JP2024040574A - cable - Google Patents

Abstract

To provide a cable in which terminal processability is improved while maintaining durability to twisting.SOLUTION: A cable 1 comprises: a pair of first electric wires 2; a multicore wire 8 having a twisted-pair wire 4 formed by stranding a pair of second electric wires 3; and a tape member 6 which is spirally wound around a stranded body 5 formed by stranding the pair of first electric wires 2 and the multicore wire 8, where the first electric wires 2 contact with each other, and each of the first electric wires 2 and the multicore wire 8 contact with each other, a stranding direction of the stranded body 5 and a winding direction of the tape member 6 are the same direction. The cable also comprises: a linear first intervention 91 which is provided in a valley part between the first electric wires 2 adjacent in a cable circumferential direction; and a pair of linear second interventions 92 which are provided in a valley part between the multicore wire 8 and one and the other first electric wires 2 adjacent in a cable circumferential direction, where the tape member 6 contacts all of the first electric wires 2 and the multicore wire 8 and the first intervention 91 and second interventions 92 which constitute the stranded body 5.SELECTED DRAWING: Figure 2

Description

FIELD OF THE INVENTION The present invention relates to cables.

In recent years, electric braking devices have been used in vehicles such as automobiles. As electric braking devices, electro-mechanical brakes (EMB) and electric parking brakes (EPB) are known. In addition, in recent years, vehicles are equipped with sensors such as ABS (Anti-lock Brake System) sensors that detect the rotational speed of the wheels while driving, air pressure sensors that detect tire air pressure, and temperature sensors. There are many things.

Therefore, the signal lines for the sensors mounted on the wheels, the signal lines for controlling the electromechanical brakes, and the power supply lines that supply power to the electric motors for the electromechanical brakes and electric parking brakes are placed in a common sheath. The wheel side and the vehicle body side are connected using a housed cable.

In Patent Document 1, a tape member is spirally wrapped around a twisted combination of a pair of first electric wires for power transmission and a twisted pair of wires made of a second electric wire for signal transmission. A cable with a surrounding sheath is disclosed. In Patent Document 1, by making the twisting direction of the twisted wire pair, the twisting direction of the twisted combination, and the winding direction of the tape member in the same direction, the electric wire can be easily unraveled, the terminal processability is improved, and the wire is prevented from being twisted. Improves durability.

JP2017-59521A

However, if the twisting direction of the twisted wire pair, the twisting direction of the twisted body, and the winding direction of the tape member are set in the same direction, the tape member and the sheath tend to get into the gap (valley portion) between adjacent electric wires. This intruded portion is difficult to cut out with a tool or the like, making it difficult to remove the sheath and tape member, which may result in poor terminal workability.

SUMMARY OF THE INVENTION Therefore, an object of the present invention is to provide a cable that maintains durability against twisting and has improved terminal processability.

In order to solve the above problems, the present invention provides a multicore wire having a pair of twisted wires in which a pair of first electric wires and a pair of second electric wires having an outer diameter smaller than the first electric wires are twisted together. a tape member spirally wound around a twisted body formed by twisting the pair of first electric wires and the multi-core wire; and an outer sheath covering the outer periphery of the tape member. , the pair of first electric wires are in contact with each other, each of the first electric wires and the multi-core wire are in contact with each other, and the twisting direction of the twisted body and the tape The winding direction of the member is the same direction, and the linear first interposition provided in the valley between the first electric wires adjacent in the circumferential direction of the cable, and the multi-core wire adjacent in the circumferential direction of the cable, and a pair of linear second intervening devices provided respectively in valley portions between the other first electric wires, and the tape member includes all the first electric wires and the second wires constituting the twisted body. A cable is provided that is in contact with an electrical wire and the first intervening and the second intervening.

According to the present invention, it is possible to provide a cable with improved terminal workability while maintaining durability against twisting.

FIG. 1 is a block diagram showing the configuration of a vehicle using a cable according to an embodiment of the present invention. FIG. 2 is a sectional view showing a cross section perpendicular to the longitudinal direction of a cable according to an embodiment of the present invention. FIG. 7 is a sectional view showing a cross section perpendicular to the longitudinal direction of a cable according to a modified example of the present invention. FIG. 7 is a sectional view showing a cross section perpendicular to the longitudinal direction of a cable according to a modified example of the present invention.

[Embodiment]
Embodiments of the present invention will be described below with reference to the accompanying drawings.

FIG. 1 is a block diagram showing the configuration of a vehicle 100 using a cable 1 according to the present embodiment. As shown in FIG. 1, a vehicle 100 is equipped with an electric parking brake (hereinafter referred to as EPB) 101 as an electric braking device.

The EPB 101 includes an EPB electric motor 101a and an EPB control section 101b. The EPB electric motor 101a is mounted on the wheel 102 of the vehicle 100. EPB control section 101b is installed in ECU (electronic control unit) 103 of vehicle 100. Note that the EPB control section 101b may be installed in a control unit other than the ECU 103, or may be installed in a dedicated hardware unit.

Although not shown, the EPB electric motor 101a is provided with a piston to which a brake pad is attached.By moving the piston by the rotational drive of the EPB electric motor 101a, the brake pad is moved to the wheel 102. It is configured to be pressed against the disc rotor to generate braking force. A pair of first electric wires 2 are connected to the EPB electric motor 101a as power lines for supplying drive current to the EPB electric motor 101a.

The EPB control unit 101b outputs a drive current to the EPB electric motor 101a for a predetermined period of time (for example, 1 second) when the parking brake activation switch 101c is operated from the OFF state to the ON state when the vehicle 100 is stopped. , the brake pad is pressed against the disc rotor of the wheel 102, and the wheel 102 is configured to generate a braking force. Furthermore, when the parking brake activation switch 101c is operated from an on state to an off state, or when an accelerator pedal is depressed, the EPB control unit 101b outputs a drive current to the EPB electric motor 101a, and brakes the EPB electric motor 101a. The pad is configured to be separated from the disc rotor of the wheel 102 to release the braking force on the wheel 102. In other words, the operating state of the EPB 101 is maintained after the parking brake activation switch 101c is turned on until the parking brake activation switch 101c is turned off or the accelerator pedal is depressed. Note that the parking brake activation switch 101c may be a lever-type or pedal-type switch.

Further, the vehicle 100 is equipped with an ABS device 104. The ABS device 104 includes an ABS sensor 104a and an ABS control section 104b.

The ABS sensor 104a detects the rotational speed of the wheel 102 while the vehicle is running, and is mounted on the wheel 102. The ABS control unit 104b is installed in the ECU 103 and controls a braking device based on the output of the ABS sensor 104a to control the braking force of the wheels 102 so that the wheels 102 are not locked during a sudden stop. A pair of second electric wires 3 are connected to the ABS sensor 104a as signal lines.

The cable 1 according to the present embodiment is a cable 1 in which the first electric wire 2 and the second electric wire 3 are collectively covered with an external sheath 7 (see FIG. 2). The cable 1 extending from the wheel 102 side is connected to a wire group 107 in a relay box 106 provided in the vehicle body 105, and is connected to the ECU 103 and a battery (not shown) via the wire group 107.

Although only one wheel 102 is shown in FIG. 1 to simplify the drawing, the EPB electric motor 101a and the ABS sensor 104a may be mounted on each wheel 102 of the vehicle 100, for example, It may be mounted only on the front wheels or only the rear wheels of the vehicle 100.

(cable 1)
FIG. 2 is a sectional view showing a cross section perpendicular to the longitudinal direction of the cable 1 according to the present embodiment. As shown in FIG. 2, the cable 1 is a multicore wire having a pair of twisted wires 4 in which a pair of first wires 2 and a pair of second wires 3 having an outer diameter smaller than the first wires 2 are twisted together. 8, a tape member 6 wound spirally around a twisted body 5 in which a pair of first electric wires 2 and a twisted wire pair 4 are twisted together, and a tape member 6 provided to cover the periphery of the tape member 6. An external sheath 7 is provided.

In this embodiment, the first electric wire 2 is a power line (that is, an electric wire for power transmission) for supplying a drive current to the EPB electric motor 101a mounted on the wheel 102 of the vehicle 100. Further, the second electric wire 3 is a signal line for the ABS sensor 104a mounted on the wheel 102 (that is, an electric wire for signal transmission).

(First electric wire 2)
The first electric wire 2 is constructed by covering a first conductor 21 made of twisted wires of good conductivity such as copper with a first insulator 22 made of an insulating resin composition such as cross-linked polyethylene. Ru.

The wire used for the first conductor 21 may have a diameter of 0.05 mm or more and 0.30 mm or less. If a wire with a diameter of less than 0.05 mm is used, sufficient mechanical strength may not be obtained and the bending resistance may be reduced; if a wire with a diameter of more than 0.30 mm is used, the flexibility of the cable 1 may be reduced. may decrease.

The outer diameter of the first conductor 21 of the first electric wire 2 and the thickness of the first insulator 22 may be appropriately set according to the required magnitude of the drive current. In this embodiment, considering that the first electric wire 2 is a power line for supplying a drive current to the EPB electric motor 101a, the outer diameter of the first conductor 21 is set to 1.5 mm or more and 3.0 mm or less. At the same time, the outer diameter of the first electric wire 2 was set to 2.0 mm or more and 4.0 mm or less.

(Multi-core wire 8)
The second electric wire 3 is constructed by covering a second conductor 31 made of twisted wires of good conductivity such as copper with a second insulator 32 made of an insulating resin composition such as cross-linked polyethylene. Ru. As with the first conductor 21, the wire used for the second conductor 31 may have a diameter of 0.05 mm or more and 0.30 mm or less.

The twisting pitch of the twisted wire pair 4 is preferably set to such an extent that no unnecessary load is applied to the second electric wire 3, taking into consideration the outer diameter of the second electric wire 3. Here, the twisting pitch of the twisted wire pair 4 was set to about 30 mm, but the twisting pitch of the twisted wire pair 4 is not limited to this. Note that the twist pitch of the twisted wire pair 4 is an interval along the longitudinal direction of the twisted wire pair 4 at which any second electric wire 3 is at the same position in the circumferential direction of the twisted wire pair 4.

The multi-core wire 8 is constructed by covering the twisted wire pair 4 with an inner sheath 81 . The inner sheath 81 is made of urethane resin, for example. In this embodiment, the outer diameter of the multi-core wire 8 is larger than the outer diameter of the first electric wire 2.

(Twisted body 5)
The twisted body 5 is constructed by twisting a pair of first electric wires 2 and a multi-core wire 8 together. In this embodiment, the pair of first electric wires 2 are brought into contact with each other, and each of the first electric wires 2 is brought into contact with the multicore wire 8. At this time, at least a portion of the multi-core wire 8 is arranged in the valley portion between the pair of first electric wires 2.

In this embodiment, in addition to the pair of first electric wires 2 and the multi-core wire 8, three linear intervening wires 9 are also twisted together to form the twisted body 5. Therefore, the twisting direction and twisting pitch of the interposer 9 are the same as the twisting direction and twisting pitch of the twisted body 5. Details of the intervention 9 will be described later.

By the way, the EPB 101 basically supplies a drive current to the EPB electric motor 101a when the vehicle 100 is stopped. On the other hand, the ABS sensor 104a is used when the vehicle 100 is running, and the ABS sensor 104a is not used when the first electric wire 2 is supplied with the drive current. Therefore, in this embodiment, the shield conductor provided around the twisted wire pair 4 (multi-core wire 8) is omitted. By omitting the shield conductor, the outer diameter of the cable 1 can be made smaller than in the case where a shield conductor is provided, and it is also possible to reduce the number of parts and reduce costs.

Although a case is described here in which the first electric wire 2 supplies a drive current to the EPB electric motor 101a, the first electric wire 2 is connected to an electromechanical brake (hereinafter referred to as EMB) provided on the wheel 102, for example. may be used to supply drive current to an electric motor of In this case, since current will flow through the first electric wire 2 even while the vehicle 100 is running, a shield is placed around the twisted pair wires 4 (multi-core wires 8) to suppress malfunction of the ABS device 104 due to noise. It can be said that it is desirable to provide a conductor.

In addition, although the case where the second electric wire 3 is a signal line for the ABS sensor 104a is explained here, the second electric wire 3 can be used to detect other sensors provided on the wheel 102, such as a temperature sensor or tire air pressure. It may be a signal line used for an air pressure sensor, etc., a damper line used to control a vibration damping device of the vehicle 100, or a signal line for EMB control (such as a CAN cable). It's okay. Even if the first electric wire 2 is for supplying drive current to the EPB electric motor 101a, when the second electric wire 3 is used while the vehicle 100 is stopped, the purpose is to suppress malfunction due to noise. In addition, it is desirable to provide a shield conductor around the twisted pair wires 4 (multi-core wires 8).

The outer diameter of the entire twisted body 5 is, for example, about 5 mm to 9 mm. The twisting pitch of the twisted body 5 is preferably set to such an extent that unnecessary loads are not applied to the first electric wire 2 and the twisted wire pair 4, taking into consideration the outer diameter of the twisted body 5. Here, the twisting pitch of the twisted body 5 was set to about 60 mm, but the twisting pitch of the twisted body 5 is not limited to this. Note that the twist pitch of the twisted body 5 is an interval along the longitudinal direction of the twisted body 5 at which arbitrary first electric wires 2 or multi-core wires 8 are at the same position in the circumferential direction of the twisted body 5.

(Tape member 6)
A tape member 6 is spirally wound around the twisted body 5. The tape member 6 is in contact with all of the first electric wires 2, multi-core wires 8, and interpositions 9 (first interposition 91 and second interposition 92 described later) that constitute the twisted body 5. The tape member 6 is interposed between the twisted body 5 and the outer sheath 7, and serves to reduce the friction between the twisted body 5 and the outer sheath 7 during bending. That is, by providing the tape member 6, the friction between the first electric wire 2 or the multi-core wire 8 and the outer sheath 7 is reduced without using a lubricant such as talc powder as in the conventional case, and the first It becomes possible to reduce the stress applied to the electric wire 2 and the multi-core wire 8 and improve the bending resistance.

As the tape member 6, it is desirable to use a tape member that is easily slippery (has a small coefficient of friction) on the first insulator 22 of the first electric wire 2 and the inner sheath 81. More specifically, as for the tape member 6, the coefficient of friction (static friction coefficient) between the tape member 6 and the first insulator 22 or the inner sheath 81 is the same as that between the outer sheath 7 and the first insulator 81 when the tape member 6 is not provided. It is preferable to use a member having a smaller coefficient of friction (static friction coefficient) between the insulator 22 and the inner sheath 81.

In this embodiment, the tape member 6 is a mixture of first fibers having a melting point higher than the extrusion temperature of the outer sheath 7 and second fibers having a melting point lower than the extrusion temperature of the outer sheath 7. It is made of non-woven fabric made by More specifically, the tape member 6 is made by mixing high melting point PET (polyethylene terephthalate) fibers as the first fibers and low melting point PET (polyethylene terephthalate) fibers as the second fibers at a predetermined ratio. It is made of non-woven fabric made by

The melting point of low melting point PET fibers is lower than that of high melting point PET fibers. Furthermore, the melting point of the low melting point PET fiber is lower than the extrusion temperature of the outer sheath 7. Further, the melting point of the high melting point PET fiber is higher than the extrusion temperature of the outer sheath 7. Note that the extrusion molding temperature of the outer sheath 7 refers to the temperature at which the outer sheath 7 is coated around the tape member 6 by extrusion-molding. For example, when PET with a melting point of about 250 degrees is used as the high melting point PET fiber and urethane resin with an extrusion temperature of about 230 degrees is used as the outer sheath 7, the low melting point PET fiber has a melting point of about 220 degrees. Preferably, PET fibers are used.

By including low melting point PET fibers in the material of the tape member 6, when covering the tape member 6 with the outer sheath 7 by extrusion molding, the low melting point PET fibers that are a part of the components of the tape member 6 are extruded. It softens or melts depending on the temperature during formation and sticks to the inner peripheral surface of the outer sheath 7. Therefore, the tape member 6 can be integrated with the outer sheath 7 without separately applying an adhesive to the tape member 6. Note that if the content of the low-melting point PET fiber is too large, the bond between the tape member 6 and the outer sheath 7 may become too strong and the flexibility of the cable 1 may decrease. It is necessary to use a mixture of not only low melting point PET fibers but also high melting point PET fibers.

The content of the low melting point PET fibers (total mass of low melting point PET fibers in the tape member 6/mass of the tape member 6) is preferably 10% by mass or more and 90% by mass or less. If the content of the low melting point PET fiber is less than 10% by mass, the tape member 6 may be difficult to stick to the inner circumferential surface of the outer sheath 7, and if the content of the low melting point PET fiber is greater than 90% by mass. This is because the flexibility of the cable 1 may be reduced. In addition, from the viewpoint of further suppressing these fears, the content of the low melting point PET fiber is more preferably 20% by mass or more and 80% by mass or less. Furthermore, in order to suppress fuzzing when removing the tape member 6, the lengths of the high melting point PET fibers and the low melting point PET fibers are preferably 5 mm or less.

Note that the second fiber with a low melting point is not limited to the low melting point PET fiber, and may be any other fiber as long as it softens or melts at the extrusion forming temperature of the outer sheath 7 and sticks to the inner peripheral surface of the outer sheath 7. It can be anything. Further, in this embodiment, the tape member 6 only needs to contain two types of fibers having different melting points, and may be formed by mixing three or more types of fibers.

The tape member 6 is spirally wound around the twisted body 5 so that a portion of the tape member 6 in the width direction (direction perpendicular to the longitudinal direction and the thickness direction of the tape member 6) overlaps. The width at which the tape members 6 overlap is, for example, 1/4 or more and 1/2 or less of the width of the tape members 6. The width of the tape member 6 may be such that the tape member 6 is not wrinkled when the tape member 6 is wound, and if the outer diameter of the twisted body 5 as a whole becomes smaller, a narrower tape member 6 is used. good. Specifically, when the outer diameter of the twisted body 5 is 5 mm to 9 mm, the width of the tape member 6 may be approximately 20 mm to 50 mm.

The winding pitch of the tape member 6, i.e., the interval along the longitudinal direction at which the tape members 6 are at the same circumferential position (for example, the interval between one end in the width direction) depends on the width and overlap width of the tape member 6 (the winding angle of the tape member 6), and in this case is approximately 40 mm at most. Here, the winding pitch of the tape member 6 is approximately 30 mm, but the winding pitch of the tape member 6 is not limited to this. Note that if the width of the tape member 6 is increased and the winding pitch is increased, the tape member 6 approaches a state in which it is vertically aligned, and the cable 1 loses flexibility and becomes difficult to bend. For this reason, it is desirable to set the winding pitch of the tape member 6 to 40 mm or less.

(External sheath 7)
An outer sheath 7 is provided around the tape member 6. The outer sheath 7 is made of, for example, urethane resin. In this embodiment, the first electric wire 2 supplies a driving current to the EPB electric motor 101a, and since the time during which the driving current flows through the first electric wire 2 is relatively short, the first electric wire 2 is provided around the tape member 6. Although the shield conductor is omitted, a shield conductor may be provided between the tape member 6 and the outer sheath 7 or around the outer periphery of the outer sheath 7 depending on the use of the first electric wire 2.

(Twisting direction of twisted body 5, winding direction of tape member 6)
In the cable 1 according to the present embodiment, the twisting direction of the twisted wire pairs 4, the twisting direction of the twisted body 5, and the winding direction of the tape member 6 are the same. Note that the twist direction here refers to the direction in which the first electric wire 2 and the multi-core wire 8 extend from the other end to the one end when the cable 1 is viewed from one end (the side where the tape members 6 overlap). Refers to the direction of rotation. Note that the twisting direction of the twisted wire pair 4 is the direction in which the two second electric wires 3 are twisted together, and the twisting direction of the twisted combination 5 is the direction in which the first electric wire 2, the multi-core wire 8, and the intervening wire 9 are twisted together. This is the direction to match. Furthermore, the winding direction of the tape member 6 refers to the direction in which the tape member 6 rotates from the other end to the one end when the cable 1 is viewed from one end (the side where the tape members 6 overlap). say. In FIG. 2, the twisting direction of the twisted pair 4 is shown by a broken line arrow A, the twisting direction of the twisted body 5 is shown by a broken line arrow B, and the winding direction of the tape member 6 is shown by a broken line arrow C.

By making the twisting direction of the twisted body 5 and the winding direction of the tape member 6 the same, when twist is applied to the cable 1, the twisted body 5 and the tape member 6 open and close in synchronization. This makes it possible to improve durability against twisting.

Regarding this, for example, when the twisting direction of the twisted body 5 and the winding direction of the tape member 6 are opposite, when twist is applied to the cable 1 in the direction in which the twisted body 5 opens (the diameter of the twisted body 5 increases), Since the direction in which the twisted body 5 is twisted and the direction in which the tape member 6 is wound are opposite to each other, the tape member 6 ends up being closed (the diameter of the tape member 6 becomes smaller). At this time, the tape member 6 restrains the twisted body 5 from opening, and stress is applied to the twisted body 5, resulting in an excessive load on a portion of the pair of first electric wires 2 and the multi-core wire 8. I'll join in. Therefore, in this embodiment, the twisting direction of the twisted body 5 and the winding direction of the tape member 6 are the same, so that when the cable 1 is twisted, the twisted body 5 and the tape member 6 open in synchronization. I try to close it. This makes it possible to improve the durability of the cable 1 against twisting.

When the twisting pitch of the twisted body 5 is reduced, the cable 1 becomes easier to bend and its flexibility is improved, but there is no margin for twisting and the durability against twisting is reduced. Conversely, when the twisting pitch of the twisted body 5 is increased, the durability against twisting improves, but the flexibility decreases. In this embodiment, when twist is applied to the cable 1, the twisted body 5 and the tape member 6 can open and close in synchrony to disperse the load, so the twist pitch of the twisted body 5 can be reduced. Even when flexibility is improved, it is possible to ensure sufficient durability against torsion.

Note that if the twisting pitch of the twisted body 5 and the winding pitch of the tape member 6 are the same, the tape member 6 and the external sheath 7 will easily get between the electric wires (the first electric wire 2 and the multi-core wire 8). Although the details will be described later, in this embodiment, the interposition 9 is provided to suppress the tape member 6 and the outer sheath 7 from entering inward. In order to further suppress the intrusion of the twisted body 5, the twist pitch of the twisted body 5 may be made different from the winding pitch of the tape member 6 (specifically, the twist pitch of the twisted body 5 may be made smaller by 10% or more and 80% or less). desirable.

(Intervention 9)
As described above, by making the direction in which the twisted body 5 is twisted and the direction in which the tape member 6 is wound in the same direction, durability against twisting can be improved. However, if the twisting direction of the twisted body 5 and the winding direction of the tape member 6 are the same, the tape member 6 and the outer sheath 7 will be connected to the first It becomes easy to get between the electric wires 2 or between the first electric wire 2 and the multi-core wire 8. When the tape member 6 and the external sheath 7 get into between the first electric wires 2 or between the first electric wire 2 and the multi-core wire 8, it becomes difficult to cut out the part where they got in with a tool etc. It becomes difficult to remove the outer sheath 7 and the outer sheath 7, and the terminal processability deteriorates. Furthermore, there is also a risk that the cross-sectional shape of the twisted body 5 may become distorted, resulting in deterioration in appearance, or that the twisted body 5 becomes difficult to slip inside the tape member 6, resulting in reduced flexibility.

Therefore, in this embodiment, by providing one interposition 9 in each valley between the electric wires (the first electric wire 2 and the multi-core wire 8) that are adjacent to each other in the circumferential direction of the cable, The tape member 6 and the outer sheath 7 are prevented from entering the valley between the core wires 8). Thereby, it is possible to suppress deterioration in end workability, and suppress deterioration in appearance and deterioration in flexibility.

More specifically, the interposition 9 includes a linear first interposition 91 provided in the valley between the first electric wires 2 , a multi-core wire 8 adjacent to each other in the circumferential direction of the cable, and one and the other first electric wire 2 . A pair of linear second interpositions 92 are respectively provided in the valley portions between the two. The first interposer 91 and the second interposer 92 have a circular cross section perpendicular to the longitudinal direction, and are bundled and twisted together with the pair of first electric wires 2 and the multi-core wire 8 to form the twisted body 5. . The tape member 6 wrapped around the twisted body 5 is in contact with all the first electric wires 2 and multi-core wires 8 and the first intervening member 91 and the second intervening member 92 that constitute the twisted combined body 5 .

The outer diameters of the first interposer 91 and the second interposer 92 are determined according to the outer diameters of the first electric wire 2 and the multicore wire 8. In this embodiment, the outer diameters of the pair of second intervening members 92 are the same, and the outer diameters of the first intervening members 91 and the pair of second intervening members 92 are different. When the outer diameter of the multi-core wire 8 is larger than the outer diameter of the first electric wire 2, the outer diameter of the first interposer 91 is preferably smaller than the outer diameter of the second interposer 92. Conversely, when the outer diameter of the multi-core wire 8 is smaller than the outer diameter of the first electric wire 2, the outer diameter of the first interposer 91 is preferably larger than the outer diameter of the second interposer 92 (see FIG. 3). ). More preferably, when a circumscribed circle of the pair of first electric wires 2 and the multi-core wire 8 is assumed in a cross-sectional view perpendicular to the longitudinal direction of the cable, this circumscribed circle and an adjacent one forming a valley portion in which the intervening wire 9 is arranged. It is preferable to determine the outer diameters of the first interposer 91 and the second interposer 92 so as to contact the outer peripheral surfaces of the two electric wires (the first electric wire 2 and the multi-core wire 8). Thereby, the inner peripheral surface of the tape member 6 can be made closer to a circular shape in a cross section perpendicular to the longitudinal direction of the cable, and the tape member 6 and the outer sheath 7 can be easily removed using a tool or the like.

The first interposer 91 and the second interposer 92 are desirably made of a material that does not soften due to the heat generated when the outer sheath 7 is extruded. This is because when the first interposer 91 and the second interposer 92 are softened by the heat generated during extrusion molding of the outer sheath 7, the first interposer 91 and the second interposer 92 are damaged by the surrounding tape member 6, the first electric wire 2, and the multicore. This is because the cable 8 sticks to the wire 8, reducing the terminal processability and hindering the movement of the twisted body 5 with respect to the tape member 6 when the cable 1 is bent, making it difficult to bend the cable 1. When the tape member 6 containing the second fibers having a low melting point is used as in the present embodiment, sticking between the tape member 6 and the interposer 9 may be particularly likely to occur.

As the first interposer 91 and the second interposer 92, a high melting point resin composition such as a fluororesin or a crosslinked resin composition can be used. Since high melting point resin compositions such as fluororesins are relatively expensive, it is more preferable to use crosslinked resin compositions. As the crosslinked resin composition, inexpensive crosslinked polyethylene can be used. Polyethylene before crosslinking has a low melting point and will melt due to the heat generated when extruding the outer sheath 7, but by crosslinking, it is possible to suppress softening caused by the heat when extruding the outer sheath 7. In this way, by using crosslinked resin compositions as the first interposer 91 and the second interposer 92, it becomes possible to use a resin composition having a melting point lower than the extrusion molding temperature for the outer sheath 7 before crosslinking. Cost reduction is possible. Furthermore, by using a crosslinked resin composition as the first intervening material 91 and the second intervening material 92, even if the tape member 6 containing the second fibers having a low melting point is used, the tape member 6 and the intervening material 92 can be The occurrence of sticking can be suppressed.

Furthermore, by roughening the surfaces of the first interposer 91 and the second interposer 92, friction with surrounding members (the tape member 6, the first electric wire 2, and the multi-core wire 8) is suppressed, and the flexible You may try to improve it. In this case, the arithmetic mean roughness Ra of the surfaces of the first interposition 91 and the second interposition 92 is preferably 1 μm or more and 30 μm or less, more preferably 4 μm or more and 15 μm or less.

(Modified example)
In this embodiment, as the multi-core wire 8, the inner sheath 81 is provided around the twisted pair wire 4, but the present invention is not limited to this. May be omitted. In this case, the multi-core wire 8 is composed only of the twisted pair wires 4.

When the inner sheath 81 is omitted and the twisted wire pair 4 is used as is, as in the cable 1a, the twisting direction of the twisted wire pair 4, the twisting direction of the twisted body 5, and the winding direction of the tape member 6 are the same. It is desirable that the direction be

By making the twisting direction of the twisted wire pair 4 and the twisting direction of the twisted wire assembly 5 the same, when twisting the twisted wire assembly 5 together, by twisting the two second electric wires 3, the twisting direction is applied to the twisted wire pair 4. The twisted wire pair 4 and the first electric wire 2 are twisted together in the direction along the bending tendency. Therefore, when the cable 1 is bent, the pair of first electric wires 2 and the twisted wire pair 4 expand and contract in the longitudinal direction of the cable 1 in synchrony, making the cable 1 easier to bend. It becomes possible to improve sexuality.

In addition, in the cable 1a, since the twisted body 5 is formed by twisting the twisted wire pairs 4 in the direction along the bending tendency, if the outer sheath 7 and the tape member 6 are removed at the same time with a tool such as a stripping device, In addition, due to the bending tendency of the twisted wire pair 4, the first electric wire 2 and the twisted wire pair 4 are easily maintained in a twisted state. If the removal length of the outer sheath 7 is to be increased during terminal processing, the stripping operation is performed in multiple steps, but in the case of the cable 1, even after the stripping operation is performed once, the first electric wire 2 and the twisted wire pair 4 are Since the fibers are maintained in a twisted state, it is possible to easily perform multiple stripping operations.

In the cable 1a, since the twisting direction of the twisted wire pair 4 and the twisting direction of the twisted wire assembly 5 are the same, if the twisting pitch of the twisted wire pair 4 and the twisting pitch of the twisted wire assembly 5 are the same, the first electric wire 2 and The positional relationship of the second electric wires 3 is always the same in the longitudinal direction, and the appearance of the cable 1 may become distorted. Therefore, the twist pitch of the twisted wire pair 4 should be different from the twist pitch of the twisted body 5 (specifically, the twist pitch of the twisted body 5 should be 10% or more and 80% or less of the twist pitch of the twisted body 5). ) is desirable. If the twist pitch of the twisted wire pair 4 is made larger than the twist pitch of the twisted wire pair 4, the twist pitch of the twisted wire pair 4 may change when twisting the twisted wire pair 5. The pitch is desirably smaller than at least the twisting pitch of the twisted body 5.

Further, as in the cable 1b shown in FIG. 4, a further interposition 9 may be provided in the valley between the interposition 9 and the electric wire (the first electric wire 2 or the multi-core wire 8) adjacent to the interposition 9 in the circumferential direction. You may also do so. In the cable 1b, a third interposer 93 is provided in each valley between the pair of second interposers 92 and the multi-core wire 8. Although not shown, a further interposition 9 may be provided in the valley between the second interposition 92 and the first electric wire 2 or between the first interposition 91 and the first electric wire 2.

Further, in this embodiment, a case has been described in which the interposer 9 is made of a resin composition; however, the present invention is not limited to this, and at least one of the interposers 9 may be made of a disconnection detection wire for detecting a disconnection of the cable 1. . The disconnection detection wire is constructed by covering a stranded conductor with an insulator, but the insulator is made of cross-linked resin to prevent it from sticking to the surroundings due to the heat generated during extrusion molding of the outer sheath 7. It is preferable to use a composition (for example, crosslinked polyethylene) or a resin composition with a high melting point such as a fluororesin. Note that the disconnection detection wire is not included in the first electric wire 2 or the second electric wire 3 because it is not used for signal transmission or power transmission.

Furthermore, in this embodiment, a case has been described in which a nonwoven fabric formed by mixing two types of fibers with different melting points is used as the tape member 6. However, the tape member 6 is not limited to this, and for example, only one type of fiber is used. It may be a nonwoven fabric made of fibers, or it may be made of paper, resin film, or the like.

(Actions and effects of embodiments)
As explained above, in the cable 1 according to the present embodiment, the twisting direction of the twisted body 5 and the winding direction of the tape member 6 are the same direction, and the valleys between the first electric wires 2 adjacent in the cable circumferential direction are A pair of linear first intervening portions 91 provided in the cable circumferential direction and a pair of linear second intervening portions provided in the valley portions between the multi-core wires 8 adjacent to each other in the circumferential direction of the cable and the first electric wires 2 on one side and the other side. The tape member 6 is in contact with all the first electric wires 2 and multi-core wires 8 and the first interposer 91 and the second interposer 92 that constitute the twisted body 5. With this configuration, it is possible to realize a cable 1 that maintains durability against twisting and has improved terminal workability.

(Summary of embodiments)
Next, technical ideas understood from the embodiments described above will be described using reference numerals and the like in the embodiments. However, each reference numeral in the following description does not limit the constituent elements in the claims to those specifically shown in the embodiments.

[1] Multi-core wire having a pair of twisted wires (4) in which a pair of first wires (2) and a pair of second wires (3) having a smaller outer diameter than the first wires (2) are twisted together. A tape member (6) wound spirally around a twisted body (5) formed by twisting together the wire (8), the pair of first electric wires (2), and the multi-core wire (8). ), and an outer sheath (7) covering the outer periphery of the tape member (6), the pair of first electric wires (2) are in contact with each other, and the first electric wire (2) and the multi-core wire (8) are in contact with each other, the twisting direction of the twisted body (5) and the winding direction of the tape member (6) are the same direction, and the cable circumference is A linear first interposition (91) provided in a valley between the first electric wires (2) adjacent to each other in the cable circumferential direction; The tape member (6) includes a pair of linear second intervening devices (92) each provided in the valley portion between the two electric wires (2), and the tape member (6) includes all A cable (1) in contact with the first electric wire (2), the multi-core wire (8), the first interposition (91) and the second interposition (92).

[2] The cable (1) according to [1], wherein the first interposition (91) and the second interposition (92) are made of a crosslinked resin composition.

[3] The cable (1) described in [1], in which at least one of the first interposer (91) and the second interposer (92) is a break detection line.

[4] The cable (1) according to [1], wherein the surfaces of the first interposition (91) and the second interposition (92) have an arithmetic mean roughness Ra of 1 μm or more and 30 μm or less.

[5] The multi-core wire is composed of only the twisted wire pairs (4), and the twist direction of the twisted wire pairs (4), the twist direction of the twisted combination (5), and the tape member ( The cable (1) according to [1], wherein the winding direction of item 6) is the same as that of the cable (1).

[6] The tape member (6) includes first fibers having a melting point higher than the extrusion temperature of the outer sheath (7) and first fibers having a melting point lower than the extrusion temperature of the outer sheath (7). The cable (1) according to [1], which is formed by mixing the fibers of No. 2 with the fibers of No. 2.

Although the embodiments of the present invention have been described above, the embodiments described above do not limit the invention according to the claims. Furthermore, it should be noted that not all combinations of features described in the embodiments are essential for solving the problems of the invention. Moreover, the present invention can be implemented with appropriate modifications within a range that does not depart from the spirit thereof.

1... Cable 2... First electric wire 3... Second electric wire 4... Twisted wire pair 5... Twisted combination 6... Tape member 7... Outer sheath 8... Multi-core wire 81... Inner sheath 9... Interposition 91... First interposition 92... 2 intervention

Claims (6)

a pair of first electric wires;
a multi-core wire having a twisted pair of second wires each having a smaller outer diameter than the first wire;
a tape member spirally wound around a twisted body formed by twisting the pair of first electric wires and the multi-core wire;
an outer sheath covering the outer periphery of the tape member;
The pair of first electric wires are in contact with each other, and each of the first electric wires and the multi-core wire are in contact with each other,
The twisting direction of the twisted body and the winding direction of the tape member are the same direction,
a linear first interposition provided in a valley portion between the first electric wires adjacent in the circumferential direction of the cable;
A pair of linear second interpositions provided in valley portions between the multi-core wires and the first electric wires on one side and the other side, respectively, which are adjacent to each other in the circumferential direction of the cable,
The tape member is in contact with all the first electric wires, the multi-core wires, the first intervening material, and the second intervening material constituting the twisted body.
cable. The first intervention and the second intervention are made of a crosslinked resin composition,
The cable according to claim 1. At least one of the first interposition and the second interposition consists of a disconnection detection wire,
The cable according to claim 1. The arithmetic mean roughness Ra of the surfaces of the first interposition and the second interposition is 1 μm or more and 30 μm or less,
The cable according to claim 1. The multi-core wire is composed only of the twisted pair wires,
The twisting direction of the twisted wire pair, the twisting direction of the twisted body, and the winding direction of the tape member are the same direction.
The cable according to claim 1. The tape member is formed by mixing first fibers having a melting point higher than the extrusion temperature of the outer sheath and second fibers having a melting point lower than the extrusion temperature of the outer sheath. ,
The cable according to claim 1.

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