the slit 84 of the ground terminal 64 is aligned with the insertion port 65 of the housing 63. Further, in this fitted state, the operating piece portion 72 of the housing 63 faces the end plate portion 92 of the ground terminal 64 vertically.

  As shown in FIGS. 11 and 12, the foamed mold body 16 is formed with a notched ground terminal holding portion 62 at the lower portion of the main body portion 21. The ground connector 61 is fitted into the ground terminal holding portion 62 from the front surface side of the main body portion 21. In other words, the ground terminal holding portion 62 fits the body portion fitting portion 97 for fitting the body portion 66 of the housing 63, the standing wall portion fitting portion 98 for fitting the standing wall portion 67, and the pair of flange portions 68. And a pair of flange portion fitting portions 99.

  As shown in FIG. 13, the bracket insertion opening 30 is formed at the position of the body portion fitting portion 97 of the ground terminal holding portion 62. The bracket insertion opening 30 is aligned with the insertion port 65 of the ground connector 61 fitted to the ground terminal holding portion 62.

  As shown in FIG. 14, a lock hole 100 is formed in the tab 52 of the mounting bracket 14a so as to penetrate in the vertical direction.

  As shown in FIG. 8A, in the state before being attached to the lean hose R, the wire harness 11 is press-fitted into the ground terminal holding part 62 from the front of the main body part 21 with the ground connector 61 of the ground wire 18a. Is done. At this time, the ground connector 61 is press-fitted with the slit 84 and the insertion port 65 at the head. As a result, the ground terminal 64 in the ground connector 61 opens in the direction of the back surface of the foamed molded body 16, and the slit 84 is made to coincide with the bracket insertion opening 30. In addition to fixing the ground connector 61 to the ground terminal holding portion 62 by press fitting, the ground connector 61 may be fixed by lance locking.

  As shown in FIG. 8B, the wire harness 11 in a state where the ground connector 61 is held by the ground terminal holding portion 62 as described above is attached to the lean hose R of the vehicle body in the vehicle assembly line. Become. At that time, the wire harness 11 inserts the tab 52 of the mounting bracket 14a of the lean hose R into the bracket insertion opening 30 and the insertion port 65, and attaches the clamp 25 on the back surface to the mounting hole 53 of the support plate portion 51 of the mounting bracket 14a. To fit. Thereby, the wire harness 11 is fixed to the mounting bracket 14a.

  Immediately before the clamp 25 is attached to the support plate portion 51, the tab 52 of the attachment bracket 14a is fitted between them while elastically deforming the spring plate portion 82 in a direction away from the contact portions 86 and 87. At this time, since the spring plate portion 82 has a spring structure, an elastic force is generated toward the tab 52. Therefore, the edge 88 of the contact part 87 which contacts the tab 52 bites into the surface of the tab 52, scrapes an oxide film, and contacts the new metal surface. In this way, the ground terminal 64 held by the ground terminal holding portion 62 is grounded to the tab 52 by attaching the wire harness 11 to the mounting plate portion 50. That is, the ground terminal 64 is grounded to the tab 52 by a collective operation of fixing the wire harness 11 to the mounting plate portion 50. When the tab 52 reaches a predetermined position in the slit 84, the lock projection 93 is engaged with the lock hole 100, and the ground connector 61 including the ground terminal 64 is fixed to the tab 52.

  At the time of attaching the wire harness 11 to the mounting plate portion 50, the ground terminal holding portion 62 extends the ground wire 18a from the ground terminal 64 to the rear in the mounting direction to the mounting plate portion 50 of the wire harness 11. A ground terminal 64 is held. In addition, the ground terminal 34 is held by the ground terminal holding portion 62, and the contact portions 86 and 87 are along the mounting direction of the wire harness 11 to the mounting plate portion 50. The spring plate 82 presses the tab 52 along the contact portions 86 and 87 against the contact portions 86 and 87. That is, the spring plate portion 82 and the contact portions 86 and 87 sandwich the tab 52. Further, at the time of attachment, the ground terminal 64 and the tab 52 are located on the same straight line, and the center of the clamp 25 is included in a vertical plane including the straight line.

  As described above, also in the case of the ground connection structure of the wire harness according to the second embodiment, the wire harness 11 is integrated with the foamed mold body 16 made of foamed resin, and is provided integrally with the foamed mold body 16. Since the ground terminal 64 is held by the ground terminal holding part 62, the complicated work of attaching the clamp is eliminated and the manufacturing cost of the wire harness 11 is reduced as compared with the case where the clamp is attached to the wire harness and the ground terminal is held. be able to.

  Further, since the foamed mold body 16 is obtained by foaming foamed beads, the weight can be significantly reduced as compared with a general resin mold.

  Further, when the wire harness 11 is attached to the attachment plate portion 50 of the attachment bracket 14a, the ground terminal 64 is attached to the earth terminal holding portion 62 of the foam molded body 16 in which the wire harness 11 is integrated. It is held in a posture that opens forward in the direction. Therefore, when the wire harness 11 is attached to the attachment plate portion 50, the ground terminal 64 is connected to the tab 52 extending in the opposite direction along the attachment direction from the attachment bracket 14a. Therefore, in the vehicle body assembly line, if the ground terminal 64 is held on the wire harness 11 integrated by the foamed mold body 16 and attached to the mounting bracket 14a, the ground connection can be automatically performed. For this reason, the trouble at the time of a connection work decreases, and the work efficiency of earth connection can be improved. As a result, the working time on the vehicle body assembly line can be shortened, and the burden on the operator can be reduced.

  The ground terminal 64 has a structure having contact portions 86, 87, a spring plate portion 82 that presses the tab 52 against the contact portions 86, 87, and a lock protrusion 93 that locks the tab 52. Therefore, the ground terminal 64 can be reliably electrically connected to the tab 52 with a simple structure, and the removal of the ground terminal 64 from the tab 52 can be restricted. Here, when the lever part 71 is pushed upward from the locked state, the operating piece part 72 comes into contact with the end plate part 92 and pushes it up. As a result, the spring plate portion 82 is deformed and the lock protrusion 93 is removed from the lock hole 100, and the ground connector 61 can be detached from the ground terminal holding portion 62.

  In addition, this invention is not limited to embodiment mentioned above, A deformation | transformation, improvement, etc. are possible suitably including a manufacturing method. In addition, the material, shape, dimensions, number, arrangement location, and the like of each component in the above-described embodiment are arbitrary and are not limited as long as the present invention can be achieved.

11 Wire harness 14a Mounting bracket (vehicle body side metal member)
16 Foamed mold body 18a Ground wire 22, 62 Ground terminal holding part 34, 64 Ground terminal 44 Substrate part 45 Clamping plate part 50 Mounting plate part (harness mounting part)
52 Tab (ground connection)
82 Spring plate (spring)
86,87 Contact part 93 Lock protrusion

Claims (5)

A ground connection structure for grounding a ground terminal provided on a terminal of a ground wire drawn from a wire harness formed by bundling a plurality of cables and connecting them to a vehicle body side metal member,
The vehicle body side metal member has a harness attachment portion for attaching the wire harness, and a ground connection portion extending in the opposite direction along the attachment direction of the wire harness to the harness attachment portion,
The wire harness is integrated with the mold body, and has an earth terminal holding part integrally holding the earth terminal in a posture that opens forward in the attachment direction.
A ground connection structure for a wire harness, wherein the ground terminal held by the ground terminal holding portion is connected to the ground connection portion by attaching the wire harness to the harness attachment portion.   The ground connection structure for a wire harness according to claim 1, wherein the mold body is a foamed mold body obtained by foaming foam beads.   3. The wire harness ground according to claim 1, wherein the ground terminal holding portion holds the ground terminal by extending the ground wire from the ground terminal to the rear in the attachment direction. 4. Connection structure.   The ground terminal is held by the ground terminal holding portion, and the substrate portion orthogonal to the mounting direction is extended from the reciprocal position of the substrate portion to the front in the mounting direction and inserted between them. It has a pair of clamping board part which clamps a connection part, The ground connection structure of the wire harness as described in any one of Claim 1 to 3 characterized by the above-mentioned.   The ground terminal is held by the ground terminal holding portion, the contact portion along the mounting direction, a spring pressing the ground connection portion along the contact portion against the contact portion, and protruding from the spring to the ground The ground connection structure for a wire harness according to any one of claims 1 to 3, further comprising: a lock protrusion that locks the connection portion.

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