JP4347658B2 - Composite flexible wire body - Google Patents

Description

  The present invention relates to a composite flexible electric wire body that can follow movement of a moving body by bending, for example.

  For example, in a sliding door of an automobile, a movable window, etc., there is a case where power supply is required for a heater or a motor.

  When the electric wire is caused to follow the movement of the moving body, the normal electric wire can be bent in any direction. However, when complicated movement is required, the direction of bending may not be determined, and it may be fatigued due to entanglement or twisting of nearby members, and may lack durability.

  In order to solve such a problem, Patent Document 1 discloses a flat cable that is bent in a circular arc shape so that it can be bent only in one direction and has improved bending resistance.

  However, a flat cable usually does not have a current capacity sufficient to pass a large current.

JP-A-6-338185

  An object of the present invention is to solve the above-described problems, to provide a composite flexible electric wire body that can be bent only in one direction and has a large current capacity.

In order to achieve the above object, a composite flexible electric wire according to the present invention comprises a belt-shaped flat cable having a metal foil conductor sandwiched between two insulating sheets made of a synthetic resin, and is bent in an arc shape. curved inner surface of the longitudinal direction along and along a plurality of covered wires Rutotomoni, characterized in that a portion of said plurality of covered wires were bonded to the curved inner surface.

  In the composite flexible electric wire body according to the present invention, the cross section of the flat cable is bent in an arc shape, and the covered electric wire is placed along the bent inner surface, so that the current capacity can be increased using the covered electric wire.

  Further, it can be bent only on the inner surface side of the arc of the flat cable, and unnecessary twisting and swelling do not occur, so that the operability is improved and the durability is improved.

FIG. 1 is a perspective view of the first embodiment. The flat cable 1 has a plurality of metal foil conductors 4 sandwiched between two insulating sheets 2 and 3 made of synthetic resin, and is formed into a band as a whole .

  The flat cable 1 is manufactured by bonding a plurality of parallel metal foil conductors 4 with insulating sheets 2 and 3 and cutting the insulating sheets 2 and 3 into a band shape having a desired width as shown in FIG. .

Next, as shown in FIG. 3, the cross section of the flat cable 1 is formed in an arc shape by heat treatment on the insulating sheets 2 and 3. For example, the insulating sheets 2 and 3 are bent such that the lower insulating sheet 2 is thicker than the upper insulating sheet 3 and the thinner insulating sheet 2 is inside. This is because bending is easier when the thin insulating sheet 2 is placed inside.
A plurality of covered electric wires 5 are arranged along the longitudinal direction of the flat cable 1 on the curved inner surface side of the flat cable 1, and a part of the plurality of covered electric wires 5 is bonded to the bent inner surface side.

  In the composite flexible electric wire body 6 configured as described above, the flat cable 1 can be bent toward the inner insulating sheet 3 side, but it is difficult to bend outward. Accordingly, the covered electric wire 5 can follow the flat cable 1 and bend only in one direction as a whole.

  Further, a signal or the like that requires a weak current is energized by the metal foil conductor 4 of the flat cable 1, and a large current is energized by using the covered electric wire 5.

  When this composite flexible electric wire body 6 is folded in a U shape as shown in FIG. 4 so that the inner surfaces of the arcs face each other, one end is connected to the fixed body 7 and the other end is coupled to the moving body 8 to move. As the body 8 moves, the composite flexible electric wire body 6 follows in an orderly manner as indicated by the dotted line while maintaining this U-shape.

  FIG. 5 shows a cross-sectional view of the second embodiment, in which the flat cable 1 and the covered electric wire 5 are covered with a flexible cylindrical body 9 made of a synthetic resin.

The housing 9 can prevent the flat cable 1 and the covered electric wire 5 from being damaged and prevent water from entering, and can prevent the flat cable 1 and the covered electric wire 5 from being hardened in a cold region. In this case, if the casing 9 has a flat cross section, bending becomes easier.

1 is a perspective view of Example 1. FIG. It is sectional drawing at the time of manufacture of a flat cable. It is sectional drawing of the state which bent the flat cable at the time of manufacture. It is an operation explanatory view. 6 is a cross-sectional view of Example 2. FIG.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Flat cable 2, 3 Insulation sheet 4 Metal foil conductor 5 Covered electric wire 6 Composite flexible electric wire body 7 Fixed body 8 Moving body 9 Cylindrical body

Claims (3)

  The cross-section of the belt-shaped flat cable sandwiched between the metal foil conductors by two insulating sheets made of synthetic resin is bent in an arc shape, and a plurality of covered electric wires are arranged along the longitudinal direction of the bent inner surface, A composite flexible electric wire body, wherein a part of the plurality of covered electric wires is bonded to the inner surface of the curved surface. The against the flat cable and the plurality of coated electric wires, the composite flexible wire of claim 1, wherein the coated collectively cylindrical body having flexibility made of a synthetic resin.   The composite flexible electric wire body according to claim 2, wherein the cylindrical body has a flat cross section.

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