JP3908992B2 - Power feeding device and harness wiring structure using the same - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention provides, for example, a power supply device that is arranged in a vehicle body of an automobile and that constantly supplies power to the slide door while absorbing the stroke (lift) in the vehicle compartment approach direction immediately before the slide door is closed, and a harness arrangement using the power supply device. It relates to the cable structure.
[0002]
[Prior art]
Conventionally, a case (harness protector) is placed vertically in a sliding door and a wire harness (synthesizes multiple wires) in order to constantly supply power from the vehicle body side to the electrical components and accessories on the sliding door side. (The one covered with a protective tube made of resin) is bent and housed in the case and energized upward with a leaf spring, and one side of the wire harness is routed to the vehicle body side and the other side to the slide door side. 2. Description of the Related Art A power feeding device that expands and contracts a wire harness in a case with opening and closing of a sliding door has been implemented. When the sliding door is opened from the fully closed state, the sliding door slides two-dimensionally while being spaced apart from the vehicle body.
[0003]
In JP-A-2002-2288, a wire harness is routed from the vehicle body to the sliding door, a box-shaped case is horizontally disposed on the vehicle body side, and a wire harness (a plurality of electric wires) is provided in the case. There has been proposed a power feeding device that absorbs expansion and contraction of a wire harness that accompanies opening and closing of a sliding door by being wound and housed in a loop shape.
[0004]
In addition, a power feeding device has been proposed in which electric power is fed along a curved exterior material having a directivity in the bending direction or a caterpillar shape or the like. There has also been proposed a power feeding device that feeds power using a special electric wire such as a cabtyre cable, a curl cord, or a braided electric wire.
[0005]
[Problems to be solved by the invention]
However, in the power feeding device described above, the sliding door moves in a direction approaching the vehicle body (vehicle compartment side) when the sliding door is fully closed, and the sliding door is moved from the vehicle body when the sliding door is opened from the fully closed state. Since the wire harness moves two-dimensionally while being spaced apart from the outside, there is a concern that the movement of the wire harness becomes complicated, the wire harness is easily bent, and the cost is increased because a wire harness corresponding to the wire harness is used. Moreover, since the wire harness is exposed between the slide door and the vehicle body, there is a concern that the wire harness is likely to be deformed or dirty due to interference with the outside. In addition, in order to accommodate the wire harness in a loop in the case, there is a restriction that a flexible electric wire must be used, and the use of special electric wires such as cabtire cables and curl cords increases the cost. Or the number of wires and the core wire diameter are limited, making it difficult to change the circuit for each vehicle type. Further, when the electric wires are housed in a horizontal case in a multi-layered manner, the case is enlarged in the height direction and cannot be placed in a narrow space of a fixed structure such as a vehicle body.
[0006]
In view of the above-described points, the present invention is a power supply device for constantly supplying power to a slide structure such as a slide door from a fixed structure such as a vehicle body, in a two-dimensional movement when the slide structure is opened and closed. A power supply device that can be smoothly handled, can be arranged on the fixed structure side in a space-saving manner, and can be used for a variety of circuit configurations at low cost using ordinary insulated wires instead of special wires. The purpose is to provide a harness routing structure.
[0007]
[Means for Solving the Problems]
In order to achieve the above-described object, a power feeding device according to claim 1 of the present invention includes: One end side is rotatably connected to the slide member on the slide structure side, Hold the wire harness The A harness holding member that is rotatable about one end side as a fulcrum; Arranged in a fixed structure, A wire harness that accommodates the harness holding member so as to advance and retract and is led out from the other end of the harness holding member Secure one end of the wire harness And a case for swingably supporting.
With the above configuration, for example, when a sliding structure such as a sliding door slides away from a fixed structure such as a vehicle body when fully open, the harness holding member is pulled out from the case and fixed when the sliding structure is fully closed. When sliding while approaching the structure, the harness holding member is pushed into the case. In this way, the two-dimensional motion of the slide structure is smoothly absorbed. The wire harness swings in the case integrally with the harness holding member and smoothly absorbs the two-dimensional motion of the slide structure. The wire harness is safely protected from interference with the outside in the case. Further, since the wire harness is arranged almost linearly in the case and does not overlap vertically, the height of the case is made compact. In addition, since the wire harness is not routed in a loop in the case, each electric wire constituting the wire harness may not be so flexible, and the use of an expensive special electric wire is not necessary.
[0008]
The power supply device according to claim 2 is the power supply device according to claim 1, An arcuate guide rail or guide wall and an arcuate peripheral wall that are slidably guided along the harness holding member are provided in the case. It is provided.
With the above configuration, the harness holding member is Arc-shaped guide rail or guide wall and arc-shaped peripheral wall And the sliding force of the harness holding member is reduced, the operability of the slide structure is increased, the wear of the case and the harness holding member is prevented, and Slide absorption is performed accurately.
[0009]
According to a third aspect of the present invention, in the power feeding device according to the first or second aspect, the harness holding member advances and retreats in the case along an arcuate locus.
With the above configuration, when the slide structure slides away from the fixed structure when fully open, the harness holding member is pulled out from the case with an arcuate path, and the slide structure is close to the fixed structure when fully closed. When sliding, the harness holding member is pushed into the case with an arcuate locus. As a result, the two-dimensional motion of the slide structure is absorbed more smoothly, and the wire harness led out from the other end of the harness holding member swings smoothly without causing a slack in an arc-shaped locus.
[0010]
A power supply device according to a fourth aspect is the power supply device according to any one of the first to third aspects, wherein the harness holding member is formed in an arc shape.
With the above configuration, the movement track of the harness holding member matches the shape of the harness holding member, and the harness holding member moves back and forth more smoothly in the case with an arcuate track. The wire harness led out from the other end of the harness holding member swings more smoothly while maintaining an almost straight state without slacking along an accurate arc-shaped locus.
[0011]
The power supply device according to claim 5 is the power supply device according to any one of claims 1 to 4, wherein the harness holding member allows the wire harness to pass therethrough. Because of the surrounding wall It is characterized by having a space.
With the above configuration, the wire harness is housed inside the harness holding member between the slide structure and the fixed structure, and is reliably protected from interference with the outside, splashing rainwater, and the like.
[0012]
The power supply device according to claim 6 is the power supply device according to any one of claims 1 to 5, wherein the case is formed in a substantially fan shape. The arc-shaped harness holding member is located along the inner surface of the arc-shaped peripheral wall of the case when housed in the case It is characterized by that.
With the above configuration, the case is substantially fan-shaped, so the vertical and horizontal dimensions of the case are minimized, especially in combination with the arc-shaped harness holding member, dead space in the case is reduced, and the case is in the width direction. It is made compact.
[0013]
The power supply device according to a seventh aspect is the power supply device according to any one of the first to sixth aspects, wherein the case fixes a connector of a terminal of the wire harness.
With the above configuration, since the connector is fixed to the case, the mating wire harness can be easily connected to the connector of the case, and the connection workability is improved. Further, since the wire harness swings around the connector as a fulcrum in the case, another wire harness support member is not necessary.
[0014]
The harness wiring structure using the power supply device according to claim 8 is characterized in that the case of the power supply device according to any one of claims 1 to 7 is arranged in a fixed structure, and the slide structure is attached to the fixed structure. Is slidably engaged, the harness holding member is rotatably and slidably connected to the slide structure side, and the wire harness is routed from the slide structure through the harness holding member into the case. , From the case to the fixed structure side Or to the circuit on the fixed structure side through a connector fixed to the case. It is connected.
With the above configuration, the same effects as those of the first to seventh aspects of the invention can be achieved. That is, when the slide structure slides away from the fixed structure when fully open, the harness holding member is pulled out from the case, and when the slide structure slides close to the fixed structure when fully closed, The harness holding member is pushed into the case. In this way, the two-dimensional motion of the slide structure is smoothly absorbed. The wire harness swings in the case integrally with the harness holding member and smoothly absorbs the two-dimensional motion of the slide structure. Since the wire harness is wired almost linearly in the case and does not overlap vertically, the height of the case is made compact. In addition, since the wire harness is not routed in a loop in the case, each electric wire constituting the wire harness may not be so flexible, and the use of an expensive special electric wire is not necessary.
[0015]
The harness routing structure using the power feeding device according to claim 9 is the harness routing structure using the power feeding device according to claim 8, wherein the slide structure is arranged vertically, and the case and the harness holding member are It is characterized by being arranged horizontally.
With the above configuration, when the slide structure is opened and closed, the harness holding member is bridged horizontally from the slide structure to the fixed structure to hold the wire harness without drooping. The case is positioned horizontally without taking any height in the slide structure.
[0016]
DETAILED DESCRIPTION OF THE INVENTION
FIGS. 1-9 shows the electric power feeder by the side of the sliding door which concerns on this invention, and a harness wiring structure using the same.
[0017]
FIG. 1 shows an embodiment of a power supply device. The power supply device 1 is composed of a box-shaped base portion 2 and a plate-like lid portion (cover portion) 3, and a wire harness 4 is folded back into a substantially U shape. A case 5 made of a synthetic resin to be accommodated in a state of being closed, a slider 7 slidably engaged with a guide rail (guide portion) 6 of the base portion 2, and a slider 7 that is rotatably supported by the slider 7. And a rectangular cylindrical harness holding member (connecting member) 8 that accommodates and protects the wire harness portion 4a.
[0018]
The base portion 2 of the case 5 includes a vertical substrate portion 9, a peripheral wall formed by the wall portions 10 to 13 orthogonal to the top, bottom, left and right of the substrate portion 9, and a horizontal guide integrally provided on the substrate portion 9. It comprises rails 6. The lid portion 3 is fixed to the base portion 2 by a locking means (not shown) such as a locking protrusion and a flexible engaging frame portion.
[0019]
A harness introduction port 14 is provided between the upper wall 10 of the base part 2 and the upper part of the one side wall 13, and the upper part of the one side wall 13 is bent inwardly horizontally and wound by tape winding around the wire harness 4. It is a fixed portion 15. The case 5 is disposed on the sliding door, and the wire harness 4 is fixed to the fixing portion 15 with a flexible protective tube such as a corrugated tube on the outer peripheral side in the case 5 and is positioned horizontally along the upper wall 10. The other side wall 12 is folded back in a substantially U shape and extends toward the vehicle body along the harness holding member 8 on the guide rail 6 side. The other side wall 12 may be a vertical wall, but the upper half is curved along the bent portion 4b of the wire harness 4 to save space. The lower wall 11 of the case 5 acts as a harness support wall that prevents the wire harness 4 from drooping particularly when the slider 7 is positioned on the side wall 13 side.
[0020]
The guide rail 6 is positioned horizontally in parallel with the lower wall 11 and extends from one side wall 13 of the case 5 to the other side wall 12. As shown in FIG. 2 (AA sectional view of FIG. 1), the guide rail 6 of this embodiment is formed by recessing the substrate portion 9 of the case 5 and projecting a pair of ribs (protrusions) 17 on both upper and lower edges of the concave portion 16. It consists of A roller 18 of the slider 7 is slidably engaged in the recess 16, and a hook portion 20 is formed so as to protrude from a substrate portion 19 that rotatably supports the roller 18. The shaft portion 21a rotatably connects the harness holding member 8 (FIG. 1).
[0021]
The hook portion 20 is composed of a large-diameter support portion 22 bent perpendicularly downward following the substrate portion 19 and a small-diameter hook-like portion 21 continuing downward from the support portion 22. The shaft portion 21a is located on the end side, and a horizontal portion 21b orthogonal to the shaft portion 21a crosses the lower side of the harness holding member 8 with a gap therebetween, and stabilizes the posture of the harness holding member 8 (FIG. 5). In FIG. 2, a chain line 9 ′ shows an embodiment in which the substrate portion is arranged near the lid portion 3 so as to avoid interference between the support portion 22 of the hook portion 20 and the wire harness 4 (FIG. 1).
[0022]
In FIG. 1, the harness holding member 8 is curved in an arc shape, and is surrounded by a wall portion 23 in the upper, lower, left, and right sides to form a protector shape having a rectangular cross section. A bearing portion 24 including a vertical hole portion through which the shaft portion 21a (FIG. 2) is inserted from below is provided on the end side. The harness holding member 8 is positioned below the guide rail 6 so as to be movable in the horizontal direction along the lower wall 11 of the case 5 and can swing (swing) about the shaft portion 21a. The case 5 functions as a main protector, and the harness holding member 8 functions as a sub protector. The harness holding member 8 is made of synthetic resin and has a relatively high rigidity, and reliably protects the internal wire harness 4.
[0023]
3 and 4 show an embodiment in which the guide rail 25 is provided not on the base portion 2 of the case 5 but on the lid portion 3.
As shown in FIG. 3, a guide rail 25 is horizontally provided over the entire length of the lid 3 at the lower part of the outer surface of the lid 3. The guide rail 25 is composed of a pair of opposing wall portions 26 having a substantially L-shaped cross section, and a space 27 is formed between the pair of wall portions 26 to slidably accommodate the slider 7 ′. A hook portion 20 ′ of the slider 7 ′ is led out from the slit-shaped opening 28.
[0024]
The slider 7 ′ is configured in substantially the same manner as the embodiment of FIG. 2, and includes a plurality of rotatable rollers 18, a substrate portion 19 that supports the rollers 18, and a hook portion 20 ′ that follows the substrate portion 19. As shown in FIG. 4 (BB cross-sectional view of FIG. 3), the hook portion 20 ′ is composed of an upper support portion 22 and a lower portion 21 ′ bent in a hook shape. Unlike the second embodiment, the case 5 is located on the inner side, the vertical part 21c following the support part 22 is located on the outer side, and the vertical upward shaft part 21a is located on the inner side through a short horizontal part. Yes. The harness holding member 8 is rotatably engaged with the shaft portion 21a.
[0025]
The harness holding member 8 is the same as that of the embodiment of FIG. And a bearing portion 24 including an insertion hole 24a.
[0026]
FIG. 5 shows a shaft portion 21a (shown by a solid line) of the embodiment of FIG. 2 and a shaft portion 21a (shown by a chain line) of the embodiment of FIG. This shows the state. The harness holding member 8 swings around the shaft portion 21a in the horizontal direction, that is, in the moving direction of the slider 7 (FIG. 1).
[0027]
FIG. 6 shows a state in which the wire harness 4 is bent and accommodated in a U shape in the base portion 2 of the case 5 and inserted into the harness holding member 8 to close the lid portion 3. The height of the lid 3 is slightly smaller than the height of the base 2, and a horizontal slit-shaped opening is formed between the lower wall 11 of the base 2 and the lower end of the lid 3 at the lower end of the case 5. 30 is configured, and the harness holding member 8 is movable in the opening 30.
[0028]
The wire harness 4 in the case 5 is configured by covering a plurality of electric wires with a protective tube, and the wire harness 4a in the harness holding member 8 is configured by a plurality of electric wires 31 without using the protective tube. Each electric wire is a normal inexpensive insulation-coated electric wire.
[0029]
The case 5 in FIG. 6 is vertically placed (fixed) on a slide door (slide structure) on the left side of the vehicle, and the harness portion 4c led out from the upper side of the case 5 is routed to the slide door and slides. The harness portion 4a connected to the electrical components in the door, auxiliary equipment, etc. and led out through the harness holding member 8 as shown in FIG. 7 (CC cross-sectional view in FIG. 6) is on the vehicle body (fixed structure) side. Is connected to the power supply side.
[0030]
FIG. 6 shows an open state of the slide door (a state in which the slide door is slid rearward of the vehicle). The harness holding member 8 moves along the guide rail 6 (FIG. 1) along with the slider 7 (FIG. 1) to the case 5. The free end side 8a of the harness holding member 8 is pivoted to the front of the case about the shaft portion 21a. The total of the effective length of the guide rail 6 and the horizontal rotation distance L of the harness holding member 8 substantially coincides with the opening stroke of the slide door.
[0031]
By bending the wire harness 4 in a U shape within the case 5, the height of the case 5 can be kept low, and the opening / closing stroke of the sliding door is determined by the sum of the horizontal effective lengths of the guide rail 6 and the harness holding member 8. Thus, the overall length of the case 5 is made compact. It is also possible to further reduce the size by cutting the case 5 into a curved shape from the front end (one side wall 13) of the case 5 to the bent portion 4b of the wire harness 4.
[0032]
By moving the sliding door forward from the open state of FIG. 6 and closing it, the harness holding member 8 moves to the rear end side of the case 5 along the guide rail 6 together with the slider 7 (FIG. 1) as shown in FIG. In addition, as shown in FIG. 9, the free end side 8 a of the harness holding member 8 is positioned so as to rotate backward about the shaft portion 21 a. Within the case 5, the wire harness 4 changes from a U-shape in FIG. 7 to a quadratic curved shape in FIG. 8. The wire harness 4 follows the movement of the slider 7 within the case satisfactorily by the elasticity (restoring force) of a protective tube such as a corrugated tube.
[0033]
The harness holding member 8 is located across the bridge (crossing space) between the slide door and the vehicle body in a bridge shape. The sliding door moves forward in parallel with the vehicle body from the fully open position in FIG. 6 and moves in a direction approaching the vehicle body (vehicle body transverse direction) immediately before reaching the fully closed position in FIG.
[0034]
In the above power feeding device, the harness holding member 8 is formed not in a rectangular cross-sectional shape but in a U-shaped cross-section, a semicircular cross-section, or a flat plate shape so that the wire harness 4 does not jump out of the harness holding member. It is also possible to fix the wire harness 4 at the longitudinal intermediate portion of the holding member.
[0035]
Further, the harness fixing portion 15 (FIG. 1) at the opening edge of the case 5 can be formed in various forms such as projecting outward rather than inward, or disposing upward. Further, the guide rail 6 of the case 5 can be formed on the lower wall 11 of the base portion 2. Further, the slider 7 can be formed of a resin material having good slidability without using the roller 18. Further, in FIG. 2, the guide rail 6 may be disposed on a slightly lower end side of the case 5 so that the shaft portion 21a of the slider 7 protrudes linearly upward from the support portion 22 without bending it into a U-shape. is there. Further, the shaft portion 21a can be provided on the harness holding member 8 and the bearing portion 24 can be provided on the slider 7 side.
[0036]
Moreover, the shape of the harness holding member 8 is not limited to a rectangular cross section, and may be a circular cross section, an oval shape, or the like. In the power feeding device 1, the harness holding member 8 can be directly moved to the vehicle body side so as to freely advance and retract without using a case (FIG. 11) on the vehicle body side which will be described later. Further, when there is sufficient horizontal space in the slide door, the case 5 of the power feeding device 1 can be arranged on the vehicle body side, and the harness holding member 8 can be advanced and retracted into the slide door. Further, the power supply device 1 is not limited to a slide door of an automobile, but can be applied to other slide structures such as a slide door of a device, for example. In that case, it is also possible to arrange the slide structure and the case 5 horizontally, and to arrange the harness holding member 8 on the fixed structure (device main body) in the vertical direction.
[0037]
10 to 15, the stroke of the sliding door (slide structure) 46 (FIG. 14) approaching the vehicle body (fixed structure) 47 (FIG. 14) when fully closed is absorbed by the rotation of the harness holding member 8. 1 shows an embodiment of a power feeding device on a vehicle body side and a harness wiring structure using the power feeding device.
[0038]
As shown in FIGS. 10 and 11, the vehicle body-side power supply device 41 is a harness holding member made of synthetic resin having a cylindrical cross-section that is curved in an arc shape and is a connecting member with the case 5 (FIG. 1) on the sliding door side. A member 8 and a flat, substantially fan-shaped case 44 (FIG. 14) made of a synthetic resin, which accommodates the harness holding member 8 so as to be movable back and forth and are horizontally placed on the vehicle body 47, are formed.
[0039]
The harness holding member 8 is of the form shown in FIG. 1 and has a bearing portion 24 for rotation on the base end side, and a protrusion 45 as a stopper for the case 44 protrudes laterally on the free end side. . The harness holding member 8 of this embodiment has a length and shape obtained by cutting a circle into ¼, and the case 44 is similarly formed in a fan shape with an inner angle of 90 °. The arc length and angle of the harness holding member 8 and the case 44 can be appropriately set according to the separation distance when the slide door 46 is fully opened.
[0040]
The harness holding member 8 is surrounded by the upper, lower, left, and right wall portions 23, is formed in a rectangular cylinder shape, and has an internal space through which the wire harness 4a is inserted. Like a normal harness protector, for example, a hook-shaped portion having a substantially U-shaped cross-section, and a hook-shaped portion that can be opened and closed with a thin hinge, and engaged with an engaging frame portion of the main body with a locking claw or the like It is also possible to configure the harness holding member 8 with a possible plate-shaped cover.
[0041]
The case 44 includes a three-dimensional base portion 42 and a plate-like lid portion 43 (FIG. 14). The base portion 42 includes a horizontal fan-shaped substrate portion 48 and three walls raised around the substrate portion 48. And an opening 52 for advancing and retracting the harness holding member 8 on the outer peripheral side of one linear wall portion 49, and a harness near the proximal end of the other linear wall portion 50. An opening 53 for connection or lead-out is provided. The height of the peripheral wall 49 is slightly larger than the height of the harness holding member 8. The harness holding member 8 is preferably formed as flat as possible, and the height of the vertical left and right wall portions 23 is preferably half or less than the width of the horizontal upper and lower wall portions 23.
[0042]
An arc-shaped wall portion (peripheral wall) 51 continues to the peripheral edge of one opening 52 of the base portion 42, and an arc-shaped guide rail 54 or guide wall that is a guide portion parallel to the arc-shaped wall portion 51 extends from the substrate portion 48. It is erected. The height of the guide rail 54 is considerably lower (about half or less) than the height of the peripheral walls 49 to 51. The harness holding member 8 is slidably guided between the arc-shaped wall 51 and the guide rail 54. The arcuate wall 51 and the guide rail 54 are formed concentrically corresponding to the radius of curvature of the harness holding member 8. The length of the guide rail 54 is shorter than the length of the arcuate wall portion 51.
[0043]
A substantially L-shaped harness guide plate 55 is provided on the distal end side of the harness holding member 8 so as to straddle the guide rail 54, and the wire harness 4 a extends from the opening 56 on the distal end side of the harness holding member 8 along the upper surface of the guide plate 55. Thus, the interference between the wire harness 4a and the guide rail 54 is prevented. The wire harness (a plurality of electric wires) 4a is fixed to the guide plate 55 by a binding means 57 such as a band or a tape. The guide plate 55 is integrally formed on the lower wall of the harness holding member 8 and is bent in a stepped shape upward so as to get over the guide rail 54. It is also possible to provide the guide plate 55 with a slide engaging portion such as a groove with respect to the guide rail 54.
[0044]
The wire harness 4 a extends substantially straight from the guide plate 55 toward the other opening 53 of the case 44, and the connector 58 of the wire harness 4 a is fixed to the other opening 53. The terminal of each electric wire 31 of the wire harness 4a is connected to a terminal, and each terminal is accommodated in a connector housing made of synthetic resin to constitute a connector 58. The connector 58 is locked to the opening edge 53 by a locking means such as a locking projection or an arm. A wire harness (not shown) on the vehicle body side is connected to the connector 58 by a connector.
[0045]
The stopper 52 comes into contact with the opening edge (inner surface) 52 of the case 44 in the state in which the harness holding member 8 of FIG. 10 is pulled out, and the harness holding member 8 is prevented from coming out. When the harness holding member 8 is pushed into the case 44 as shown in FIGS. 12 to 13 from the pulled-out state of FIG. 10, the harness holding member 8 is circular along the guide rail 54 together with the wire harness 4a led out from the tip opening 56. Draw an arc trajectory and slide.
[0046]
The wire harness 4a swings in the case 44 while maintaining a substantially straight state between FIGS. In FIG. 13, the harness part 4a ′ on the connector 58 side is bent in the 90 ° direction. In the pushed state of FIG. 13, the bearing portion 24 at the proximal end of the harness holding member 8 abuts against the opening edge (outer surface) 52 of the case 44, and further pushing is prevented. The bearing portion 24 also functions as a stopper. You may provide the protrusion as a stopper symmetrically with the bearing part 24. FIG.
[0047]
FIG. 14 corresponds to the pulled-out state of the harness holding member 8 of FIG. 10, and the left sliding door 46 of the automobile is pulled to the rear of the vehicle and is fully open. For example, the case 5 of the power feeding device 1 shown in FIG. 1 is provided vertically between the door panel and the door trim of the slide door 46, and the harness holding member 8 is bridged between the slide door 46 and the vehicle body 47. The case 5 extends horizontally and in a curved shape to the horizontally placed case 44. Note that the two power feeding devices 1 and 41 can be regarded as one power feeding device, and in this case, the harness holding member 8 is common.
[0048]
The case 44 on the vehicle body side is horizontally disposed on the floor surface 49. Since this case 44 is flat, it can be applied to a vehicle body 47 having no steps of a passenger car type that is not a one-box car. In FIG. 14, reference numeral 60 denotes a wire harness on the vehicle body side, 61 denotes a lower arm for sliding guidance of the slide door 46, and 62 denotes a weather strip for waterproofing.
[0049]
By moving the slide door 46 forward from the fully open state of FIG. 14, the slide door 46 of FIG. 15 is fully closed. FIG. 15 corresponds to FIG. 13, and immediately before the sliding door 46 is fully closed, the sliding door 46 moves in the direction approaching the vehicle body 47 (in the direction of the passenger compartment) as indicated by an arrow E, and the harness holding member 8 is moved along with the case. It is pushed into the arc 44 with an arcuate trajectory and smoothly absorbs the displacement of the slide door 46 toward the passenger compartment.
[0050]
10 to 15, the internal angle of the fan-shaped case 44 is not limited to 90 °, and can be set as appropriate according to the stroke of the harness holding member 8 for each vehicle type. However, if a larger stroke is set, one type of case 44 and harness holding member 8 can be shared for each vehicle type. The shape of the case 44 is not limited to a fan shape, but may be a rectangular shape (however, a large arrangement space is required), and the shape of the harness holding member 8 is not limited to a ¼ arc (90 ° arc), The radius of curvature and length can be set.
[0051]
Further, the guide rail 54 (FIG. 11) can be provided on the base portion 42 and / or the lid portion 43 of the case 44. It is also possible to provide a guide groove on the upper wall and / or the lower wall of the harness holding member 8 and provide the case 44 with an arcuate low guide rail that is slidably engaged with the guide groove. It is also possible to provide the guide groove in the case 44 and provide the guide rail in the harness holding member 8. In these cases, since there is no concern about interference between the guide rail 54 and the wire harness 4a, the harness guide plate 55 is unnecessary. However, it is preferable to project a portion for fixing the wire harness 4 a by tape winding or the like at the opening end of the harness holding member 8. Further, in these cases, the shape of the harness holding member 8 is not limited to the arc shape, and the harness holding member 8 may be bent into a substantially square shape or a substantially trapezoidal shape. It is also possible to move the linear harness holding member back and forth in the case along an arcuate path, or to move back and forth linearly. However, in this case, a lot of space is required in the case, and the stroke may be slightly lacking in smoothness.
[0052]
Further, the harness holding member 8 can be slidable by a roller or the like like the slider 7 in FIG. Moreover, it is also possible to provide a shaft part (21a) in the harness holding member 8 and to provide a bearing part (24) in the slider 7 of FIG. Further, the connector 58 may be connected to the vehicle body side wire harness 60 outside the case 44 by providing the wire harness 4 a to the outside from the opening 53 of the case 44 without being provided in the case 44.
[0053]
When there is a wide space in the horizontal direction in the slide door 46, the power supply device 41 of FIG. 14 is disposed in the slide door 46 instead of the vehicle body 47, and the case 44 of the power supply device on the slide door side is arranged in the vehicle. It is also possible to arrange on the body side. Further, the power feeding device 41 of FIG. 14 is not limited to an automobile, and can be disposed on a fixed structure that is a device main body corresponding to a sliding structure such as a sliding door of a processing device or the like. In this case, it is also possible to arrange the case 44 vertically (vertically placed) and slide the slide structure in the horizontal direction.
[0054]
【The invention's effect】
As described above, according to the first aspect of the present invention, when the slide structure is fully closed and when the slide structure is opened from the fully closed state, the harness holding member moves forward and backward in the case integrally with the wire harness so that the two-dimensional operation of the slide structure is achieved. Since the wire harness led out from the harness holding member in the case swings and smoothly absorbs the two-dimensional movement, the wire harness is not subjected to a strong load or bending in the expansion / contraction direction, The life of the wire harness is extended, and the reliability of constant power supply from the fixed structure to the slide structure is increased. Since the wire harness is protected from interference with the outside in the case, the reliability of constant power supply is also increased. In addition, since the wire harness is routed almost linearly in the case and does not overlap vertically like a conventional case, the case is made compact in the height direction and easy in a narrow space such as a vehicle body. It is not necessary to use flexible special electric wires, and the cost can be kept low by using ordinary coated electric wires, thereby increasing versatility and adapting to various circuit configurations. Sharing is possible.
[0055]
According to invention of Claim 2, Arc-shaped guide rail or guide wall and arc-shaped peripheral wall As a result, the positionability and slidability of the harness holding member are improved, so that the two-dimensional operation of the slide structure is absorbed more smoothly, and the reliability of the constant power supply is further improved.
[0056]
According to the invention described in claim 3, since the harness holding member advances and retreats in the case along an arcuate locus, the two-dimensional motion of the slide structure is absorbed more smoothly and led out from the other end of the harness holding member. The wire harness smoothly swings without causing a slack in the arc-shaped locus, the load applied to the wire harness is further reduced, the life of the wire harness is extended, and the reliability of the constant power supply is further improved.
[0057]
According to the fourth aspect of the present invention, the harness holding member advances and retreats more smoothly in the case with an accurate arc-shaped trajectory, and the wire harness is substantially straight without causing slack in the accurate arc-shaped trajectory in the case. Therefore, the load applied to the wire harness is further reduced, the life of the wire harness is extended, and the reliability of constant power supply is further improved.
[0058]
According to the invention described in claim 5, since the wire harness is reliably protected from interference with the outside, splashing of rainwater, etc. in the harness holding member, the life of the wire harness is extended and the reliability of constant power supply is further increased. improves.
[0059]
According to the invention described in claim 6, since the dead space in the case is reduced and the case is made compact in the width direction, it can be easily assembled in a narrow space such as a vehicle, and the arrangement of auxiliary machines on the assembly side is arranged. The degree of freedom increases.
[0060]
According to the seventh aspect of the present invention, the mating wire harness can be easily connected to the connector of the case, the connection workability is improved, and the wire harness swings around the connector as a fulcrum in the case. Other wire harness support members are not required, and the cost is reduced.
[0061]
According to the eighth aspect of the present invention, the same effect as that of the first to seventh aspects of the invention can be achieved. That is, when the slide structure is fully closed and when it is opened from the fully closed state, the harness holding member moves forward and backward in the case integrally with the wire harness to smoothly absorb the two-dimensional movement of the slide structure and holds the harness in the case. Since the wire harness derived from the member swings and smoothly absorbs the two-dimensional movement, the wire harness is not subjected to a strong load or bending in the expansion / contraction direction, extending the life of the wire harness and sliding from the fixed structure The reliability of constant power supply to the structure is increased. Since the wire harness is protected from interference with the outside in the case, the reliability of constant power supply is also increased. In addition, since the wire harness is routed almost linearly in the case and does not overlap vertically like a conventional case, the case is made compact in the height direction and easy in a narrow space such as a vehicle body. It is not necessary to use flexible special electric wires, and the cost can be kept low by using ordinary coated electric wires, thereby increasing versatility and adapting to various circuit configurations. Sharing is possible.
[0062]
According to the ninth aspect of the invention, since the harness holding member is bridged horizontally between the slide structure and the fixed structure and holds the wire harness without drooping, the wire harness may be caught in the slide structure. There will be no. Moreover, since the case is positioned horizontally without taking a height in the slide structure, versatility to various vehicles and the like is enhanced.
[Brief description of the drawings]
FIG. 1 is an exploded perspective view showing an embodiment of a power feeding device on the slide structure side according to the present invention.
FIG. 2 is a cross-sectional view taken along the line AA of FIG.
FIG. 3 is an exploded perspective view showing an embodiment in which the arrangement of the guide rails of the power feeding device is changed.
4 is a cross-sectional view taken along the line BB in FIG.
FIG. 5 is a perspective view showing an engaged state between a harness holding member and a shaft portion of each power feeding device.
FIG. 6 is a perspective view showing a state where a harness holding member is slid to one side in an assembled state of the power feeding device.
7 is a cross-sectional view taken along the line CC of FIG.
FIG. 8 is a perspective view of a state in which a harness holding member of the power feeding apparatus is slid to the other side.
9 is a side view taken along the arrow D in FIG. 8. FIG.
FIG. 10 is a plan view showing an embodiment of a power feeding device on the fixed structure side according to the present invention with a lid part removed.
FIG. 11 is a perspective view showing a power feeding device on the fixed structure side in the same manner.
FIG. 12 is a plan view showing a state in the middle of pushing in the harness holding member of the power feeding device.
FIG. 13 is a plan view showing a fully pushed state of the harness holding member.
FIG. 14 is a perspective view of a state in which each power feeding device is disposed on a slide door and a vehicle body, and the slide door is fully opened.
FIG. 15 is a perspective view showing a state where the sliding door is fully closed.
[Explanation of symbols]
4a Wire harness
8 Harness holding member
41 Power supply device
44 cases
46 Sliding door (sliding structure)
47 Vehicle body (fixed structure)
51 Wall (peripheral wall)
54 Guide (guide rail)
58 connector

Claims (9)

One end side is rotatably connected to the slide member on the slide structure side, holding the wire harness, and a harness holding member that is rotatable about the one end side,
A case that is disposed in a fixed structure , accommodates the harness holding member so as to be able to move forward and backward , fixes one end of the wire harness led out from the other end side of the harness holding member , and supports the wire harness in a swingable manner A power supply apparatus comprising: The power supply device according to claim 1, wherein an arcuate guide rail or guide wall and an arcuate peripheral wall that are slidably guided along the harness holding member are provided in the case .   The power supply apparatus according to claim 1, wherein the harness holding member advances and retreats in the case along an arcuate locus.   The power feeding device according to claim 1, wherein the harness holding member is formed in an arc shape. 5. The power supply device according to claim 1, wherein the harness holding member has a space surrounded by a wall portion through which the wire harness is inserted. The said case is formed in substantially fan shape, and the said arc-shaped harness holding member is located along the inner surface of the circular-arc-shaped surrounding wall of this case at the time of the accommodation to this case . The power feeding device according to Item 1.   The power feeding device according to claim 1, wherein the case fixes a connector of a terminal of the wire harness. The case of the power feeding device according to any one of claims 1 to 7, wherein the case is disposed in a fixed structure, a slide structure is slidably engaged with the fixed structure, and the harness is held on the slide structure side. A member is rotatably and slidably coupled, and the wire harness is routed from the slide structure through the harness holding member into the case and from the case to the fixed structure , or the case A harness wiring structure using a power feeding device, wherein the harness wiring structure is connected to a circuit on the fixed structure side through a connector fixed to the cable .   9. The harness routing structure using the power feeding device according to claim 8, wherein the slide structure is arranged vertically, and the case and the harness holding member are arranged horizontally.

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