JP5330792B2 - Flat cable - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To prevent a flat cable from being twisted. <P>SOLUTION: The flat cable 10 includes: a plurality of collective cores 12 to 22 made by twisting together a plurality of insulating coated cores 42; at least one of tensile strength bodies 24, 26 that are made by twisting together a plurality of metal individual wires 44; a cable body 30 made of the collective cores 12 to 22 and tensile strength bodies 24, 26 that are parallely disposed; and a protection layer 40 that is coated with the cable body 30 and formed of a synthetic resin, wherein the tensile strength bodies 24, 26 have substantially polygonal or substantially elliptical cross sections in the direction substantially perpendicular to the longitudinal direction (X direction) of the cable. <P>COPYRIGHT: (C)2010,JPO&amp;INPIT

Description

  The present invention relates to a flat cable, and more particularly to a flat cable used for a moving device such as an elevator.

As a power supply or control cable for a moving apparatus such as an elevator or a crane, for example, a flat cable that is used while being suspended in the vertical direction is used. In particular, in the case of a multi-core cable including a large number of wire cores, a flat cable is often used because it is easier to bend than a round cable and saves space when winding the cable. Patent Literature 1 and Patent Literature 2 describe a flat cable used for a moving device such as an elevator or a crane.
JP 2002-205887 A JP-A-5-227623

  By the way, the flat cable used for moving apparatuses, such as an elevator, is installed so that the movement of moving apparatuses, such as an elevator, may follow. If the flat cable is twisted when laying the flat cable or moving a moving device such as an elevator, the track of the flat cable may change when the moving device such as an elevator moves. As a result, the flat cable may be damaged by contact with, for example, a structure in an elevator premises.

  Therefore, an object of the present invention is to provide a flat cable that can prevent twisting.

The flat cable according to the present invention includes a plurality of assembly wire cores obtained by twisting a plurality of insulation-coated wire cores and at least one strength member obtained by twisting a plurality of metal strands, and the assembly wire cores. And a cable body arranged in parallel with each other, and a protective layer coated with the cable body and formed of a synthetic resin, the strength body being substantially orthogonal to the longitudinal direction of the cable The cross section in the direction is formed by applying a compressive force to a substantially polygonal cross section or a substantially oval cross section by plastic working .

  In the flat cable according to the present invention, the strength member is formed such that the cross section is formed in a substantially rectangular cross section, and the long side of the rectangular cross section is in the longitudinal direction of the cross section substantially orthogonal to the cable longitudinal direction in the cable body. It is preferable that they are arranged substantially in parallel.

  In the flat cable according to the present invention, it is preferable that the strength member is formed in a spiral shape along the longitudinal direction of the cable.

  According to the flat cable having the above-described configuration, the twist of the tension member is suppressed, so that the twist of the flat cable can be prevented.

  Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. FIG. 1 is a diagram showing a configuration of a flat cable 10, FIG. 1 (a) is a plan view, and FIG. 1 (b) is a cross-sectional view in the AA direction in FIG. 1 (a). The flat cable 10 includes a cable main body 30 having aggregated wire cores 12 to 22 and strength members 24 and 26, and a protective layer 40 that covers the cable main body 30.

  The cable main body 30 is formed by arranging a plurality of assembly wire cores 12 to 22 including a plurality of insulation-coated wire cores 42 and at least one strength members 24 and 26 in parallel. The cable main body 30 is not limited to the arrangement configuration of the assembly wire cores 12 to 22 and the strength members 24 and 26 shown in FIG. For example, the cable body 30 is configured such that the strength members 24 are disposed on the assembly wire core 12 side, the strength bodies 26 are disposed on the assembly wire core 22 side, and the strength bodies 24 and 26 are disposed outside the cable body 30. May be formed. The cable body 30 shown in FIG. 1 is formed by arranging a plurality of assembly wire cores 12 to 22 and at least one strength member 24, 26 in parallel in one row, but is limited to one row. Instead, it may be arranged in a plurality of rows such as two rows.

  The assembly wire cores 12 to 22 are formed by twisting a plurality of insulation-coated wire cores 42. The collective cores 12 to 22 are formed, for example, by twisting five insulating coated cores 42 together. Of course, the number of the insulation coating wire cores 42 constituting the assembly wire cores 12 to 22 is not limited to five. For example, Z twist and S twist are used for the method of twisting the insulating coated core 42.

  The insulation-coated core 42 is formed by coating a plurality of annealed copper wires, tin-plated annealed copper wires, aluminum wires or the like with an insulating material. Further, the insulation-coated wire core 42 may be provided with an inclusion as a spacer (not shown) at substantially the center thereof, and a copper wire or the like may be twisted around the inclusion. For example, a lead wire for power supply or a twisted pair wire for communication is used for the insulation coated core 42.

  The plurality of collective cores 12 to 22 are arranged in parallel. In FIG. 1A and FIG. 1B, the cable body 30 is composed of six assembly wire cores 12 to 22, but the number of assembly wire cores constituting the cable body 30 is limited to six. It will never be done.

  In order to improve the twist balance of the flat cable 10, the assembly wire cores 12 to 22 are preferably arranged by combining the S strand and Z strand assembly wires 12 to 22. More preferably, the plurality of assembly wire cores 12 to 22 are arranged in parallel so that the twisting direction of the assembly wire cores 12 to 22 is symmetric with respect to the central axis of the flat cable 10. As shown in FIGS. 1 (a) and 1 (b), the assembly cable cores 12, 16, and 20 are S-twisted and the assembly cable cores 14, 18, and 22 are Z-twisted. The collective line cores 12 to 22 are arranged in parallel symmetrically with respect to the central axis.

  The strength members 24 and 26 are formed by twisting the metal wires 44 and function as tension members that reinforce the flat cable 10. The strength members 24 and 26 are formed by, for example, S-twisting or Z-twisting a plurality of metal strands 44. For the strength members 24 and 26, for example, a metal wire cable in which metal strands 44 such as a stainless steel wire, a mild steel wire, and a hard steel wire are twisted together can be used.

  In order to improve the torsional balance of the flat cable 10, the strength members 24 and 26 are preferably arranged in combination with the cable body 30 with the S twist strength member 24 and the Z twist strength member 26. In addition, it is more preferable that the strength members 24 and 26 are arranged in parallel so that the twisting directions of the strength members 24 and 26 are symmetrical. As shown in FIGS. 1 (a) and 1 (b), the tensile body 24 is made of S-strand and the tensile body 26 is made of Z-twist, so that the tensile body is symmetrical with respect to the central axis of the flat cable 10. 24 and 26 are arranged. Of course, it suffices that at least one strength member is provided in the cable body 30.

  The protective layer 40 is covered by the cable body 30 and has a function of protecting the assembly wire cores 12 to 22 and the strength members 24 and 26. The protective layer 40 is covered with the cable body 30 by, for example, extruding a synthetic resin. For the synthetic resin, for example, vinyl chloride resin, chloroprene rubber or the like is used.

  Here, in the strength members 24 and 26, a cross section in a direction substantially orthogonal to the cable longitudinal direction (X direction) is formed into a substantially polygonal cross section or a substantially oval cross section. The substantially polygonal cross section may be a substantially triangular cross section such as a substantially triangular cross section, a substantially square cross section, or a substantially star cross section, and the substantially oval cross section may be a substantially oval cross section such as a substantially oval cross section. The cross-sectional shape in the direction substantially orthogonal to the longitudinal direction (X direction) may be any non-circular cross-sectional shape other than the substantially circular cross-section. Moreover, when making the cross-sectional shape of the strength members 24 and 26 into a substantially square cross section, not only a substantially square cross section but also a substantially rectangular cross section may be used.

  In the tension members 24 and 26 having a substantially circular cross section in a direction substantially orthogonal to the cable longitudinal direction (X direction), even if the strength members 24 and 26 are twisted, the twist is determined by visual observation. Is difficult. On the other hand, by making the cross sections of the strength members 24 and 26 into a substantially polygonal cross section or a substantially oval cross section, the outer peripheral corners (edges) are rotated and reversed, so that the strength members 24 can be easily observed by visual observation. , 26 can be detected, and the tensile bodies 24, 26 in which the twist has occurred can be corrected or removed on the production line of the flat cable 10.

  Further, in the strength members 24 and 26 having a substantially circular cross section in a direction substantially orthogonal to the cable longitudinal direction (X direction), the adhesive strength with the protective layer 40 is reduced, and the strength members 24 and 26 slip. As a result, the strength members 24 and 26 may rotate and twist may occur. On the other hand, since the corners (edges) of the outer periphery are constrained by the protective layer 40 by making the cross sections of the tensile bodies 24, 26 into a substantially polygonal cross section or a substantially oval cross section, the tensile bodies 24, 26 Twisting is suppressed.

  The tensile body has a substantially rectangular cross section in a direction substantially orthogonal to the cable longitudinal direction (X direction), and the long side of the rectangular cross section is substantially orthogonal to the cable longitudinal direction (X direction) in the cable body 30. It is preferable to be arranged substantially parallel to the longitudinal direction of the cross section in the direction. FIG. 2 is a cross-sectional view showing a configuration of a flat cable 10a having strength members 24a and 26a having a substantially rectangular cross section in a direction substantially orthogonal to the cable longitudinal direction (X direction). As shown in FIG. 2, the strength members 24a and 26a are preferably arranged with the long side of the rectangular cross section of the strength members 24a and 26a oriented substantially parallel to the long side of the flat cable 10a.

  In the strength members 24a and 26a having a substantially rectangular cross section in a direction substantially orthogonal to the cable longitudinal direction (X direction), the rigidity is lower in the short direction (short side direction) of the substantially rectangular cross section. In the longitudinal direction (long side direction), the rigidity becomes higher. Therefore, the strength members 24a and 26a have the long side of the rectangular cross section with respect to the cable longitudinal direction (X direction) of the cable body 30 so that the longitudinal direction of the substantially rectangular cross section is the cable width direction (Y direction). Bending deformation (bending deformation in the Z direction) can be suppressed by arranging it in parallel with the width direction (Y direction) of the cable, which is the longitudinal direction of the cross section in a substantially orthogonal direction, so that twisting of the strength members 24a and 26a is suppressed. Is done.

  Furthermore, it is preferable that the strength members 24 and 26 are formed in a spiral shape such as a spiral shape at a predetermined pitch along the cable longitudinal direction (X direction). By forming the strength members 24 and 26 in a spiral shape such as a spring shape, the contact area with the protective layer 40 becomes larger, so that twisting of the strength members 24 and 26 is suppressed. In addition, it is preferable that the spiral pitch of the strength members 24 and 26 is formed at a pitch longer than other wire cores in the cable.

  In order to form the cross sections of the strength members 24 and 26 into a substantially polygonal cross section or a substantially oval cross section, a plurality of twisted metal strands 44 are plastically processed using dies, rolls, etc. It can be formed into a substantially oval cross section.

  For example, a cross-section of the strength members 24 and 26 is substantially obtained by drawing a round metal wire rope in which a plurality of metal strands 44 are twisted into a circular cross-section by S twist or Z twist using a square die. It can be a polygonal cross section. In addition, the round metal wire rope is pressed against a roll having a square groove and roll-formed, so that the round metal wire rope is square-shaped and the cross sections of the strength members 24 and 26 are substantially polygonal cross sections. It can be.

  In this way, the cross section of the strength members 24 and 26 is formed into a substantially polygonal cross section or a substantially oval cross section by applying a compressive force by drawing or roll forming, so that it is inherent in the round metal wire rope. Twist is reduced, and twist of the strength members 24 and 26 is suppressed. Further, when the tensile strength members 24 and 26 are formed in a spiral shape such as a spring shape along the longitudinal direction of the cable, a spiral processing of a general metal material can be used. By twisting a round metal wire rope twisted with metal strands and twisting it in a spiral shape, a stronger habit can be given, so the twist inherent in the round metal wire rope is further reduced. Further, the twisting of the strength members 24 and 26 is suppressed.

  The tensile body is made by twisting aramid fibers such as Kevlar into a linear shape, a carbon fiber cable formed by twisting carbon fibers into a linear shape, and twisting polyamide fibers such as nylon. It is preferable to use a polyamide fiber cable or the like formed in a shape. This is because an aramid fiber cable or the like has high tensile strength and lower torsional rigidity than a metal wire rope. As a result, in metal wire ropes, twisting tends to remain after twisting as a wire due to the rigidity of the metal itself, but in the case of aramid fiber cables, etc., the rigidity is lower than that of metal wire ropes. Power is lowered. Therefore, by forming the strength member with an aramid fiber cable or the like, twisting of the strength member can be suppressed and twisting of the flat cable can be prevented.

  Further, the tensile body may be formed using a resin rod or a reinforced fiber resin rod. The tensile body is formed of, for example, a resin rod formed of a synthetic resin such as an epoxy resin, or a reinforcing fiber resin rod obtained by reinforcing a synthetic resin such as an epoxy resin with a reinforcing fiber such as glass fiber, carbon fiber, or aramid fiber. . This is because a reinforced fiber resin rod using such a resin rod or a fiber reinforced composite material (FRP) does not have twisting force because it is not twisted together during production unlike a metal wire rope. Moreover, it is because a tensile strength can be made higher by forming a tensile body with a reinforced fiber resin rod. A general synthetic resin molding method or a fiber-reinforced composite material molding method can be used for such a tensile strength molding method. Note that the strength member formed of a resin rod or a reinforced fiber resin rod preferably has a non-circular cross section such as a substantially polygonal cross section or a substantially oval cross section in a direction substantially orthogonal to the cable longitudinal direction. .

  In addition, although the case where it applied to a flat cable was demonstrated in the said structure, of course, you may apply to the tension body used for a round cable.

  As described above, according to the above configuration, the plurality of assembly wire cores include a plurality of assembly wire cores obtained by twisting a plurality of insulation-coated wire cores and at least one strength member obtained by twisting a plurality of metal strands. And a cable main body arranged in parallel with at least one strength member, and a protective layer coated with the cable body and formed of a synthetic resin, the strength member being substantially orthogonal to the cable longitudinal direction Since the cross section is formed into a substantially polygonal cross section or a substantially oval cross section, the twist of the tensile strength body is discriminated by visual inspection or the like when the flat cable is manufactured, and the twist of the tensile strength body can be corrected. In the members constituting the flat cable, the strength member has the highest rigidity. Therefore, the twisting of the strength member can be suppressed to prevent the twisting of the flat cable.

  According to the above configuration, since the cross section in the direction substantially orthogonal to the cable longitudinal direction is formed into a substantially polygonal cross section or a substantially oval cross section, the strength member is constrained by the protective layer at the corners of the strength body. . In addition to the adhesive force between the strength member and the protective layer, the corners of the strength member are constrained by the protective layer, so that twisting of the strength member is suppressed, so that twisting of the flat cable can be prevented.

  According to the above-described configuration, the tensile body is applied to the longitudinal direction of the cable by a plastic working with a compressive force such as a drawing process using a square die or a roll forming process for pressing a roll having a square groove. Since the cross section in a substantially orthogonal direction is formed into a substantially polygonal cross section or a substantially oval cross section, even if the twist was inherent before the plastic working, the twist of the tensile strength body is suppressed by the plastic working with a compressive force, The twist of the flat cable can be prevented.

  According to the above configuration, the tensile body has a substantially rectangular cross section formed in a substantially rectangular cross section with respect to the cable longitudinal direction, and the long side of the rectangular cross section is substantially perpendicular to the cable longitudinal direction in the cable body. Therefore, the bending deformation of the flat cable is suppressed, and the flat cable can be prevented from being twisted.

  According to the above configuration, since the tensile body has low torsional rigidity by being formed of an aramid fiber, carbon fiber, polyamide fiber, resin rod or reinforced fiber resin rod, the twist of the tensile body is suppressed, The twist of the flat cable can be prevented.

In embodiment of this invention, it is a figure which shows the structure of a flat cable. In embodiment of this invention, it is sectional drawing which shows the structure of the flat cable which has a tensile strength body in which the cross section of a substantially orthogonal direction is a substantially rectangular cross section with respect to a cable longitudinal direction (X direction).

Explanation of symbols

10, 10a Flat cable 12-22 Assembly wire core 24, 24a, 26, 26a Strength member 30 Cable body 40 Protective layer 42 Insulation coated wire core 44 Metal element wire

Claims (3)

A flat cable,
A plurality of assembly wire cores obtained by twisting a plurality of insulation-coated wire cores and at least one strength member obtained by twisting a plurality of metal strands, and the assembly wire cores and the strength members are provided in parallel. A cable body arranged and
A protective layer coated with the cable body and formed of synthetic resin;
With
In the flat cable, the tensile body is formed by applying a compressive force to a substantially polygonal cross section or a substantially oval cross section in a direction substantially orthogonal to the cable longitudinal direction by plastic working . The flat cable according to claim 1,
The tensile body is formed such that the cross section is a substantially rectangular cross section,
A flat cable characterized in that the long side of the rectangular cross section is arranged so as to be substantially parallel to the longitudinal direction of the cross section substantially orthogonal to the longitudinal direction of the cable in the cable body. The flat cable according to claim 1 or 2,
The flat cable is characterized in that the tensile body is formed in a spiral shape along the longitudinal direction of the cable.

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