WO2023136210A1 - Wiring fixing member and wiring module - Google Patents

Abstract

The purpose of the present invention is to enable a flat wiring member to be fixed more easily along the surface of a rod-shaped member. This wiring fixing member comprises a pressing portion having an inner surface curved in conformity to the surface of a rod-shaped member, and an insertion/fixation portion that protrudes from the pressing portion and is fixed by being inserted into a fixation hole formed on the rod-shaped member, and forms a space, in which the flat wiring member can be placed, between the inner surface and the surface of the rod-shaped member in a state where the insertion/fixation portion has been fixed by being inserted into the fixation hole.

Description

Wiring fixing member and wiring module

The present disclosure relates to wiring fixing members and wiring modules.

Patent Document 1 discloses a structure for fixing a flat wiring member to a reinforcement with a binding band.

Patent Document 2 uses a wire harness including electric wires and a support member including a fitting portion formed in a partial cylindrical shape that is partially open in the circumferential direction so that it can be fitted to the outer peripheral portion of the reinforcement. A structure for fixing a wiring member to a reinforcement is disclosed.

WO2020/178998 JP 2019-004679 A

It is desired that the flat wiring member can be more easily fixed in a state along the surface of the rod-shaped member.

Therefore, an object of the present disclosure is to enable the flat wiring member to be more easily fixed in a state along the surface of the rod-shaped member.

The wiring fixing member of the present disclosure includes a pressing portion having an inner surface curved according to the surface of the rod-shaped member, an insertion fixing portion that protrudes from the pressing portion and is inserted and fixed into a fixing hole formed in the rod-shaped member, The wiring fixing member forms a space in which a flat wiring member can be arranged between the inner surface and the surface of the rod-shaped member in a state where the insertion fixing portion is inserted and fixed in the fixing hole.

According to the present disclosure, it is an object of the present disclosure to more easily fix the flat wiring member along the surface of the rod-shaped member.

FIG. 1 is a plan view showing a state in which a wiring module according to Embodiment 1 is fixed to a rod-shaped member. FIG. 2 is a cross-sectional view taken along line II--II of FIG. FIG. 3 is a cross-sectional view taken along line III--III of FIG. FIG. 4 is an explanatory view showing a state in the middle of fixing the wiring module to the rod-like member. FIG. 5 is a diagram showing an example of a rod-shaped member. FIG. 6 is a diagram showing a state in which a flat wiring member is fixed to a short reinforcement. FIG. 7 is a diagram showing a state in which a flat wiring member is fixed to a long reinforcement. FIG. 8 is a plan view showing a modification of the flat wiring member. FIG. 9 is a diagram showing a state in which the fixing position of the reinforcement in the circumferential direction is adjusted. FIG. 10 is a plan view showing a state in which the wiring module is fixed to the bar member. 11 is a cross-sectional view taken along the line XI--XI of FIG. 10. FIG. FIG. 12 is an explanatory view showing a state in the middle of fixing the wiring module to the rod-shaped member. FIG. 13 is a cross-sectional view showing a state in the middle of fixing the wiring module to the rod-shaped member.

[Description of Embodiments of the Present Disclosure]
First, the embodiments of the present disclosure are listed and described.

The wiring fixing member of the present disclosure is as follows.

(1) a pressing portion having an inner surface curved according to the surface of a rod-shaped member; an insertion fixing portion protruding from the pressing portion and inserted and fixed into a fixing hole formed in the rod-shaped member; The wiring fixing member forms a space in which a flat wiring member can be arranged between the inner surface and the surface of the rod-shaped member while being inserted and fixed in the fixing hole.

According to the present disclosure, when the insertion fixing portion is inserted and fixed into the fixing hole, the flat wiring member can be fixed between the inner surface of the pressing portion and the surface of the rod-shaped member. Therefore, the flat wiring member can be easily fixed along the surface of the rod-shaped member.

(2) In the wiring fixing member of (1), the inner surface may have a shape having at least one of an arcuate curved portion and an angular curved portion. Thereby, when the surface of the rod-shaped member has at least one of an arc-shaped curved portion and an angularly curved portion, the flat wiring member can be made to follow the surface of the rod-shaped member.

(3) In the wiring fixing member of (1) or (2), the insertion fixing portion may protrude from the middle portion in the extending direction of the pressing portion. As a result, both ends of the pressing portion protrude from both sides of the head portion of the insertion fixing portion to press the flat wiring member. As a result, the flat wiring member can be stably pressed against the surface of the bar member.

(4) In the wiring fixing member according to any one of (1) to (3), the insertion fixing portion gradually protrudes outward from the shaft portion toward the base end side from the distal end side of the shaft portion. , and an elastically deformable retaining elastic projection.

In this case, when the insertion fixing portion is inserted into the fixing hole, the retaining elastic protrusion elastically deforms so as to approach the shaft portion side. When the retainer elastic protrusion passes over the fixing hole, the retainer elastic protrusion returns to its original shape and engages with the periphery of the fixation hole, thereby fixing the insertion fixing portion to the rod-shaped member. Therefore, the wiring fixing member can be easily fixed to the rod-shaped member.

(5) In the wiring fixing member of (4), the retaining elastic protrusion has a pair of retaining elastic pieces protruding from the shaft, and when viewed along the extending direction of the shaft, , the extending direction of the pressing portion and the extending direction of the pair of retaining elastic pieces may intersect.

In this case, the insertion fixing portion can be inserted and fixed into the long fixing hole along the extending direction of the rod-shaped member with the extending direction of the pair of retaining elastic pieces along the extending direction of the rod-shaped member. In this inserted and fixed state, when viewed along the extending direction of the shaft portion, the pressing portion that intersects the extending direction of the pair of retainer elastic pieces is arranged to intersect the extending direction of the rod-shaped member. be done. Therefore, the pressing portion can easily press the flat wiring member along the curved surface of the bar member.

(6) In the wiring fixing member according to any one of (1) to (3), the insertion fixing portion has a shaft portion and a retaining protrusion projecting outward from the shaft portion, The base end portion of the shaft portion may be rotatable within the fixing hole in a state in which the insertion fixing portion is inserted into the fixing hole until the retaining protrusion exceeds the fixing hole.

In this case, in a state in which the insertion fixing portion is inserted into the fixing hole until the retaining projection exceeds the fixing hole, the insertion fixing portion is rotated, so that the retaining projection extends into the fixing hole. It can be locked to prevent it from coming off.

(7) In the wiring fixing member of (6), the retaining projection has a pair of retaining pieces protruding from the shaft, and when viewed along the extending direction of the shaft, the The extending direction of the pressing portion and the extending direction of the pair of retaining pieces may be along the same direction.

In this case, the insertion fixing portion can be inserted and fixed into the long fixing hole along the extending direction of the rod-shaped member with the extending direction of the pair of retaining pieces along the extending direction of the rod-shaped member. After that, by rotating the insertion fixing part, the insertion fixing part can be retained in the fixing hole. In this rotation-retaining fixed state, the pressing portions parallel to the extending direction of the pair of retaining pieces when viewed along the extending direction of the shaft portion are arranged to intersect the extending direction of the rod-shaped member. be done. Therefore, the pressing portion can easily press the flat wiring member along the curved surface of the bar member.

The wiring module of the present disclosure is as follows.

(8) A wiring module comprising the wiring fixing member according to any one of (1) to (7) and a flat wiring member located on the inner side surface of the pressing portion. Thereby, the flat wiring member can be arranged along the surface of the rod-shaped member by the inner surface of the pressing portion.

(9) In the wiring module of (8), the flat wiring member includes a plurality of linear transmission members and a base member that keeps the plurality of linear transmission members flat, and the base member Further, at least one of a long hole along the extending direction of the rod-shaped member and a plurality of holes formed so as to be aligned along the extending direction of the rod-shaped member may be formed.

Accordingly, when the insertion fixing part is inserted into the long hole or hole and inserted and fixed to the rod-shaped member, the pressing part can press the flat wiring member along the surface of the rod-shaped member and fix it. By adjusting the position of the insertion fixing portion in the elongated hole or selectively adjusting the plurality of holes into which the insertion fixing portion is inserted, it is possible to easily cope with different fixing holes in the rod-shaped member.

[Details of the embodiment of the present disclosure]
Specific examples of the wiring fixing member and the wiring module of the present disclosure will be described below with reference to the drawings. The present disclosure is not limited to these examples, but is indicated by the scope of the claims, and is intended to include all modifications within the meaning and scope of equivalents of the scope of the claims.

[Embodiment 1]
A wiring fixing member and a wiring module according to the first embodiment will be described below. FIG. 1 is a plan view showing a state in which the wiring module 20 is fixed to the bar member 10. FIG. FIG. 2 is a cross-sectional view taken along line II--II of FIG. FIG. 3 is a cross-sectional view taken along line III--III of FIG. FIG. 4 is an explanatory diagram showing a state in which the wiring module 20 is being fixed to the rod-like member 10. As shown in FIG. In FIG. 4, the flat wiring member 30 is indicated by a chain double-dashed line.

The wiring module 20 includes a wiring fixing member 40 and a flat wiring member 30. The flat wiring member 30 is, for example, a flat wiring member including wiring that connects a plurality of electrical components in the vehicle. The wiring fixing member 40 is a member that fixes the flat wiring member 30 to the rod-shaped member 10 while the flat wiring member 30 is along the surface of the rod-shaped member 10 .

Here, the rod-shaped member 10 is, for example, a rod-shaped member that is part of a vehicle. The rod-shaped member 10 may be any member that is long in one direction. The rod-shaped member 10 may be a cylindrical member, an elliptical tubular member, or a rectangular tubular member. It may be a U-shaped member in cross section (cross section perpendicular to the longitudinal direction). In this embodiment, an example in which the rod-shaped member 10 is a cylindrical reinforcement is described. The reinforcement is, for example, an instrument panel reinforcement provided on the side of the instrument panel opposite to the vehicle interior, and extends along the vehicle width direction.

The flat wiring member 30 includes a plurality of linear transmission members 32 and a base member 34.

The linear transmission member 32 may be any linear member that transmits electricity or light. The linear transmission member is, for example, an electric wire that transmits electricity or an optical fiber that transmits light. In the present embodiment, the linear transmission member 32 is a coated electric wire having a core wire 32a and a coating 32b covering the core wire 32a. The linear transmission member 32 may be a bare conductor wire, a nichrome wire, or the like. A plurality of linear transmission members 32 may be grouped together to form a twisted wire or cable. The linear transmission member 32 may be an optical fiber.

The base member 34 is a member that keeps the plurality of linear transmission members 32 flat. In this embodiment, the base member 34 is a sheet made of resin or the like. The base member 34 may be a non-woven fabric or a solid sheet with a filling inside.

A plurality of linear transmission members 32 are fixed to one main surface of the base member 34 . Such a fixation mode may be contact site fixation, non-contact site fixation, or a combination of both. Here, the fixed contact portion means that the portion where the linear transmission member 32 and the base member 34 contact each other is attached and fixed. Non-contact site fixation is a fixation mode that is not contact site fixation. For example, a thread, another sheet material, an adhesive tape, or the like presses the linear transmission member 32 toward the base member 34, or a thread, another sheet material, an adhesive tape, or the like presses the linear transmission member 32 and the base member. 34, the linear transmission member 32 and the base member 34 are sandwiched, and the linear transmission member 32 and the base member 34 are maintained in a fixed state. In the following description, it is assumed that the linear transmission member 32 and the base member 34 are in a fixed state of contact. Each discussion relating to contact site fixation is also applicable to non-contact site fixation, unless the configuration is not applicable.

As a form of such contact site fixation, it may be indirect fixation at the contact site, direct fixation at the contact site, or both may be used in different areas. Here, the indirect fixation of the contact portion means that the linear transmission member 32 and the base member 34 are indirectly fixed by intervening an intervening member such as an adhesive, a pressure-sensitive adhesive, or a double-sided adhesive tape provided between them. There is. Further, the direct fixation of the contact portion means that the linear transmission member 32 and the base member 34 are directly attached and fixed without interposing an adhesive or the like separately provided. In direct fixation of the contact portion, for example, it is conceivable that resin contained in at least one of the linear transmission member 32 and the base member 34 is melted to stick and fix. In the following description, it is assumed that the linear transmission member 32 and the base member 34 are directly fixed at their contact portions. Each discussion relating to direct contact site fixation is also applicable to indirect contact site fixation, unless the configuration is not applicable.

In forming such a state in which the contact portion is directly fixed, the resin may be melted, for example, by heat or melted by a solvent. That is, the state of direct fixation of the contact portion may be the state of direct fixation of the contact portion by heat or the state of direct fixation of the contact portion by solvent. Preferably, the contact portion is directly fixed by heat.

At this time, the means for forming a state in which the contact parts are directly fixed is not particularly limited, and various means including known means such as welding, fusing, and welding can be used. For example, when the contact portion is directly fixed by heat by welding, various welding means such as ultrasonic welding, heat-pressure welding, hot-air welding, and high-frequency welding can be employed. Further, when the contact portion directly fixed state is formed by these means, the linear transmission member 32 and the base member 34 are brought into the contact portion directly fixed state by the means. Specifically, for example, when the contact portion is directly fixed by ultrasonic welding, the linear transmission member 32 and the base member 34 are brought into the contact portion directly fixed state by ultrasonic welding. The portion (fixed portion between the linear transmission member 32 and the base member 34) in which the contact portion is directly fixed by heat is called the welded portion, and the portion fixed by ultrasonic welding is the ultrasonic welded portion. A portion fixed by pressure welding may be referred to as a heat-pressure welded portion or the like.

In the case of directly fixing the contact portion, only the resin contained in the coating of the linear transmission member 32 may be melted, or only the resin contained in the base member 34 may be melted. In these cases, the melted resin may become stuck to the outer surface of the other, forming a relatively sharp interface. In the case of direct fixation of the contact portion, both the resin contained in the coating of the linear transmission member 32 and the resin contained in the base member 34 may be melted. In this case, both resins may mix and a clear interface may not be formed. In particular, when the coating of the linear transmission member 32 and the base member 34 contain resins that are easily compatible, such as the same resin material, both resins may mix and a clear interface may not be formed.

In addition, the flat wiring member may have a configuration in which a plurality of linear transmission members formed of bare conductors or the like are insulated from each other and covered with resin (for example, FFC (flexible flat cable)). A configuration in which a plurality of linear transmission members made of copper foil or the like are sandwiched between a pair of films (for example, FPC (flexible printed circuit)) may be used.

A long hole 34 h is formed in the base member 34 along the extending direction of the rod-shaped member 10 . In this embodiment, a plurality of linear transmission members 32 are fixed to the base member 34 in parallel. Long holes 34h are formed in both outer sides and intermediate portions in the direction in which the plurality of linear transmission members 32 are arranged (the width direction of the flat wiring member 30). The long hole 34h may be a rectangular hole or a long hole having arcuate ends in the longitudinal direction. The long hole 34 h is formed at a position avoiding the plurality of linear transmission members 32 .

At least part of the plurality of linear transmission members 32 may be bent in the middle. Also, a part of the plurality of linear transmission members 32 may intersect with another part.

Since the flat wiring member 30 is a member that can be bent and deformed, if it can be fixed to the rod-shaped member 10 along the surface of the rod-shaped member 10, the wiring space around the rod-shaped member 10 can be reduced. The wiring fixing member 40 is a fixing member suitable for fixing the flat wiring member 30 to the rod-like member 10 .

<Regarding wiring fixing members>
The wiring fixing member 40 is a member integrally molded with the same resin with a mold, and includes a pressing portion 42 and an insertion fixing portion 50 .

The pressing portion 42 is a member having a curved inner side surface 43 corresponding to the surface of the rod-shaped member 10 . The inner surface 43 is a surface facing inward when the wiring fixing member 40 is viewed as a whole. In this embodiment, the insertion fixing portion 50 protrudes from the pressing portion 42 , and the surface of the pressing portion 42 on which the insertion fixing portion 50 protrudes is the inner side surface 43 .

The inner side surface 43 preferably has a shape that has at least one of an arc-shaped curved portion and an angular curved portion depending on the surface of the rod-shaped member 10 . In this embodiment, it is assumed that the rod-shaped member 10 is cylindrical, so the surface of the rod-shaped member 10 has a circumferential surface shape. The inner surface 43 is an arcuate curved surface corresponding to a portion of the circumferential surface in the circumferential direction. The radius of curvature of the inner side surface 43 may be the same as the radius of curvature of the circumferential surface shape of the rod-shaped member 10, or the circumferential surface of the rod-shaped member 10 may be within a range where the flat wiring member 30 can be pressed along the surface. It may differ from the radius of curvature of the shape. For example, the radius of curvature of the inner surface 43 may be smaller than the radius of curvature of the circumferential surface shape of the bar member 10, and the pressing portion 42 may be elastically deformed to press the flat wiring member 30 against the surface.

The outer surface may have a shape that bends according to the surface of the rod-shaped member 10 , for example, a shape that bends in the same manner as the inner surface 143 . The outer surface may not have a shape that bends according to the surface of the rod-shaped member 10 . In this embodiment, the entire pressing portion 42 is formed in a shape that bends according to the surface of the rod-shaped member 10, that is, in an arc shape. Therefore, the pressing portion 42 itself is also arranged along the surface of the rod-shaped member 10, and the amount of protrusion of the pressing portion 42 from the rod-shaped member 10 can be reduced.

It is also conceivable that the surface shape of the rod-shaped member 10 has corners, for example, that the rod-shaped member 10 has a rectangular tubular shape. In this case, the inner side surface 143 corresponding to the inner side surface 43 may be configured to have corners 143a (see the pressing portion 142 indicated by the two-dot chain line in FIG. 2). Depending on the surface shape of the rod-shaped member, the inner surface of the pressing portion may have both arcuate curved portions and angled portions.

The insertion fixing portion 50 is a portion that protrudes from the pressing portion 42 and is inserted and fixed into the fixing hole 11 formed in the rod-shaped member 10 . The fixing hole 11 is a hole into which the insertion fixing part 50 can be inserted and with which the insertion fixing part 50 can be hooked. In this embodiment, the fixing hole 11 is a hole elongated in the longitudinal direction of the rod-shaped member 10 . If the fixing hole 11 is long in the longitudinal direction of the rod-shaped member 10, the strength of the rod-shaped member 10 can be easily maintained.

A space S in which the flat wiring member 30 can be arranged can be formed between the inner surface 143 and the surface of the rod-like member 10 in a state where the insertion fixing portion 50 is inserted and fixed in the fixing hole 11 . The space S is an arc-shaped thin space along the surface of the rod-shaped member 10 .

More specifically, the insertion fixing portion 50 protrudes from the inner side surface 143 at the intermediate portion in the extending direction of the pressing portion 42 . In this embodiment, the insertion fixing portion 50 protrudes from the center of the pressing portion 42 in the extending direction. The insertion fixing portion 50 may protrude from a position that is biased toward one of the ends with respect to the center in the extending direction of the pressing portion 42 .

The insertion fixing portion 50 has a shaft portion 52 and a retainer elastic protrusion 54 . The shaft portion 52 is a long portion that protrudes from the pressing portion 42 . The shaft portion 52 may be cylindrical or prismatic. The extending direction of the shaft portion 52 may be the direction toward the center of curvature of the inner side surface 143 .

The retaining elastic protrusion 54 is a portion that can be elastically deformed, and gradually protrudes outward from the shaft portion 52 from the distal end side to the proximal end side of the shaft portion 52 . Here, the outer side of the shaft portion 52 is a direction away from the shaft portion 52 in a direction orthogonal to the extending direction of the shaft portion 52 .

In this embodiment, the retaining elastic protrusion 54 has a pair of retaining elastic pieces 54a that protrude in opposite directions with the shaft portion 52 as a base point. Each of the pair of retaining elastic pieces 54a is formed in an arcuate shape that protrudes outward. The pair of retainer elastic pieces 54a are continuously connected at the distal end of the shaft portion 52, and are formed in an outwardly convex arc shape as a whole. The pair of retaining elastic pieces 54a may be formed so as to gradually become thinner toward the distal end side so that the proximal end side is difficult to deform and the distal end side is easy to deform.

When viewed along the extending direction of the shaft portion 52, it is preferable that the extending direction of the pressing portion 42 and the extending direction of the pair of retaining elastic pieces 54a intersect. That is, on the projection plane viewed along the extending direction A (see FIG. 4) of the shaft portion 52, the extending direction of the pressing portion 42 and the extending direction of the pair of retaining elastic pieces 54a intersect. They are preferably orthogonal. As a result, when the fixing hole 11 long in the extending direction is formed in the rod-like member 10, the pressing portion 42 can be moved while the extending direction of the pair of retainer elastic pieces 54a is aligned with the extending direction of the fixing hole 11. It is easy to arrange along the direction orthogonal to the rod-shaped member 10 (the circumferential direction of the surface of the rod-shaped member 10).

In the direction orthogonal to the extending direction of the shaft portion 52, the width of the retaining elastic protrusion 54 is equal to or smaller than the width of the fixing hole 11 in the lateral direction. In the direction orthogonal to the extending direction of the shaft portion 52, the length of the retaining elastic protrusion 54 is smaller than the length of the fixing hole 11 in the longitudinal direction.

Therefore, by elastically deforming the distal end portions of the pair of retaining elastic pieces 54 a to contract the retaining elastic protrusions 54 , the retaining elastic protrusions 54 can be inserted into the fixing holes 11 . When the retaining elastic projections 54 pass through the fixing hole 11, the pair of retaining elastic pieces 54a return to their original shapes, and the tips of the pair of retaining elastic pieces 54a move from the inner peripheral surface side of the rod-shaped member 10 into the fixing hole. 11 abuts on the periphery. As a result, the insertion fixing portion 50 is fixed in the fixing hole 11 so as not to come off. The shaft portion 52 can form a thin space S in which the flat wiring member 30 can be arranged between the surface of the rod-shaped member 10 and the inner side surface 43 in a state where the insertion fixing portion 50 is fixed in the fixing hole 11 so as not to come off. length is set.

The flat wiring member 30 and the wiring fixing member 40 may be provided separately or in a combined form. In the former case, the flat wiring member 30 and the wiring fixing member 40 may be combined when fixed to the rod-shaped member 10 . In the latter case, the insertion fixing portion 50 is inserted into the elongated hole 34h of the base member 34, that is, the shaft portion 52 passes through the elongated hole 34h, and the flat wiring member 30 is connected to the pressing portion 42 and the retaining elastic protrusion 54. and may be arranged between.

<Example of fixing work and fixing structure>
An example of work for fixing the wiring module 20 to the rod-shaped member 10 will be described.

For example, the flat wiring member 30 is arranged along the surface of the rod-shaped member 10 (see FIG. 4). At this time, the fixing hole 11 is made to overlap a part of the long hole 34h. Then, the insertion fixing portion 50 is inserted into the long hole 34h and the fixing hole 11 while the extending direction of the retainer elastic protrusion 54 is aligned with the extending direction of the long hole 34h and the fixing hole 11 . Then, of the ends of the pair of retainer elastic pieces 54 a , the surfaces on the front side in the insertion direction come into contact with both longitudinal direction edges of the fixing hole 11 . As a result, the pair of retaining elastic pieces 54a are elastically deformed so as to approach the shaft portion 52 side.

Note that, as described above, the insertion fixing portion 50 may be inserted into the long hole 34h in advance.

When the pair of retaining elastic pieces 54a pass through the fixing hole 11 and are arranged in the rod-shaped member 10, the pair of retaining elastic pieces 54a elastically return to their original shape. Then, the tips of the pair of retaining elastic pieces 54a come into contact with the inner peripheral surface of the rod-shaped member 10 around the fixing hole 11 (positions outside the fixing hole 11 along the longitudinal direction of the rod-shaped member 10).

In this state, a space S in which the flat wiring member 30 can be arranged is formed between the outer peripheral surface of the rod-shaped member 10 and the inner surface 43 of the pressing portion 42 . The inner surface 43 of the pressing portion 42 presses the flat wiring member 30 toward the outer peripheral surface of the rod-shaped member 10 . As a result, the flat wiring member 30 is fixed to the rod-shaped member 10 while being positioned on the inner surface 43 side of the pressing portion 42 and along the outer peripheral surface of the rod-shaped member 10 .

In this state, the pair of retaining elastic pieces 54a is elastically deformed, and the pressing portion 42 presses the flat wiring member 30 against the outer peripheral surface of the bar member 10 due to the elastic restoring force of the pair of retaining elastic pieces 54a. may

It should be noted that when the retainer elastic projection 54 is inserted and fixed into the fixing hole 11, the tip portions of the pair of retainer elastic pieces 54a are in contact with the outer sides of the fixing hole 11 at both ends in the longitudinal direction. This contact portion is the closest position to the pressing portion 42 . Therefore, the rotation of the wire fixing member 40 is restricted by pressing the tip portions of the pair of retaining elastic pieces 54a against the contact portions. Further, the inner surface 43 of the pressing portion 42 is arranged along the arc-shaped curved surface of the outer peripheral surface of the rod-shaped member 10, so that the rotation of the wiring fixing member 40 is restricted.

<Effects, etc.>
According to the wiring fixing member 40 and the wiring module 20 configured as described above, when the insertion fixing portion 50 is inserted and fixed into the fixing hole 11 , the flat wiring is secured between the inner surface 43 of the pressing portion 42 and the surface of the rod-shaped member 10 . Member 30 can be fixed. Therefore, the flat wiring member 30 can be easily fixed along the surface of the rod-shaped member 10 .

Further, if the inner surface 43 of the pressing portion 42 has at least one of an arcuate portion and an angled portion, the surface of the rod-shaped member 10 may have an arcuate portion and an angled portion. , the flat wiring member 30 can be laid along the surface of the rod-shaped member 10 .

Also, the insertion fixing portion 50 protrudes from the middle portion in the extending direction of the pressing portion 42 . Therefore, both ends of the pressing portion 42 protrude from both sides of the head portion of the shaft portion 52 of the insertion fixing portion 50 so that the flat wiring member 30 can be pressed against the surface of the rod-shaped member 10 . Thereby, the flat wiring member 30 can be stably pressed against the surface of the rod-shaped member 10 .

In addition, the insertion fixing portion 50 has an elastically deformable retaining elastic protrusion 54 that gradually protrudes outward from the distal end side of the shaft portion 52 toward the proximal end side. Therefore, when the insertion fixing portion 50 is inserted into the fixing hole 11 , the retaining elastic protrusion 54 can be elastically deformed so as to approach the shaft portion 52 side. When the retaining elastic protrusion 54 passes over the fixing hole 11 , the retaining elastic protrusion 54 returns to its original shape and engages with the periphery of the fixing hole 11 , thereby fixing the insertion fixing part 50 to the rod-shaped member 10 . Therefore, the wiring fixing member 40 can be easily fixed to the rod-shaped member 10 .

Further, when viewed along the extending direction of the shaft portion 52, the extending direction of the pressing portion 42 and the extending direction of the pair of retaining elastic pieces 54a intersect. For this reason, the insertion fixing portion 50 is inserted into the long fixing hole 11 along the extending direction of the rod-shaped member 10 with the extending direction of the pair of retaining elastic pieces 54a aligned with the extending direction of the rod-shaped member 10. Can be inserted and fixed. In this inserted and fixed state, when viewed along the extending direction of the shaft portion 52, the pressing portion 42 intersecting with the extending direction of the pair of retaining elastic pieces 54a is positioned with respect to the extending direction of the rod-shaped member 10. placed crosswise. Therefore, the pressing portion 42 can easily press the flat wiring member 30 along the curved surface of the rod-like member 10 .

Further, the long hole 34h formed in the flat wiring member 30 is long along the extending direction of the rod-shaped member 10. Therefore, by adjusting the position of the insertion fixing portion in the elongated hole 34h, it is possible to easily deal with different fixing holes 11 in the rod-shaped member 10. FIG. Therefore, for example, the same wiring module 20 can be easily standardized as a wiring component that is fixed to the same type of bar member 10 for different vehicle models.

<Examples of application to different car models>
An application example in which the wiring module 20 is shared as a component for different vehicle models will be described.

FIG. 5 is a diagram showing an example of a rod-shaped member. The bar member is part of the vehicle. Here, an example in which the rod-shaped members are reinforcements 80 and 90 will be described. The reinforcements 80 and 90 are, for example, instrument panel reinforcements provided on the opposite side of the vehicle interior with respect to the instrument panel, and extend along the vehicle width direction. The reinforcements 80 and 90 do not need to be instrument panel reinforcements, and may be reinforcements provided at other locations in the vehicle.

In FIG. 5, two types of reinforcements 80, 90 are shown. The two types of reinforcements 80 and 90 are applied to different vehicle types. Here, reinforcement 90 is longer than reinforcement 80 . It is assumed that the width dimension of the vehicle body to which the reinforcement 90 is fixed is larger than the width dimension of the vehicle body to which the reinforcement 80 is fixed. In the following description, it is assumed that the flat wiring member 30 having a common configuration is fixed to the two types of reinforcements 80 and 90, respectively.

The reinforcement 80 includes a first extension portion 81 , a second extension portion 82 and an intervening portion 83 . The second extension portion 82 is narrower than the first extension portion 81 . The first extension portion 81 and the second extension portion 82 extend on the same straight line. In this embodiment, the first extension portion 81 and the second extension portion 82 are separated along the extension direction of the reinforcement 80 . The intervening portion 83 is interposed between the first extending portion 81 and the second extending portion 82 along the extending direction of the reinforcement 80 . The intervening portion 83 is formed in a shape that gradually tapers from the first extending portion 81 toward the second extending portion 82 . The reinforcement 80 is, for example, a cylindrical member. In this case, the diameter of the first extension portion 81 is greater than the diameter of the second extension portion 82 . The intervening portion 83 has a conical circumferential surface whose diameter gradually decreases from the first extending portion 81 toward the second extending portion 82 . The reinforcement 80 may have an elliptical tubular shape or a square tubular shape.

The fixing holes 11 are formed in the reinforcement 80 . Here, a fixing hole 11 is formed at the boundary between the first extension portion 81 and the intervening portion 83 . It is assumed that the fixing hole 11 is formed in the intervening portion 83, the portion adjacent to the intervening portion 83, and the portion extending from the intervening portion 83 to its adjacent portion. The fixing hole 11 may be provided at a position distant from the intervening portion 83 .

As with the reinforcement 80 , the reinforcement 90 has a first extension portion 91 corresponding to the first extension portion 81 , a second extension portion 92 corresponding to the second extension portion 82 , and an intervening portion 83 . and a corresponding intervening portion 93 . A fixing hole 11 is formed at the boundary between the first extending portion 91 and the intervening portion 93 in the same manner as described above.

As mentioned above, the reinforcements 80 and 90 are different in length. For this reason, it is conceivable that the first extension portion 91 is longer than the first extension portion 81 and the intervening portion 93 is positioned further away from the ends of the reinforcements 80 and 90 than the intervening portion 83 . Further, the fixed position of the flat wiring member 30 at the end of the first extending portions 81 and 91 is determined by the position of the component to which the flat wiring member 30 is connected, the connection path, etc. Suppose that it exists at a fixed fixed position P at a certain distance from the part.

In this case, it is assumed that the distance D2 between the constant fixing position P of the reinforcement 90 and the fixing hole 11 is larger than the distance D1 between the constant fixing position P of the reinforcement 80 and the fixing hole 11. As described above, the wire fixing member 40 is movable along the longitudinal direction of the long hole 34h. Therefore, the distances D1 and D2 between the fixed fixing position P and the fixing hole 11 can be adjusted.

When fixing the flat wiring member 30 to the reinforcement 80, the wiring fixing member 40 is fixed to the reinforcement 80 at the fixed fixing position P as shown in FIG. Fixation at this portion may be made with a binding member 88 such as a binding band or adhesive tape, or may be made with a clip (also called a clamp) for fixing to the vehicle. The wire fixing member 40 is inserted and fixed into the fixing hole 11 in a state where it is moved through the elongated hole 34h of the flat wiring member 30 and positioned near the fixed fixing position P. As shown in FIG. As a result, the flat wiring member 30 is fixed to the reinforcement 80 along the surface of the reinforcement 80 .

When fixing the flat wiring member 30 to the reinforcement 90, the wiring fixing member 40 is fixed to the reinforcement 90 at the fixed fixing position P as shown in FIG. Since the distance D2 is larger than the distance D1, the wire fixing member 40 cannot be inserted into the fixing hole 11 when the wire fixing member 40 is positioned at a fixed position with respect to the flat wiring member 30 . Therefore, the wiring fixing member 40 is moved along the elongated hole 34h and positioned near the end away from the fixed fixing position P. As shown in FIG. In this state, the wire fixing member 40 is inserted and fixed into the fixing hole 11 . Thereby, the flat wiring member 30 is fixed to the reinforcement 90 along the surface of the reinforcement 90 .

As a result, the same flat wiring member 30 can be applied to vehicle models with different fixing positions on the rod-shaped member 10 (reinforcements 80, 90).

As shown in FIG. 8, the long holes 34h formed in the flat wiring member 30 may be a plurality of holes 35h formed so as to be spaced apart along the extending direction of the rod-shaped member 10. The hole 35h may have the same shape as the fixing hole 11, for example. In this case, by selectively selecting a hole into which the insertion fixing portion 50 is inserted from the plurality of holes 35h, it is possible to easily cope with the positional deviation of the fixing holes in the rod-shaped member.

When the positions of the fixing holes 11 are different in the reinforcements 80 and 90 in the circumferential direction of the reinforcements 80 and 90, the wiring fixing member 40 is set to the width of the flat wiring member 30 as shown in FIGS. It can be aligned in direction.

For example, when the reinforcement 80 is positioned above the fixing hole 11, the insertion fixing portion 50 is inserted into the fixing hole 11 while the wire fixing member 40 is inserted through the elongated hole 34h in the center of the flat wiring member 30 in the width direction. It can be inserted and fixed (see the state of being fixed to the rod member in FIG. 2). On the other hand, when the fixing holes 11 in the reinforcement 90 are positioned obliquely laterally from above, as shown in FIG. The insertion fixing portion 50 can be inserted and fixed into the fixing hole 11 while being inserted through the elongated hole 34h. Even when the insertion fixing portion 50 is arranged near one side of the flat wiring member 30, one end portion of the pressing portion 42 is more than half of the width direction of the flat wiring member 30, preferably the linear transmission member 32 is arranged. It is preferable to press the portion toward the surface of the rod-shaped member 10 . In either case, the flat wiring member 30 itself can be placed above the reinforcements 80 and 90 .

[Embodiment 2]
A wiring fixing member 140 and a wiring module 120 according to the second embodiment will be described. FIG. 10 is a plan view showing the wiring module 120 fixed to the bar member 10. FIG. 11 is a cross-sectional view taken along the line XI--XI of FIG. 10. FIG. FIG. 12 is an explanatory diagram showing a state in which the wiring module 120 is being fixed to the rod-like member 10. As shown in FIG. In FIG. 12, the flat wiring member 30 and the wiring fixing member 140 in the inserted and fixed state are indicated by chain double-dashed lines. FIG. 13 is a cross-sectional view showing a state in which the wiring module 120 is being fixed to the bar member 10. As shown in FIG. In the description of the second embodiment, the same components as those described in the first embodiment are denoted by the same reference numerals, and the description thereof will be omitted.

In this embodiment, an example will be described in which the shaft portion 152 is rotatable in the fixing hole 11, and the retaining protrusion 154 is retained in the fixing hole 11 by rotating the insertion fixing portion 150. .

The wire fixing member 140 includes an insertion fixing portion 150 instead of the insertion fixing portion 50 of the wire fixing member 40 . The insertion fixing portion 150 has a shaft portion 152 and a retaining protrusion 154 .

The proximal end portion of the shaft portion 152 is configured to be rotatable within the fixing hole 11 while the insertion fixing portion 150 is inserted into the fixing hole 11 until the retaining protrusion 154 exceeds the fixing hole 11 . For example, the shaft portion 152 is a cylindrical portion having a diameter equal to or smaller than the width of the fixing hole 11 .

The retaining protrusion 154 protrudes outward from the shaft portion 152 . The retaining projection 154 has a pair of retaining pieces 154a projecting from the shaft portion 152 in a direction away from the axis of the shaft portion 152 . That is, when the shaft portion 152 is observed in the direction along its central axis, the pair of retaining pieces 154a protrude away from the shaft portion 152 .

In this embodiment, the retaining projection 154 has a pair of retaining pieces 154a that are arcuate, similar to the pair of retaining elastic pieces 54a of the retaining elastic projection 54. As shown in FIG. Therefore, by elastically deforming the pair of retaining pieces 154a, the insertion fixing portion 150 can be inserted into the fixing hole 11 shorter than the pair of retaining pieces 154a. By engaging the retaining projection 154 in the fixing hole 11 to prevent the retaining projection 154 from detaching while the pair of retaining pieces 154a are elastically deformed, the elastic force of the pair of retaining pieces 154a can be used to move the pressing portion 42. , the flat wiring member 30 can be pressed. In this embodiment, since the pair of retaining pieces 154a are locked in the fixing hole 11 by the rotation of the insertion fixing portion 150, it is essential that the pair of retaining pieces 154a have a shape that is easily elastically deformable. isn't it.

In this embodiment, when viewed along the extending direction of the shaft portion 152, the extending direction of the pressing portion 42 and the extending direction of the pair of retaining pieces 154a are along the same direction. On the projection plane viewed along the extending direction A of the shaft portion 152 (see FIG. 12), the extending direction of the pressing portion 42 and the extending direction of the pair of retaining pieces 154a match. As a result, when the fixing hole 11 long in the extending direction is formed in the rod-like member 10, the extending direction of the retaining projection 154 is aligned with the extending direction of the fixing hole 11 so that the insertion fixing portion 150 can be inserted into the fixing hole. 11, and after the insertion, by rotating the insertion fixing portion 150, it is suitable for maintaining the inserted and fixed state and holding the flat wiring member 30. As shown in FIG.

That is, in this embodiment, the insertion fixing portion 150 is inserted into the fixing hole 11 while the flat wiring member 30 is arranged on the surface of the rod-shaped member 10 . At this time, the fixing hole 11 extends along the longitudinal direction of the rod-shaped member 10 , and the extending direction of the pair of retaining pieces 154 a is aligned with the longitudinal direction of the fixing hole 11 . As a result, the retaining projection 154 of the insertion fixing portion 150 can be inserted into the fixing hole 11 and positioned inside the rod-shaped member 10 .

Insert the insertion fixing part 150 into the fixing hole 11 until the retaining protrusion 154 exceeds the fixing hole 11 . In this state, the pair of retaining pieces 154a are arranged inside the rod-shaped member 10, and the pressing portion 42 is arranged outside the rod-shaped member 10. As shown in FIG. Immediately after insertion, the pressing portion 42 extends along the extending direction of the rod-shaped member 10 . If necessary, at least one end of the pair of retaining pieces 154a and the pressing portion 42 may be pressed against the inner surface or the outer surface of the rod-shaped member 10 and elastically deformed.

Then, the wiring fixing member 140 is rotated around the central axis of the shaft portion 152 (see arrow B in FIG. 12). For example, the wiring fixing member 140 is rotated by 90 degrees. Then, the pressing portion 42 rotates around the shaft portion 152 outside the rod-shaped member 10 , and the inner surface 43 of the pressing portion 42 is arranged along the outer peripheral surface of the rod-shaped member 10 . As a result, the arc-shaped inner side surface 43 presses the flat wiring member 30 toward the outer peripheral surface of the rod-shaped member 10 . In this state, since the arc-shaped inner side surface 43 is arranged along the arc-shaped portion of the rod-shaped member 10, the posture of the wire fixing member 140 around the shaft portion 152 is stable.

Inside the rod-shaped member 10, the retaining projection 154 rotates around the shaft portion 152, and the tips of the pair of retaining pieces 154a touch the inner peripheral surface of the rod-shaped member 10 at positions separated in the width direction of the fixing hole 11. (see FIG. 11). In this state, the positions of the inner peripheral surface of the rod-shaped member 10 with which the tips of the pair of retaining pieces 154a abut are separated from the fixing hole 11 with the pressing portion 42 as a reference. The length of the shaft portion 152 is set to such an extent that the wiring fixing member 140 does not rattle in the extending direction of the shaft portion 152 in the above state. Preferably, when the wire fixing member 140 is inserted and fixed, the pair of retaining pieces 154a are elastically deformed.

According to the second embodiment, the insertion fixing portion 150 is rotated in a state where the insertion fixing portion 150 is inserted into the fixing hole 11 until the removal preventing protrusion 154 exceeds the fixing hole 11 , so that the removal preventing protrusion 154 is rotated. can be retained in the fixing hole 11 to prevent it from coming off.

In this state, when viewed along the extending direction of the shaft portion 152, the pressing portion 42 extending along the extending direction of the pair of retaining pieces 154a is arranged to intersect the extending direction of the rod-shaped member 10. . Therefore, the pressing portion 42 can easily press the flat wiring member 30 along the curved surface of the rod-like member 10 .

[Variation]
In each of the above-described embodiments, it is conceivable that the insertion fixing portions 50 and 150 have no directionality around the shaft portions 52 and 152 . For example, the insertion fixing portion may be a tree-shaped clip in which an umbrella-shaped elastic piece is formed on a rod-shaped shaft. In this case, the fixing hole may not be a hole elongated in one direction, and may be a circular hole, for example.

It should be noted that each configuration described in each of the above embodiments and modifications can be appropriately combined as long as they do not contradict each other.

10 rod-shaped member 11 fixing holes 20, 120 wiring module 30 flat wiring member 32 linear transmission member 32a core wire 32b coating 34 base member 34h long hole 35h holes 40, 140 wiring fixing members 42, 142 pressing portions 43, 143 inner surface 50, 150 insertion fixing portions 52, 152 shaft portion 54 retaining elastic projection 54a retaining elastic pieces 80, 90 reinforcements 81, 91 first extending portions 82, 82 second extending portions 83, 83 intervening portion 88 binding member 143a Corner 154 Retaining protrusion 154a Retaining piece

Claims (9)

1. a pressing portion having an inner surface curved according to the surface of the rod-shaped member;
   an insertion fixing portion protruding from the pressing portion and inserted and fixed into a fixing hole formed in the rod-shaped member;
   A wiring fixing member that forms a space in which a flat wiring member can be arranged between the inner surface and the surface of the rod-like member in a state in which the insertion fixing portion is inserted and fixed in the fixing hole.
2. The wiring fixing member according to claim 1,
   The wiring fixing member, wherein the inner surface has a shape having at least one of an arcuate curved portion and an angularly curved portion.
3. The wiring fixing member according to claim 1 or claim 2,
   A wiring fixing member, wherein the insertion fixing portion protrudes from an intermediate portion in the extending direction of the pressing portion.
4. The wiring fixing member according to any one of claims 1 to 3,
   A wire fixing member, wherein the insertion fixing portion has a shaft portion and an elastically deformable removal-preventing elastic protrusion projecting outward gradually from the distal end side to the proximal end side of the shaft portion.
5. The wiring fixing member according to claim 4,
   The retaining elastic projection has a pair of retaining elastic pieces protruding from the shaft,
   A wiring fixing member, wherein the extending direction of the pressing portion and the extending direction of the pair of retaining elastic pieces intersect when viewed along the extending direction of the shaft portion.
6. The wiring fixing member according to any one of claims 1 to 3,
   The insertion fixing portion has a shaft portion and a retaining protrusion projecting outward from the shaft portion, and the insertion fixing portion is inserted into the fixing hole until the retaining protrusion exceeds the fixing hole. a wiring fixing member, wherein the base end portion of the shaft portion is rotatable in the fixing hole in the fixed state.
7. The wiring fixing member according to claim 6,
   The retaining projection has a pair of retaining pieces projecting from the shaft,
   A wiring fixing member, wherein the extending direction of the pressing portion and the extending direction of the pair of retaining pieces are along the same direction when viewed along the extending direction of the shaft portion.
8. a wiring fixing member according to any one of claims 1 to 7;
   a flat wiring member positioned on the inner side surface of the pressing portion;
   Wiring module with
9. The wiring module according to claim 8,
   The flat wiring member includes a plurality of linear transmission members, a base member that keeps the plurality of linear transmission members flat, and
   with
   A wiring module, wherein at least one of a long hole along the extending direction of the rod-shaped member and a plurality of holes formed to line up along the extending direction of the rod-shaped member is formed in the base member.

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