JP5090831B2 - Power feeding device for slide structure - Google Patents

Description

  The present invention relates to a power supply device for a slide structure for constantly supplying power to a slide structure such as a slide door of an automobile from a fixed structure such as a vehicle body.

  FIG. 10 shows a first form of a conventional power feeding device for a slide structure (see Patent Document 1).

  The power feeding device 51 includes a guide rail 53 provided horizontally on a slide door 52 of an automobile, a slider 54 slidably engaged with the guide rail 53, one end connected to the slider 54, and the other end to the guide rail 53. A pair of openable and closable mountain-shaped links 55 and 56 are provided.

  The wire harness 57 is routed from the link arm 55 to the fixing portion 59 on the vehicle body 58 side while being bent in a substantially U shape via the slider 54, and one end of the wire harness 57 is connected to the wire harness 60 on the slide door side by a connector. The other end is connected to the vehicle body side wire harness 61 by a connector.

  As the slide door 52 is opened and closed, the pair of links 55 and 56 opens and closes (extends and contracts), and the slider 54 moves along the guide rail 53 and is always positioned in the vicinity of the fixed portion 59 on the vehicle body side.

  FIG. 11 shows a second embodiment of a conventional power feeding device for a slide structure (see Patent Document 2).

  The power supply device 62 is configured by connecting three long and short links 65 between a slide door 63 and a vehicle body 64 of an automobile so as to be swingable in a horizontal direction. A wire harness 66 is connected to the vehicle along each link 65. It is routed from the body 64 to the slide door 63.

  As the slide door 63 opens and closes, the links 65 rotate in opposite directions to absorb the amount of movement of the slide door 63.

  FIGS. 12-13 shows the 3rd form of the electric power feeder for the conventional slide structure (refer patent document 3).

  The power supply device 67 has a protector (case) 32 made of synthetic resin assembled to a slide door 68 of an automobile, and one end side is fixed in the protector, and the wire harness 69 is supported and biased upward at the other end side. A metal leaf spring 70 is provided. The protector 32 includes a base 32a and a cover 32b (FIG. 14).

  The wire harness 69 is routed from the opening 71 at the front end of the protector 32 to the slide door side, passes from the elongated opening 72 at the lower end of the protector 32 through the crossing space 73, and the harness fixture 12 near the step on the vehicle body 74 side (see FIG. 14) and is connected from the harness fixture 12 to a wire harness (not shown) on the vehicle body side.

  The wire harness 69 is composed of a plurality of insulated coated electric wires and a flexible corrugated tube made of synthetic resin that covers the wires. A corrugated tube having an oblong cross section (flat type) is routed between the protector 32 and the harness fixture 12 with the long diameter portion being vertical.

When the sliding door 68 in FIG. 12 is fully closed, the wire harness 69 is pulled backward with the harness fixture 12 as a fulcrum while bending the leaf spring 70 downward, and when the sliding door 68 is fully opened (FIG. 13 shows a state immediately before full opening). The wire harness 69 is pulled forward with the harness fixture 12 as a fulcrum while bending the leaf spring 70 downward, and when the slide door 68 is half-opened, the wire harness 69 hangs down as shown by a chain line in FIG. However, it is urged upward by the leaf spring 70 to absorb the excess length, and it is possible to prevent the wire harness 69 from being drooped and being caught when the door is closed.
JP 2001-122054 (FIG. 1) JP 2001-151042 A JP 2002-17032 A (FIGS. 4 to 5)

  However, in the first power supply device 51 of FIG. 10 described above, there is a problem that the number of parts and the weight increase due to the long guide rail 53 and the links 55 and 56, and the wire harness 57 has the slider portion 54 and the links 55 and 56. Bending to a small diameter at the intersection of the wires, the bending stress may increase, and the durability of the wire harness 57 may decrease, and the wire harness 57 may interfere with other parts in the door and cause damage. There was a concern. Further, in the second power supply device 62 of FIG. 11 described above, there is a concern that the wire harness 66 may be bent in a complicated manner with the rotation of each link 65 and the durability of the wire harness 66 may be reduced.

  In the third power supply device 67 of FIG. 12 described above, the protector 32 is enlarged in order to absorb (accommodate) the extra length of the wire harness 69 along the leaf spring 70 in the protector 32 in a curved shape. There is a concern that it occupies a large area inside the slide door 68 and the degree of freedom of arrangement of other auxiliary machines is limited. Moreover, in order to bend and accommodate the wire harness 69 in the protector, a long wire harness 69 is required (corrugated tube and electric wire part becomes long), and there is a concern that the cost is increased and the weight is increased.

  These concerns can occur in the same way when each power supply device is applied to a slide structure such as a slide door of a train or the like, a manufacturing device, a detection device, or the like as well as a slide door of an automobile. . In this case, the vehicle body, the apparatus main body, and the like are collectively referred to as a fixed structure.

In view of the above facts, to eliminate the lengthening and weight reduction in the size and the wire harness protector can be placed at low cost space, moreover, to reduce the bending stress of the wire harness It is a first object of the present invention to provide a power feeding device for a slide structure that can enhance the durability of a wire harness. In addition, a second object is to provide a power feeding device for a slide structure that can prevent the interference between the wire harness and other parts and the like and can increase the durability of the wire harness.

In order to achieve the above object, a power supply device for a slide structure according to claim 1 of the present invention is provided with a link arm on a protector base disposed vertically on the slide structure so as to be rotatable at a shaft portion. A harness holder is rotatably connected to the rotation tip side of the link arm, the wire harness is inserted and held in the harness holder, the link arm is urged by an elastic member in the harness surplus length absorption direction, A power supply device for a slide structure in which one of the wire harnesses is routed from the harness holder to the slide structure, and the other of the wire harnesses is routed to the fixed structure, wherein the harness holder is connected to a link arm. A wire harness insertion holding portion offset in the wire harness radial direction and in the harness surplus length absorption direction from the link arm connecting portion, From ear harness the wire harness through the holding portion passes between the said and the link arm connecting portion shaft portion, and a curved bent portion across said link arm in the width direction to one of the wire harness It is characterized by continuing.

  With the above configuration, the wire harness is fixed to the harness holder on the distal end side of the link arm, for example, is swingably routed from the slide structure to the fixed structure. The wire harness swings in the opening / closing direction while rotating in the opening / closing direction. When the slide structure is half open, the slack of the wire harness increases between the slide structure and the fixed structure, but the elastic member loosens the link arm and rotates it in the slack absorption direction. The protector base may be sized to accommodate the link arm or harness holder, or may be sized to accommodate a part of the link arm. This accommodation is performed by attaching the protector cover to the protector base, but the protector cover may be a part of a slide structure, for example.

In addition, when the slide arm is opened and closed, the link arm is rotated while the harness holder is rotated independently of the link arm in the direction of rotation of the link arm or in the opposite direction. The wire harness is routed from the slide structure to the fixed structure, and the length of the wire harness can be shortened. Bending stress is reduced.
Further, the wire harness from the portion (shaft portion) for connecting the link arms are arranged offset (eccentric), Wa ear harness to bend with a large radius without such bending on the outside of the shaft portion, the bending stress applied to the wire harness It is reduced.

A power supply device for a slide structure according to a second aspect is the power supply device for the slide structure according to the first aspect , wherein the harness holder includes a holder base and a holder cover, and the holder base and the holder cover The wire harness is inserted and held in between.

  With the above configuration, the wire harness is inserted into the holder base while the holder cover is opened, the holder cover is closed, and the wire harness is held between the holder base and the holder cover. When a corrugated tube is used as the protective tube of the wire harness, for example, the concave groove of the corrugated tube is engaged with the inner peripheral rib of the holder base.

Feeding device for a slide structure according to claim 3, wherein the power supply apparatus for a sliding structure according to claim 2, wherein the holder base, the link ah minutes arm connecting portion, as the wire harness insertion holding portion characterized in that e Bei a portion for holding the corrugated tube of the wire harness.

With the above structure, the corrugated tube from the portion (shaft portion) for connecting the link arm wire harness are arranged offset (eccentric), corrugated tube Wa tire harness to bend with a large radius without such bending on the outside of the shaft portion The bending stress applied to the corrugated tube of the wire harness is reduced.

The power supply device for a slide structure according to claim 4 is the power supply device for a slide structure according to any one of claims 1 to 3, wherein the wire harness interferes with the elastic member and the shaft portion. To avoid this, a guide plate is provided so as to cross the link arm integrally, and the wire harness passes from the wire harness insertion holding portion between the link arm connecting portion and the guide plate, and the curved bent portion. The link arm is traversed in the width direction and continues to one of the wire harnesses .

  With the above configuration, the wire harness contacts the guide plate of the link arm and does not move further in the direction of the elastic member or the shaft portion, and interference between the wire harness and the elastic member or the shaft portion is prevented.

The power supply device for a slide structure according to claim 5 is the power supply device for a slide structure according to any one of claims 1 to 4 , wherein the wire harness, the elastic member, and the shaft portion are provided on the protector base. A guide plate for preventing interference with the projection is provided.

  With the configuration described above, the wire harness abuts against the guide plate of the protector base and does not move further in the direction of the elastic member or the shaft portion, and interference between the wire harness and the elastic member or the shaft portion is prevented.

The power supply device for the slide structure according to claim 6 is the power supply device for the slide structure according to any one of claims 1 to 5 , wherein the shaft portion connecting the harness holder to the link arm and the wire harness A rib for preventing interference with the harness holder is provided on the edge of the harness holder around the shaft portion.

  With the above configuration, the wire harness introduced from the harness holder toward the link arm abuts on the peripheral rib of the harness holder, thereby preventing interference between the wire harness and the inner shaft portion of the rib.

A power supply device for a slide structure according to a seventh aspect is the power supply device for the slide structure according to any one of the first to sixth aspects, wherein the rotation tip side of the link arm is disposed on the other side of the wire harness. It is characterized by bending in the direction of the cable.

  With the above configuration, for example, when the power feeding device is arranged perpendicular to the slide structure, the tip end side of the link arm is bent downward, and the upward protruding amount of the wire harness introduced upward from the harness holder at the tip of the link arm is The amount of downward bending of the arm is reduced, and the overall height of the power supply device can be reduced.

The power supply device for a slide structure according to claim 8 is the power supply device for a slide structure according to any one of claims 1 to 7 , wherein one of the wire harnesses is connected from the harness holder to the protector base and the link. It is characterized in that it is routed through the arm.

  With the above configuration, the wire harness is routed along the surface of the protector base by effectively using the space between the protector base and the link arm, and the space occupied by the wire harness in the protector base is saved in the thickness direction of the protector base. Space is made.

  According to the first aspect of the present invention, since the surplus length of the wire harness is absorbed by the rotation of the link arm, the surplus length absorbing space is provided as compared with the case where the wire harness is accommodated in a curved shape along a conventional leaf spring. And the structure is reduced in size and cost by a simple configuration of the link arm, the harness holder, and the elastic member.

In addition, by rotating the harness holder independently of the link arm, the wire harness is routed at the shortest distance, the length of the wire harness is shortened, the power feeding structure is made compact and lightweight, The bending stress applied to the wire harness is reduced, the durability of the wire harness is improved, and the reliability of constant power supply is increased.
Further, the harness holder, by providing the offset wire harness insertion holding portion from the link arm connecting portion to the harness excess length absorbing direction, Wa tire harness is bent at bending etc. without large radius on the outside of the shaft portion, the wire The bending stress applied to the harness is reduced, the durability of the wire harness is increased, and the reliability of constant power supply is improved.

According to the second aspect of the present invention, for example, a corrugated tube can be easily held between the holder base and the holder cover as a protective tube for the wire harness, for example, and the ease of assembling the wire harness to the harness holder is improved. To do.

According to the third aspect of the present invention, word ear harness of the corrugated tube is bent with a large radius without such bending on the outside of the shaft portion, the bending stress applied to the corrugated tube of the wire harness is reduced, the wire harness corrugated tube As a result, the reliability of continuous power supply is improved.

According to the fourth aspect of the present invention, the guide plate of the link arm prevents interference between the wire harness and the elastic member or the shaft portion, and there is no fear of the wire harness being worn or damaged due to the interference. Increased reliability.

According to the fifth aspect of the present invention, the protector-based guide plate prevents interference between the wire harness and the elastic member or the shaft portion, so that there is no fear of the wire harness being worn or damaged due to the interference. Increased reliability. Moreover, the said effect is accelerated | stimulated by the synergistic effect with invention of Claim 4 .

According to the invention of claim 6 , the rib of the harness holder prevents interference between the wire harness and the shaft inside the rib, and there is no fear of the wire harness being worn or damaged due to the interference. Increases nature.

According to the invention of claim 7 , when the power feeding device is arranged perpendicular to the slide structure, the amount by which the wire harness protrudes upward from the harness holder is reduced by the amount of bending of the distal end side of the link arm, By reducing the height of the power feeding device, it is possible to save space on the slide structure side and improve the degree of freedom of layout of other components.

According to the eighth aspect of the invention, the wire harness is routed using the space between the protector base and the link arm, so that the power feeding device is thinned and the mounting space to the slide structure or the like is reduced. Is done.

  FIG. 1 shows an embodiment of a power feeding device for a slide structure according to the present invention.

  This power supply device 1 includes a protector base 2 made of synthetic resin that is mounted vertically (vertically) on a sliding door (slide structure) of an automobile, and a base portion that is rotatably supported by a shaft portion 3 on the protector base 2. A single link arm 4, a torsion spring (elastic member) 5 that urges the link arm 4 upward, and a harness holder 6 that is rotatably connected to the tip of the link arm 4. Is.

  The protector base 2 includes a vertical substrate portion 7 on the back side, a peripheral wall composed of vertical wall portions 8 and 9 at the front and rear ends, and an upper horizontal wall portion 10, and a long opening 11 on the lower side. It is formed in a horizontally long rectangular shape. It is also possible to shorten the upper wall portion 19 or eliminate the rear end wall portion 9.

  A protector cover (not shown) is preferably attached to the protector base 2, and the protector base and the protector cover constitute the protector. The protector base 2 is fixed to the slide door panel with bolts (not shown). A harness guide 2a having a curved longitudinal section as shown in FIG. 8 to be described later is formed at the edge of the lower opening 11 of the protector cover close to the passenger compartment. When the protector cover is not used, a separate harness guide 2a is disposed on the slide door side, or a synthetic resin door trim (not shown) is used as the protector cover.

  In the protector, the link arm 4 and the harness holder 6 are rotatably accommodated and protected along the board portion 7 of the protector base 2, and the wire harness 13 is connected to the vehicle body (fixed structure) from the elongated lower opening 11 of the protector. ) Side.

  The shaft portion 3 is disposed on the plate wall 14 at the upper front side of the protector base 2. Adjacent to the front side of the plate wall 14, the harness outlet 15 is provided upward, and the harness guide walls 8 and 78 are erected in parallel from the plate wall 14 on both lower sides of the outlet 15, and between the two guide walls 8 and 78. The vertical portion 13a of the wire portion of the wire harness 13 that has passed through (substitute with reference numeral 13) is fixed by a tie band 16 to a frame-shaped portion (harness fixing portion) 81 having a band insertion hole outside the outlet port 15.

  The wire harness 13 is bent downward from the vertical portion 13a (the downward bent portion is indicated by reference numeral 13b), and then bent upward (the upward bent portion is indicated by reference numeral 13c), while the back side of the distal end side of the link arm 4 is It passes through the corrugated tube 17 made of synthetic resin on the harness holder 6 side. The corrugated tube 17 is an existing bellows-like harness protection tube having good flexibility, in which circumferential grooves and ridges (not shown) are alternately arranged in the tube longitudinal direction.

  As shown in FIG. 2, the link arm 4 has a hole portion 24 through which the shaft portion 3 is inserted on the base end (front end) side, and the hole portion 24 is a short annular boss portion 24 a on the back surface side of the link arm 4. The front end of the boss portion 24a is pivotally in contact with the surface of the plate wall 14 and is inserted into the wire harness between the back surface of the link arm 4 and the surface of the substrate portion 7 by the length of the boss portion 24a. A gap is formed.

  The front end (rear end) side of the link arm 4 is bent downward in an inclined manner (the bent portion is indicated by reference numeral 4a), and is substantially circular via a short narrow portion 18 at the lower half of the front end of the link arm 4. The bearing plate 19 is integrally provided. The harness holder 6 is rotatably connected to the bearing plate 19 by a horizontal shaft portion 20. A link arm assembly 21 is configured by the link arm 4 and the harness holder 6.

  A hook-like spring support piece (support part) 22 for hooking the projecting piece 5a of the latter half of the torsion coil spring 5 protrudes from the upper part of the center in the longitudinal direction on the back surface side of the link arm 4, and as shown in FIG. A column (support) 23 is provided on the second plate wall 14 to hook the first half protruding piece 5b of the torsion spring 5. A central winding portion 5 c of the torsion winding spring 5 is disposed on the outer periphery of the shaft portion 3. The link arm 4 is preferably made of synthetic resin or metal.

  As shown by the chain line in FIG. 3 or FIG. 1, the front half portion 13c ′ of the upward bent portion 13c of the wire harness 13 in FIG. It is preferable that a curved guide plate 25 for preventing interference between the spring 5 and the shaft portion 3 is provided so as to protrude toward the substrate portion 7 of the protector base 2 perpendicular to the back surface of the link arm.

  3 crosses the link arm 4 in the width direction (longitudinal orthogonal direction) and protrudes (extends) downward (the protrusion is indicated by reference numeral 25a), and is provided integrally with the link arm 4. . The guide plate 25 of FIG. 1 is curved and provided within the range of the width dimension of the link arm 4. Any guide plate 25 is effective.

  When the wire harness 13 is routed on the surface side of the link arm 4, it is necessary to shorten or eliminate the boss 24 a of the link arm 4. In that case, the guide plate 25 is disposed on the surface side of the link arm. Since the torsion spring 5 is disposed on the back side of the link arm 4, there is no need to worry about interference between the wire harness 13 and the spring 5.

  It is also effective to project a curved guide plate 79 on the plate wall 14 of the protector base 2 on the outer peripheral side of the shaft portion 3. The guide plate 79 eliminates the concern about interference between the wire harness 13 and the shaft portion 3. Each of the guide plates 25 and 79 may be provided either alone or both.

  As shown in FIG. 2, the harness holder 6 includes a synthetic resin holder base 6a and a holder cover 6b. As shown in FIG. 4, the holder base 6 a includes a rectangular hook-shaped portion (portion for holding the corrugated tube 13) 26, a short hook portion 27 protruding to one side of the hook-shaped portion, and the other side of the hook-shaped portion 26. And a long plate-like portion (portion connecting the link arm 4) 28 protruding in the direction. As shown in FIG. 2, the holder cover 6 b includes a central rectangular cover portion 40 and flanges 41 on both sides having bolt insertion holes 42.

  As shown in FIG. 4, the upper end portion of the plate-like portion 28 of the holder base 6a protrudes slightly longer than the flange portion 26, and a hole portion 29 through which the shaft portion 20 (FIG. 2) is inserted is provided at the upper end portion. Bolt insertion holes 30 for fixing the holder cover 6 b (FIG. 2) to the plate 27 and the plate-like portion 28 are provided symmetrically. A rib 31 protrudes from the periphery of the upper end of the plate-like portion 28, and the rib 31 eliminates the concern that the upward bent portion 13 c of the wire harness 13 of FIG. 1 interferes with the shaft portion 20.

  The hook-shaped portion 26 is configured by being surrounded on both sides by both side walls 33 and a bottom wall 34, and a plurality of strips that engage with the concave grooves in the circumferential direction of the corrugated tube 17 on the inner peripheral surfaces of the wall portions 33, 34. Ribs 35 are formed to protrude. The plate-like portion 28 is disposed orthogonal to the intermediate portion in the height (standing) direction of one side wall 33. The bottom wall 34 is disposed lower than the plate-like portion 28.

  The bottom wall 34 has an inclined part 34a and a flat extension part 34b following the inclined part 34a on the upper end side, and the wire part of the wire harness 13 led out from the insulation lock through-hole, that is, the corrugated tube 17 (FIG. 1) is passed through the extension part 34b. A pair of holes 36 for inserting the band 16 (FIG. 1) to be bound and fixed is provided. The electric wire portion 13 is fixed to at least one end of the corrugated tube 17 with a tape or a band. The electric wire portion 13 can be freely inserted into the corrugated tube without being fixed to the corrugated tube 17. The wire harness 13 includes a plurality of electric wires (electric wire portions) and a corrugated tube 17.

  It is preferable that a plurality of ribs (35) that engage with the circumferential grooves of the corrugated tube 17 are also formed on the inner peripheral surface of the holder cover 6b in FIG. After setting the corrugated tube 17 to the holder base 6a, the holder cover 6b is mounted. A tube insertion space 37 is formed between the holder base 6a and the holder cover 6b.

  Since the hook-like portion 26 of the holder base 6a is disposed adjacent to the plate-like portion 28 having the shaft hole 29, the wire harness 13 passing through the hook-like portion 26 is different from the shaft portion 20 (FIG. 2). It is routed with an offset. As a result, the upward bent portion 13c of the wire portion of the wire harness 13 in FIG. 1 is separated from the shaft portion 20 and is routed with a large bending radius, and the bending stress applied to the wire portion is reduced.

  In the example of FIG. 2, it is also possible to remove the flange portion 27 of the holder base 6a and connect the holder cover 6b to the holder base 6a so as to be openable and closable with a thin and integral hinge (not shown). This hinge structure can also be applied to the example of FIG. 5 described later.

  5A and 5B show an embodiment in which, for example, a holder cover (not shown) is fixed to the holder base 6a ′ of the harness holder 6 ′ by the locking means 38. FIG. The protector base 2 'in FIG. 5A is smaller than the example in FIG.

  The locking means 38 is a locking claw provided on both side walls 33 ′ of the holder base 6 a ′ and an engaging recess (not shown) on the holder cover side. The corrugated tube 17 of the wire harness 13 may be fixed to the holder base 6a ′ with a band (not shown) instead of the locking means 38, and the holder cover may be omitted. The band is inserted through the hole 39 of the plate-like portion 28 ′ adjacent to the flange-like portion 26 ′.

  The plate-like portion 28 ′ is formed longer than the bowl-like portion 26 ′, and an annular boss portion 29 a ′ (FIG. 5B) is provided on the upper end side of the plate-like portion 28 ′. The shaft portion 20 is inserted through the hole portion 29 '. The shaft portion 20 is covered with the boss portion 29 a ′ to prevent interference between the wire portion of the wire harness 13 and the shaft portion 20.

  As shown in FIG. 5B, the plate-like portion 28 'is disposed perpendicular to the intermediate portion in the height (standing) direction of one side wall 33' of the bowl-like portion 26 ', and the bottom wall of the bowl-like portion 26'. 34 'is positioned lower than the plate-like portion 28'. Accordingly, similarly to the example of FIG. 4, the wire harness 13 (FIG. 1) is disposed close to the board portion 7 ′ of the protector base 2, so that the protectors 2 and 2 ′ are thinned, that is, the power feeding device 1. 1 'thickness direction can be made compact.

  As shown in FIG. 5A, the link arm 4 is the same as that shown in FIG. 1, and is rotated upward from FIG. In the example of FIG. 5A, the protector base 2 'is smaller than that in FIG. 1, and the harness holder 6' protrudes from the protector base 2 'to the outside. Short wall portions 8 'and 10' as peripheral walls are provided orthogonally on the front side and upper side of the vertical substrate portion 7 'of the protector 2', and the other portions are largely opened (the opening portion is denoted by reference numeral 11 ' ).

  The link arm 4 abuts against the wall portions 8 'and 10' and is prevented from further rotation. A large protector base (not shown) is overlapped on the surface side of this small protector base 2 ', and fixed to the hole 80 by means such as screwing or welding bosses to form the protector base 2 as shown in FIG. It is also possible. The small protector base 2 ′ can be assembled to the slide door panel.

  In FIG. 5A, the same components as those in FIG. The spring 5 is not shown. Reference numeral 14 ′ denotes a plate wall on the same plane as the substrate part 7 ′, reference numeral 15 denotes a harness outlet 15, reference numeral 81 denotes a band-like part for inserting a band as a harness fixing part, and reference numeral 79 denotes a shaft part 3 or a spring 5 and a wire. It is a guide plate for preventing interference with the harness 13. Of course, it is possible to use the same protector 1 as in FIG. 1 in the example of FIG.

  FIG. 6 shows an embodiment of a link arm 43 in which a harness holder 45 is integrally formed on the rotating tip (free end) side.

The harness holder-integrated link arm 43 is preferably composed of a link arm main body 44 and a harness holder 45 made of synthetic resin. Hole 24 for inserting the shaft portion 3 '' is provided at the base end side of the link arm body 44, the shaft portion 3 'projects from example protector base plate wall 14 ", a stop ring 46 and locking nut on the front end side The link arm 43 is rotatably supported between the torsion coil springs 5 and the torsion coil springs 5 (see FIG. 1) on the outer periphery of the shaft portion 3 '. It is also possible to use a leaf spring or the like as the elastic member instead.

  The harness holder 45 is formed in a rectangular cylinder shape, and has a plurality of ribs 35 that engage with the circumferential grooves in the corrugated tube 17 (FIG. 1) on the inner peripheral surface. The link arm 43 is divided into left and right (plate thickness direction) integrally with the harness holder 45, the plate-like portion 43b on the surface side is removed, and the corrugated tube 17 of the wire harness 13 (FIG. 1) is inserted into the harness holder 45. After that, the divided plate-like portion 43 b is fixed to the main body portion 43 a by tightening the nut 46, positioning means 48, and locking means 49. The positioning means 48 includes, for example, a protrusion protruding from the main body portion 43a and a hole portion of the plate-like portion 43b for engaging the protrusion, and the locking means 49 includes, for example, a flexible frame piece and a frame piece It is comprised with the protrusion to engage.

  It is also possible to close the cover portion 45a only by the harness holder 45 by the locking means 49, or to connect the cover portion 45a to the harness holder main body by a hinge (not shown) so as to be opened and closed.

  The wire portion of the wire harness 13 (FIG. 1) led upward from the harness holder 45 passes through the upper side of the link arm main body 44 and is led out of the plate wall 14 ″ from the harness fixing portion 50 on the shaft portion 3 ′ side. It is preferable.

  The plate wall 14 "is formed as a part of the protector base 2, 2 'as shown in Figs. 1 and 5. Alternatively, the plate wall 14" is used as a bracket, and the plate wall 14 "is directly fixed to the slide door panel or the like with bolts. Since the harness holder 45 in Fig. 6 is a link arm integrated type, it can be rotated independently of the link arm 4 like the harness holders 6 and 6 'in Figs. Can not.

  7 to 9 show the operation of the power feeding device 1 "similar to the power feeding devices 1 and 1 'described above in a simplified manner. The power feeding device 1" shown in FIGS. This is the same as that proposed in Japanese Patent Application No. 2006-295324.

  In the example of FIG. 7, the link arm 4 is rotatably supported by the shaft portion 3 on, for example, a vertical support wall 75 on the slide door side without using the protectors 2 and 2 ′. 1 and 5, it is possible to omit the protectors 2 and 2 'and support the link arm 4 with the support wall 75. FIG.

  In FIG. 7, the right side view shows the fully closed state of the slide door (slide structure) 76, the center view shows the half open state of the slide door 76, and the left side view shows the fully open state of the slide door 76. The power feeding device 1 ″ moves forward and backward integrally with the slide door 76. The wire harness 13 is routed from the harness holder 6 on the distal end side of the link arm 4 to the harness fixing portion 77 on the vehicle body (fixed structure) side. .

  As the slide door 76 is slid rearward and opened, the link arm 4 rotates counterclockwise against the urging force of the spring 5 (FIG. 1), and the harness holder on the distal end side of the link arm 4 6 is rotated counterclockwise, and the wire harness 13 is always routed smoothly between the link arm tip and the harness fixing portion 77 on the vehicle body side at a shortest distance and with a large bending radius. The bending of the wire harness 13 is reduced by preventing the small-diameter bending, and the wire harness 13 can be bent smoothly and the sliding door 76 can be opened and closed. This effect is more prominently achieved by offsetting and wiring the wire harness 13 with respect to the shaft portion 20 of the harness holder 6 as in the embodiment of FIGS. 1 and 5.

  In FIG. 8A, the wire harness 13 tries to hang down when the slide door 76 is half open, but the link arm 4 is rotated upward (clockwise) as indicated by the arrow by the force of the spring 5 (FIG. 1). The state which absorbs the slack (extra length) of the wire harness 13 is shown. In FIG. 8A, reference numeral 2a denotes a lower end portion of the protector 2 (FIG. 1). The lower end portion 2a has a long lower opening 11 through which the wire harness 13 is led out toward the harness fixing portion 77 on the vehicle body side. Have.

  When the link arm 4 is arranged away from the slide door panel 76a in the door thickness direction as shown in FIG. 8B, the wire harness 13 is curved from the harness holder 6 at the tip of the link arm toward the slide door panel 76a ( The curved portion is indicated by reference numeral 13d), and is bent toward the harness fixing portion 77 on the vehicle body side (the bent portion is indicated by reference numeral 13e), that is, the wire harness 13 is bent with a relatively small radius (high bending stress). As shown in FIG. 8C, by arranging the link arm 4 along (close to) the slide door panel 76a, the wire harness 13 extends from the harness holder 6 at the end of the link arm to the harness fixing portion 77 on the vehicle body side. It bends smoothly and smoothly with a large radius (the bent portion is indicated by reference numeral 13e), and the power feeding device 1 "itself is thin. It is of.

  In FIG. 8C, the wire harness 13 is led out from the harness holder 6 to the vehicle body side at a substantially central position in the thickness direction of the power feeding device 1 ″. The thinning of the power feeding device 1 ″ is illustrated in FIGS. This is prominent by arranging the hook-like portions 26 and 26 ′ of the harness holders 6 and 6 ′ closer to the door inner panel 76 a than the link arm 4.

  9A shows a state using a link arm 4 bent downward like the link arm 4 in FIG. 1, and FIG. 9B shows a state using a straight link arm 4 ′. The link arm 4 bent downward in FIG. 9A is led upward from the harness holder 6 on the shaft portion 5 side of the link arm 4 compared to the straight link arm 4 ′ in FIG. 9B. In addition, the protruding amount H of the wire harness 13 is small or suppressed to zero or less, thereby reducing the height of the power feeding device itself.

  In each of the above-described embodiments, the power feeding devices 1 and 1 ′ are arranged vertically (vertically) on the slide door (slide structure) 76. However, for example, as shown in FIG. When there is a margin in the thickness, the power feeding devices 1 and 1 ′ can be arranged horizontally (horizontal) on the slide door 76.

  Further, instead of the slide door 76, the power feeding devices 1 and 1 'may be disposed horizontally (horizontal) on the vehicle body (fixed structure), and the harness fixing portion 77 may be disposed on the slide door 76 side instead of the vehicle body. Is possible.

  Further, in each of the above embodiments, the corrugated tube 17 is used as the harness protective tube, but a resin tube having no irregularities (bellows) other than the corrugated tube, a flexible net-like tube (not shown), or a protective tube is used. It is also possible to use a plurality of electric wires bundled by tape winding or the like without using a wire. In these cases, the wire harness is held and fixed to the harness holder 6 on the distal end side of the link arm by a band or the like, or the wire harness is clamped and fixed by the holder base 6a and the holder cover 6b.

  Moreover, although the example applied to the slide door 76 of a motor vehicle was demonstrated in the said embodiment, not only the slide door 76 of a motor vehicle but slide structures, such as a slide door of trains, a manufacturing apparatus, a detection apparatus, etc. It is also possible to apply the power feeding devices 1 and 1 'to the above. The vehicle body and the like are collectively referred to as a fixed structure.

  The above-described configuration of the power supply device for the slide structure is also effective as a power supply structure for the slide structure, a harness routing structure for the slide structure, a power supply method to the slide structure, and the like.

It is a front view which shows one Embodiment of the electric power feeder for slide structures which concerns on this invention. It is a perspective view which similarly shows one form of the link arm assembly in an electric power feeder. It is a perspective view which shows the other example of a form of a link arm. It is a perspective view which shows one form of the base part of the harness holder connected with a link arm. (A) is a front view which shows the electric power feeder using the other form of a harness holder, (b) is a perspective view which shows the harness holder. It is a perspective view which shows other embodiment of a link arm assembly. It is a front view (description figure) which simplifies and shows the effect | action of an electric power feeder. (A) is the front view which simplifies and shows an electric power feeder, (b) is a side view similarly, (c) is a side view which shows the electric power feeder improved compared with (b). (A) is the front view which simplifies and shows the electric power feeder which aimed at the low profile with the bent link arm, (b) is a front view which shows the example using a straight link arm. It is a perspective view which shows the 1st form of the electric power feeder for the conventional slide structure. It is a perspective view which shows the 2nd form of the electric power feeder for the conventional slide structure. It is a perspective view at the time of a slide structure fully closed which shows the 3rd form of the electric power feeder for the conventional slide structure. It is a perspective view just before full opening of the slide structure similarly showing a 3rd form. It is a side view which shows the hanging state of a wire harness.

Explanation of symbols

1, 1 'Power supply device 2, 2' Protector base 4, 43 Link arm 3, 3 ', 20 Shaft 4a Bent part (turning tip side)
5 Torsion winding spring (elastic member)
6, 6 ', 45 Harness holder 6a Holder base 6b Holder cover 13 Wire harness 17 Corrugated tube 25, 79 Guide plate 26 Gutter-shaped part (holding part)
28 Plate-shaped part (joining part)
31 Rib 76 Sliding door (sliding structure)

Claims (8)

A link arm is provided on a protector base disposed vertically on a slide structure so as to be rotatable at its shaft portion, and a harness holder is rotatably connected to a rotating tip side of the link arm. The wire harness is inserted and held, the link arm is urged by the elastic member in the harness surplus length absorption direction, one of the wire harness is routed from the harness holder to the slide structure, and the other of the wire harness is fixed A power supply device for a slide structure arranged in a structure,
The harness holder includes a link arm connecting portion and a wire harness insertion holding portion offset from the link arm connecting portion in the wire harness radial direction and in the harness surplus length absorption direction, and the wire harness is inserted into the wire harness. From the holding portion , it passes between the link arm connecting portion and the shaft portion, becomes a curved bent portion, crosses the link arm in the width direction, and continues to one of the wire harnesses. Power feeding device for slide structure.   2. The power supply device for a slide structure according to claim 1, wherein the harness holder includes a holder base and a holder cover, and the wire harness is inserted and held between the holder base and the holder cover. .   The power supply apparatus for a slide structure according to claim 2, wherein the holder base includes the link arm connecting portion and a portion for holding the corrugated tube of the wire harness as the wire harness insertion holding portion. . In order to prevent the wire harness from interfering with the elastic member and the shaft portion, a guide plate is integrally provided across the link arm , and the wire harness is connected to the link arm connecting portion from the wire harness insertion holding portion. 4. The structure according to claim 1, characterized in that it passes between the wire harness and the guide plate, forms a curved bent portion, crosses the link arm in the width direction, and continues to one of the wire harnesses . The electric power feeder for slide structures as described in 2.   The power supply for the slide structure according to any one of claims 1 to 4, wherein a guide plate for preventing interference between the wire harness and the elastic member or the shaft portion is provided on the protector base. apparatus.   6. The rib portion for preventing interference between the shaft portion connecting the harness holder to the link arm and the wire harness is provided on an edge portion of the harness holder around the shaft portion. A power supply device for a slide structure according to any one of the above.   The power feeding device for a slide structure according to any one of claims 1 to 6, wherein a turning front end side of the link arm is bent in the other wiring direction of the wire harness.   The power supply device for a slide structure according to any one of claims 1 to 7, wherein one of the wire harnesses is routed from the harness holder through the protector base and the link arm. .

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