JP2022003654A - Composite cable for vehicle and composite harness for vehicle - Google Patents

Abstract

To provide a composite cable for a vehicle capable of suppressing cross talk between signal lines, even when a pair of power source lines for supplying a current to an electrically-driven parking brake and a plurality of signal lines uncoated with a shield conductor are coated collectively with a sheath; and to provide a composite harness for the vehicle including the composite cable for the vehicle.SOLUTION: Two power source lines for an electrically-driven parking brake, and first and second transit-time signal lines are not coated with a shield conductor, respectively, and first and second twist pair lines are separated by the two power source lines, and arranged separately with the two power source lines interposed therebetween.SELECTED DRAWING: Figure 1

Description

The present invention relates to a composite cable for a vehicle and a composite harness for a vehicle using the composite cable for a vehicle.

Conventionally, it is connected to a cable dedicated to the electric parking brake for supplying current to the electric parking brake mechanism for suppressing the rotation of the wheels after the vehicle is stopped, and an ABS sensor for measuring the rotation speed of the wheels while the vehicle is running. A composite harness including a composite cable in which a cable for an ABS sensor is integrated with a common sheath is known (see Patent Document 1).

In this type of composite harness, one end is fixed to the vehicle body and the other end is fixed to the wheels supported by the vehicle body via a suspension device. Then, when the vehicle body moves up and down with respect to the road surface as the vehicle travels, the composite cable is bent, so that the composite cable is required to have high flexibility. In the composite harness described in Patent Document 1, the electric parking brake dedicated cable and the ABS sensor cable are not provided with a shield conductor for noise suppression, thereby improving the flexibility and reducing the weight.

Japanese Patent No. 5541331

Due to the advanced computerization of vehicles in recent years, a plurality of sensors may be attached to the wheel side. However, when a plurality of signal lines that transmit detection signals of a plurality of sensors are collectively covered with a sheath, crosstalk between the signal lines is likely to occur unless a shield conductor is provided for each of the plurality of signal lines. Will end up.

Therefore, in the present invention, even if a pair of power supply lines for supplying current to the electric parking brake device and a plurality of signal lines not covered with the shield conductor are collectively covered with a sheath, cross talk between the twisted pair wires is performed. It is an object of the present invention to provide a composite cable for a vehicle capable of suppressing the above-mentioned, and a composite harness for a vehicle provided with the composite cable for the vehicle.

The present invention is a composite cable for a vehicle that is wired between the vehicle body and the wheels of the vehicle for the purpose of solving the above problems, and applies a current to an electric parking brake device that generates a braking force after the vehicle is stopped. A pair of first insulated wires supplied and whose central conductor is covered with an insulator and a pair of first insulated wires which are energized while the vehicle is running and whose central conductor is coated with an insulator are twisted together. The first twist pair wire, the second twist pair wire which is energized while the vehicle is running, and a pair of second insulated wires whose central conductor is covered with an insulator are twisted together, and the two power supply lines. And a sheath that collectively covers the first and second twisted pair wires, and the two power lines have an outer diameter larger than that of the first and second insulated wires, respectively. The distance between the two power lines is narrower than the thickness of the first insulated wire and the thickness of the second insulated wire, and the two power lines and the first and second twisted pair wires are shielded, respectively. A composite cable for a vehicle that is not covered with a conductor, and the first and second twist pair wires are separated by the two power lines and are arranged apart with the two power lines in between. I will provide a.

Further, for the purpose of solving the above problems, the present invention relates to the vehicle composite cable, the two power lines exposed from the sheath, the first twisted pair wire, and the second twisted pair wire. Provided is a composite harness for a vehicle having a connector attached to at least one of the ends.

According to the composite cable for vehicles and the composite harness for vehicles according to the present invention, it is possible to suppress crosstalk between twisted pair wires.

It is a schematic diagram which shows the structure of the vehicle which used the composite harness which concerns on 1st Embodiment. It is a schematic diagram which shows the structural example of the peripheral part of a rear wheel. It is a block diagram which shows a specific example of the structure of a wire harness. It is a schematic diagram which shows one end part of the composite cable which constitutes a wire harness. It is sectional drawing of the composite cable. (A) is an explanatory view showing the internal structure of the composite cable according to the second embodiment, and (b) is a cross-sectional view of the composite cable. (A) is an explanatory view showing the internal structure of the composite cable according to the third embodiment, and (b) is a cross-sectional view of the composite cable. It is sectional drawing of the composite cable which concerns on 4th Embodiment. It is sectional drawing of the composite cable which concerns on 5th Embodiment. (A) is a cross-sectional view of the composite cable according to the sixth embodiment, and (b) is an explanatory view showing a configuration example of a braided shield of the composite cable.

[First Embodiment]
FIG. 1 is a schematic view showing a configuration of a vehicle in which the composite harness according to the present embodiment is used.

The vehicle 1 has four tire houses 100 in the vehicle body 10, and two front wheels 11 and two rear wheels 12 are arranged in each tire house 100. In the present embodiment, the vehicle 1 is a front-wheel drive vehicle, and the front wheels 11 are driven by receiving the driving force of a drive source (not shown) including an engine and an electric motor. That is, in the present embodiment, the front wheels 11 are the driving wheels and the rear wheels 12 are the driven wheels.

Further, the vehicle 1 has two electric parking brake devices 130 and a control device 14. The electric parking brake device 130 is provided corresponding to each of the two rear wheels 12 and operates by the current supplied from the control device 14 to generate a braking force on the rear wheels 12. The control device 14 can detect the operating state of the parking brake operating switch 140 provided in the vehicle interior, and the driver can turn the parking brake operating switch 140 on / off to turn on / off the parking brake operating switch 140, whereby the electric parking brake device 130 can be operated. It is possible to switch between the activated state and the non-operated state.

For example, when the driver turns the parking brake operation switch 140 from the off state to the on state while the vehicle is stopped, the control device 14 outputs an operating current for operating the electric parking brake device 130 for a predetermined time (for example, 1 second). do. As a result, the electric parking brake device 130 operates to generate a braking force on the rear wheels 12. The operating state of the electric parking brake device 130 is maintained until a current for deactivating the electric parking brake device 130 is output from the control device 14. As described above, the electric parking brake device 130 mainly generates a braking force after the vehicle 1 is stopped.

The control device 14 outputs a current for deactivating the electric parking brake device 130 when the parking brake operation switch 140 is turned from the on state to the off state by the operation of the driver. The control device 14 applies a current for deactivating the electric parking brake device 130 not only when the parking brake operation switch 140 is turned off but also when the accelerator pedal is depressed, for example. Output.

Further, the front wheels 11 and the rear wheels 12 are provided with a wheel speed sensor 131 for detecting the wheel speed and an air pressure sensor 132 for detecting the tire pressure. The wheel speed sensor 131 itself is well known and has a magnetic field detection element that detects the magnetic field of an annular magnetic encoder that rotates with the front wheels 11 or the rear wheels 12, and the wheels are changed by a cycle in which the direction of the magnetic field changes. The speed (rotational speed of the front wheel 11 or the rear wheel 12) is detected. The air pressure sensor 132 has, for example, a diaphragm whose deflection amount changes according to the air pressure of the tire, and outputs an electric signal according to the deflection amount of the diaphragm.

The control device 14 and the wheel speed sensor 131 and the air pressure sensor 132 of the front wheels 11 are electrically connected by a front wheel electric wire group 151 composed of a plurality of electric wires and a front wheel wire harness 152. The front wheel electric wire group 151 and the front wheel wire harness 152 are connected in a relay box 153 fixed to the vehicle body 10. The relay box 153 is arranged in the vicinity of each of the pair of left and right front wheels 11.

Further, the control device 14, the electric parking brake device 130 for the rear wheels 12, the wheel speed sensor 131, and the air pressure sensor 132 are electrically connected by a rear wheel electric wire group 154 composed of a plurality of electric wires and a rear wheel wire harness 2. Is connected. The rear wheel wire harness 2 is an aspect of the "composite harness" according to the present invention. The rear wheel electric wire group 154 and the rear wheel wire harness 2 are connected in a relay box 155 fixed to the vehicle body 10. The relay box 155 is arranged in the vicinity of each of the pair of left and right rear wheels 12.

The front wheel electric wire group 151 is arranged in a wiring path 150 provided in the vehicle body 10 in a bundled state. Further, the rear wheel electric wire group 154 is also arranged in the wiring path 150 provided in the vehicle body 10 in a bundled state, like the front wheel electric wire group 151.

One end of the front wheel wire harness 152 is connected to the wheel speed sensor 131 and the pneumatic sensor 132 of the front wheel 11, and the other end is housed in the relay box 153. One end of the rear wheel wire harness 2 is connected to the electric parking brake device 130, the wheel speed sensor 131, and the air pressure sensor 132 of the rear wheel 12, and the other end is housed in the relay box 155. Since the front wheel wire harness 152 and the rear wheel wire harness 2 are bent in response to the vertical movement of the front wheels 11 and the rear wheels 12 with respect to the vehicle body 10 as the vehicle 1 travels, high bending durability is required. Hereinafter, the rear wheel wire harness 2 is simply referred to as "wire harness 2".

FIG. 2 is a schematic view showing a configuration example of a peripheral portion of the rear wheel 12. The rear wheel 12 is supported by the suspension device 16 with respect to the vehicle body 10. The suspension device 16 includes an upper arm 161, a lower arm 162, a shock absorber 163, and a suspension spring 164. One end of each of the upper arm 161 and the lower arm 162 is connected to the knuckle 165, and the other end is connected to the vehicle body 10. The outer ring 171 of the hub unit 17 of the rear wheel 12 is fixed to the knuckle 165. The upper arm 161 is connected to the first mounting portion 165a of the knuckle 165 together with the shock absorber 163, and the lower arm 162 is connected to the second mounting portion 165b of the knuckle 165.

The suspension spring 164 is coaxially arranged on the outer periphery of the shock absorber 163, and expands and contracts according to the vertical movement of the vehicle body 10 with respect to the road surface. Then, as the shock absorber 163 expands and contracts, the upper arm 161 and the lower arm 162 swing with respect to the vehicle body 10.

Further, a third mounting portion 165c is projected from the knuckle 165, and the electric parking brake device 130 is fixed to the third mounting portion 165c. The electric parking brake device 130 has a main body 130a, a caliper 130b, and a brake pad 130c fixed to the caliper 130b.

The hub unit 17 has an outer ring 171 and a hub ring 172 rotatably supported by the outer ring 171. The hub wheel 172 is provided with a wheel mounting flange 172a, and the rear wheel 12 is mounted on the wheel mounting flange 172a. A plurality of rolling elements (not shown) are held and arranged in a cage between the inner peripheral surface of the outer ring 171 of the hub unit 17 and the outer peripheral surface of the hub ring 172.

A disk-shaped brake rotor 18 is fixed to the wheel mounting flange 172a of the hub wheel 172 together with the wheel 120 of the rear wheel 12. The brake rotor 18 integrally has a friction portion 18a with which the brake pad 130c of the electric parking brake device 130 is frictionally engaged, and a fixing portion 18b fixed to the wheel mounting flange 172a of the hub wheel 172. One side surface of the friction portion 18a faces the brake pad 130c of the electric parking brake device 130. When the electric parking brake device 130 is activated, the caliper 130b is pulled into the main body 130a, and the brake pad 130c is pressed against the friction portion 18a of the brake rotor 18. As a result, a frictional force is generated between the brake pad 130c and the brake rotor 18, and this frictional force becomes the braking force of the vehicle 1.

A tire 121 is mounted on the wheel 120. The tire 121 is a rubber tire in which a reinforcing agent or the like is mixed with a rubber material made of synthetic rubber or natural rubber. The air pressure sensor 132 includes a detection element 132a that transmits a radio wave signal corresponding to the air pressure of the tire 121, and an antenna element 132b that receives the radio wave signal transmitted from the detection element 132a. The detection element 132a is attached to the wheel 120 and rotates together with the rear wheel 12. The antenna element 132b is fixed to a non-rotating member that does not rotate with the rotation of the rear wheel 12. In the present embodiment, the antenna element 132b is fixed to the knuckle 165 which is a non-rotating member, but the antenna element 132b may be fixed to, for example, the vehicle body 10.

The radio wave signal transmitted from the detection element 132a is converted into an electric signal by the antenna element 132b and transmitted to the control device 14 via the wire harness 2. When the air pressure detected by the air pressure sensor 132 is lower than a predetermined value, the control device 14 issues a warning to the driver by a lamp display or an alarm sound.

(Structure of wire harness 2)
FIG. 3 is a configuration diagram showing a specific example of the configuration of the wire harness 2. FIG. 4 is a schematic view showing one end of the composite cable 2A constituting the wire harness 2. 5A is a cross-sectional view of the composite cable 2A, FIG. 5B is a cross-sectional view of the insulated wire 31 constituting the first signal line 30, and FIG. 5C is a cross-sectional view of the power supply line 21. FIG. 5D is a cross-sectional view of the insulated wire 41 constituting the second signal line 40.

In FIG. 3, the end portion on the rear wheel 12 side is shown on the left side of the drawing, and the end portion on the relay box 155 side is shown on the right side of the drawing. In the following description, the end portion of the wire harness 2 on the rear wheel 12 side is referred to as "one end portion", and the end portion on the relay box 155 side is referred to as "the other end portion".

The composite cable 2A includes a pair of power lines 21 and 22, a first signal line 30 composed of twisted pair lines, a second signal line 40 also composed of twisted pair lines, and a pair of power lines 21 and 22 and the first and first. It has a sheath 20 that collectively covers the second signal lines 30 and 40, and an inclusion 5 housed in the sheath 20.

A first power connector 23 for connecting to the electric parking brake device 130 is attached to one end of the pair of power lines 21 and 22, and a relay box 155 is attached to the other end of the pair of power lines 21 and 22. A second power connector 24 for connection with the rear wheel electric wire group 154 inside is attached.

A wheel speed sensor 131 is attached to one end of the first signal line 30, and a first signal line connection connector 33 for connecting to the rear wheel electric wire group 154 in the relay box 155 is attached to the other end. It is attached. Further, an antenna element connection connector 43 for connecting the antenna element 132b of the air pressure sensor 132 is attached to one end of the second signal line 40, and a rear wheel electric wire in the relay box 155 is attached to the other end. A second signal line connector 44 for connection with group 154 is attached.

The wire harness 2 includes a composite cable 2A, a first power supply connector 23, a second power supply connector 24, a wheel speed sensor 131, a first signal line connection connector 33, an antenna element connection connector 43, and a second signal line connection connector 44. It is composed of.

The pair of power lines 21 and 22 are used to supply current to the electric parking brake device 130. The first signal line 30 is used to transmit the detection signal of the wheel speed sensor 131 to the control device 14. Further, the second signal line 40 is used to transmit the detection signal of the pneumatic sensor 132 to the control device 14.

That is, the first signal line 30 and the second signal line 40 transmit the detection signal of the vehicle state amount indicating the traveling state of the vehicle 1 to the control device 14 when the vehicle 1 is traveling. The detection signal of the wheel speed sensor 131 transmitted by the first signal line 30 is a signal for detecting the wheel speed of the rear wheels 12, and is a specific example of the "first electric signal" of the present invention. Further, the detection signal of the pneumatic sensor 132 transmitted by the second signal line 40 is a specific example of the "second electric signal" of the present invention.

The inclusions 5 are interposed inside the sheath 20 between the pair of power lines 21 and 22 and the first and second signal lines 30 and 40. By this inclusion 5, the outer peripheral surface 20a of the sheath 20 in the cross section orthogonal to the central axis of the composite cable 2A is brought closer to a circular shape, and the arrangement of the composite cable 2A is enhanced. Further, when the composite cable 2A is bent by the inclusions 5, the sheath 20, the pair of power lines 21 and 22, the first signal line 30, and the second signal line 40 are prevented from rubbing against each other. Therefore, the bending resistance of the composite cable 2A is enhanced.

The sheath 20 is made of an insulating resin, and specifically, flexible polyurethane having excellent flexibility and durability can be particularly preferably used as the material thereof. As shown in FIG. 5A, where D is the outer diameter of the sheath 20 and t is the thickness, D is 8.0 to 10.0 mm and t is 1.0 to 2.0 mm.

The pair of power lines 21 and 22 are insulated wires in which the central conductors 210 and 220, each of which is made of a good conductive conductor such as copper, are coated with an insulator 211 and 221 made of an insulating resin. The insulators 211 and 221 are made of, for example, cross-linked PE (polyethylene) or flame-retardant cross-linked PE (polyethylene). Of the pair of power supply lines 21 and 22, the outer diameter of the center conductor 210 of one power supply line 21, the thickness of the insulator 211, and the outer diameter of the insulator 211 are the outer diameters of the center conductor 220 of the other power supply line 22. It is common with the diameter, the thickness of the insulator 221 and the outer diameter of the insulator 221. As shown in FIG. 5 (c), assuming that the outer diameter of the center conductor 210 of one of the power lines 21 is D ₀₁ , the thickness of the insulator 211 is t ₀ , and the outer diameter of the insulator 211 is D ₀₂ , D ₀₁ Is 1.8 to 2.3 mm, t ₀ is 0.3 to 0.5 _{mm, and D 02} is 2.9 to 3.1 mm.

The first signal line 30 is a twisted pair wire formed by twisting a pair of insulated wires 31 and 32 at a predetermined twisted pitch. Of the pair of insulated wires 31 and 32, one of the insulated wires 31 has a central conductor 310 made of a good conductive conductor such as copper coated with an insulator 311 made of an insulating resin, and the other insulated wire. Similarly, the center conductor 320 made of a good conductive conductor wire such as copper is covered with an insulator 321 made of an insulating resin. The central conductors 310 and 320 of the insulated wires 31 and 32 are stranded wires composed of a plurality of strands. The insulators 311, 321 are made of, for example, cross-linked PE (polyethylene) or flame-retardant cross-linked PE (polyethylene).

The outer diameter of the central conductor 310 of one insulated wire 31, the thickness of the insulator 311 and the outer diameter of the insulator 311 and the outer diameter of the central conductor 320 of the other insulated wire 32, the thickness of the insulator 321 and the thickness of the insulator 321. The outer diameter of the insulator 321 is common to each other. That is, one of the insulated wires 31 and 32 has common specifications. As shown in FIG. 5B, assuming that the outer diameter of the central conductor 310 of one of the insulated wires 31 is D ₁₁ , the thickness of the insulator 311 is t ₁ , and the outer diameter of the insulator 311 is D ₁₂ , D ₁₁ Is 0.6 to 0.9 mm, D ₁₂ is 1.3 to 1.6 mm, and t ₁ is 0.25 to 0.4 mm.

The second signal line 40 is a twisted pair wire formed by twisting a pair of insulated wires 41 and 42 at a predetermined twisted pitch. The twist pitch and twist direction of the second signal line 40 are the same as the twist pitch and twist direction of the first signal line 30, and are configured in the same manner as the first signal line 30.

Specifically, of the pair of insulated wires 41 and 42 of the second signal line 40, one of the insulated wires 41 insulates the central conductor 410 made of a good conductive conductor wire such as copper from an insulating resin. The other insulated wire 42 is also covered with the body 411, and similarly, the central conductor 420 made of a good conductive conductor such as copper is covered with an insulator 421 made of an insulating resin. The central conductors 410 and 420 of the insulated wires 41 and 42 are stranded wires composed of a plurality of strands, and the insulators 411 and 421 are made of, for example, cross-linked PE (polyethylene) or flame-retardant cross-linked PE (polyethylene).

The outer diameter of the central conductor 410 of one insulated wire 41, the thickness of the insulator 411, and the outer diameter of the insulator 411 in the second signal line 40, and the outer diameter and insulation of the central conductor 420 of the other insulated wire 42. The thickness of the body 421 and the outer diameter of the insulator 421 are common to each other. That is, one of the insulated wires 41 and 42 has common specifications. As shown in FIG. 5 (d), assuming that the outer diameter of the central conductor 410 of one of the insulated wires 41 is D ₂₁ , the thickness of the insulator 411 is t- ₂ , and the outer diameter of the insulator 411 is D ₂₂ , D ₂₁ is 0.7 to 1.0 mm, D ₂₂ is 1.4 to 1.8 mm, and t ₂ is 0.25 to 0.4 mm.

_{In the present embodiment, the outer diameter (thickness) D 12} of the pair of insulated wires 31 and 32 of the first signal line 30 and the outer diameter (thickness) of the pair of insulated wires 41 and 42 of the second signal line 40. S) Equivalent to _{D 22.} Specifically, the ratio of D ₂₂ of _{D 12 (D 12 / D 22} ) is 0.8 to 1.2. Further, the more desirable range of the ratio of _{D 12} to D _{22 (D 12} / D ₂₂ ) is 0.9 or more and 1.1 or less.

In FIG. 5A, when the composite cable 2A is viewed in the longitudinal direction from the illustrated cross section, the pair of insulated wires 31 and 32 of the first signal line 30 and the pair of insulation of the second signal line 40 are insulated. The outer edge of the range where the electric wires 41 and 42 exist is shown by a broken line.

In the composite cable 2A, one end of the sheath 20 is fixed to a non-rotating member that does not rotate with the rotation of the rear wheel 12. In the present embodiment, as shown in FIG. 2, one end of the sheath 20 is fixed to the knuckle 165 by the fixture 19. However, not limited to this, one end of the sheath 20 is a non-rotating member that does not rotate with the rotation of the rear wheel 12 and moves up and down with respect to the vehicle body 10 together with the rear wheel 12 with the expansion and contraction of the suspension spring 164. It suffices if it is fixed to.

The first signal line 30 is not covered with a shield conductor. Also, the second signal line 40 is not covered with the shield conductor. Furthermore, the pair of power lines 21 and 22 are also not covered with the shield conductor. That is, between the pair of insulated wires 31 and 32 of the first signal line 30 and the pair of power lines 21 and 22, and the pair of insulated wires 41 and 42 of the second signal line 40 and the pair of power lines 21. A conductive member that shields the electromagnetic wave is not arranged between the 22 and the 22 except that the inclusion 5 is interposed.

This is because the current flows through the pair of power lines 21 and 22 mainly when the vehicle 1 is stopped, and the first and second signal lines 30 and 40 transmit the electric signals mainly while the vehicle 1 is running. Therefore, it is not necessary to provide a shield conductor between the first signal line 30 and the pair of power lines 21 and 22 and between the second signal line 40 and the pair of power lines 21 and 22. It focuses on that.

That is, when a current flows through the pair of power supply lines 21 and 22, the electromagnetic waves generated by this current are the potential difference between the pair of insulated wires 31 and 32 in the first signal line 30 and the second signal line 40. Although it may affect the potential difference between the pair of insulated wires 41 and 42, the control device 14 outputs the electric signals of the first and second signal lines 30 and 40 while the vehicle 1 having a vehicle speed of zero is stopped. It can be ignored and can be prevented from adversely affecting the running of the vehicle 1. Further, since the first and second signal lines 30 and 40 are not covered with the shield conductor, the flexibility of the composite cable 2A is increased, the flexibility is increased, and the weight and cost of the composite cable 2A are reduced. Can also contribute.

Further, in the present embodiment, the first signal line 30 and the second signal line 40 are further separated by a pair of power supply lines 21 and 22. In other words, the space inside the sheath 20 is divided into the accommodation space of the first signal line 30 and the accommodation space of the second signal line 40 by a pair of power supply lines 21 and 22.

This is because, as described above, by not covering the first and second signal lines 30 and 40 with the shield conductor, crosstalk occurs between the first signal line 30 and the second signal line 40. In view of facilitation, the composite cable 2A is configured so that the pair of power lines 21 and 22 are sandwiched between the first signal line 30 and the second signal line 40 so as to suppress crosstalk. It was done. That is, by separating the first signal line 30 and the second signal line 40 by a pair of power supply lines 21 and 22, the distance between the first signal line 30 and the second signal line 40 is crosstalked. By keeping the distance above the possible distance, crosstalk between the first signal line 30 and the second signal line 40 is suppressed.

Specifically, the distance between the pair of power lines 21 and 22 is the thickness of the pair of insulated wires 31 and 32 of the first signal line 30, and the pair of insulated wires 41 of the second signal line 40. It is narrower than the thickness of 42 so that the pair of insulated wires 31 and 32 of the first signal line 30 and the pair of insulated wires 41 and 42 of the second signal line 40 do not come into direct contact with each other. There is. In the example shown in FIG. 5A, since the pair of power lines 21 and 22 are in contact with each other, this interval is zero. Further, since the central conductors 210 and 220 of the pair of power lines 21 and 22 are conductors, a certain shielding effect can be expected, and the shielding effect of the central conductors 210 and 220 also suppresses crosstalk.

_{In the present embodiment, as described above, the outer diameter D 12} of the pair of insulated wires 31 and 32 of the first signal line 30 and the outer diameter D of the pair of insulated wires 41 and 42 of the second signal line 40. _{Since 22} is equivalent, a pair of power supply lines 21 and 22 are located at the center of the sheath 20 in the arrangement direction of the first signal line 30 and the second signal line 40 in the cross section of the composite cable 2A, and the pair The relative positional relationship between the power supply lines 21 and 22 and the first and second signal lines 30 and 40 is stable. As a result, the above effect becomes more remarkable.

_{Further, as shown in FIG. 5A, in the present embodiment, the regions A 11} and A ₁₂ surrounded by the pair of power supply lines 21 and 22, the first signal line 30, and the second signal line 40. Is a space, and the regions A ₁₁ and A ₁₂ are not filled with inclusions 5. This facilitates terminal processing of the composite cable 2A.

That is, when the composite cable 2A is terminally processed, a part of the sheath 20 is cut off to expose the pair of power lines 21 and 22, the first and second signal lines 30, 40, and the inclusions 5. Further, it is necessary to cut off the inclusions 5 exposed from the end of the sheath 20, but at this time, if the _{inclusions 5 are filled in the regions A 11} and A ₁₂ , the work of cutting off the inclusions 5 is performed. , It becomes difficult to be disturbed by the pair of power lines 21 and 22 and the first and second signal lines 30 and 40. Therefore, in the present embodiment, the terminal processing of the composite cable 2A is easy by not filling _{the regions A 11} and A ₁₂ surrounded by the first signal line 30 and the second signal line 40 with the inclusions 5. It has become.

As the inclusions 5, various fibrous materials such as polypropylene yarn, aramid fiber, nylon fiber, and fibrous plastic, which are generally used as inclusions in cables, paper, cotton thread, and the like can be used. In the embodiment, the inclusions 5 contain artificial polypropylene fibers. This artificial polypeptide fiber, also called spider silk fiber, is an artificial fiber containing a polypeptide derived from a natural spider silk protein as a main component, and has, for example, a stress of 350 to 628.7 MPa and a toughness of 138 to 265. .4 MJ / m ³ . By including the artificial polypeptide fiber in the inclusions 5, the strength of the composite cable 2A can be increased.

Further, the sheath 20 may contain the above-mentioned artificial polypeptide fiber. Since the strength is increased by containing the artificial polypeptide fiber, the sheath 20 can be made thinner, the flexibility can be increased while maintaining the strength of the composite cable 2A, and the weight can be reduced.

According to the first embodiment described above, since the first signal line 30 and the second signal line 40 are not covered with the shield conductor, the flexibility of the composite cable 2A is enhanced and the composite cable 2A has increased flexibility. It can contribute to weight reduction and cost reduction. Further, since the first signal line 30 and the second signal line 40 are separated by a pair of power supply lines 21 and 22, crosstalk between the first signal line 30 and the second signal line 40 Is suppressed. That is, according to the present embodiment, between the first signal line 30 and the second signal line 40 while omitting the shield conductor covering the first signal line 30 and the second signal line 40. It is possible to suppress the crosstalk of.

(Other embodiments)
Hereinafter, the composite cables 2B to 2F according to the second to sixth embodiments of the present invention will be described. These composite cables 2B to 2F are connectors to the ends of the pair of power supply lines 21 and 22, the first signal line 30, and the second signal line 40, as in the composite cable 2A according to the first embodiment. It is configured as a wire harness by attaching such as, and can be applied to the vehicle 1. Further, in the composite cables 2B to 2F, regarding the materials and dimensions of the sheath 20, the pair of power lines 21 and 22, and the insulated wires 31, 32, 41, 42 of the first and second signal lines 30, 40, etc. It can be similar to the one described above.

[Second Embodiment]
A second embodiment of the present invention will be described with reference to FIG. The composite cable 2B according to the second embodiment has a sheath 20, a pair of power lines 21 and 22, a first signal line 30, and a second signal line 30, similarly to the composite cable 2A according to the first embodiment. The signal line 40 and the inclusions 5 are provided, and the first signal line 30 and the second signal line 40 are separated by a pair of power supply lines 21 and 22, but the first signal line 30 and the second signal line 30 are separated from each other. The phases of the twists of the signal lines 40 of 2 are different. Hereinafter, this difference will be mainly described.

FIG. 6A is an explanatory view showing the internal structure of the composite cable 2B according to the present embodiment, and FIG. 6B is a cross-sectional view of the composite cable 2B. In FIG. 6A, the sheath 20 is cut in a semicircular cross section along the longitudinal direction, and the inclusion 5 is omitted from the illustration to illustrate the internal structure of the composite cable 2B.

In the composite cable 2B according to the present embodiment, similarly to the composite cable 2A according to the first embodiment, the first signal line 30 is formed by twisting a pair of insulated wires 31 and 32 to form a second signal. The wire 40 is made by twisting a pair of insulated wires 41 and 42. _{Further, the twist pitch P 1} of the pair of insulated wires 31 and 32 in the first signal line 30 _{and the twist pitch P 2} of the pair of insulated wires 41 and 42 in the second signal line 40 are common.

However, the phase of twisting the pair of insulated wires 31 and 32 in the first signal line 30 and the phase of twisting the pair of insulated wires 41 and 42 in the second signal line 40 are different from those in FIG. 6 (b). ) In the cross section orthogonal to the longitudinal direction of the sheath 20, when the pair of insulated wires 31 and 32 of the first signal line 30 are arranged along the direction parallel to the arrangement direction of the pair of power lines 21 and 22. Second signal line 40 A pair of insulated wires 41, 42 are arranged along a direction orthogonal to the arrangement direction of the pair of power lines 21 and 22.

As a result, the diameter of the sheath 20 can be reduced. That is, in the present embodiment, the diameter of the composite cable 2B can be reduced as compared with the composite cable 2A according to the first embodiment.

That is, in the composite cable 2A according to the first embodiment, as shown in FIG. 5, the pair of insulated wires 31 and 32 in the first signal line 30 and the pair of insulated wires 41 in the second signal line 40, Even when both 42 are arranged in a direction orthogonal to the arrangement direction of the pair of power lines 21 and 22, the pressing force from the first signal line 30 and the second signal line 40 causes the pair of power lines 21 and 22 to be arranged. It was necessary to set the inner diameter of the sheath 20 so that the interval would not be greatly widened. However, according to the present embodiment, the pair of insulated wires 31, 32 and the second signal line in the first signal line 30 are used. Since the pair of insulated wires 41 and 42 in 40 are not lined up in a row, the inner diameter of the sheath 20 can be made smaller than that of the composite cable 2A according to the first embodiment.

Further, also in the composite cable 2B according to the present embodiment, the pair of power supply lines 21 and 22, the first signal line 30, and the second signal line are similar to the composite cable 2A according to the first embodiment. _{The areas A 21} and A ₂₂ surrounded by 40 are spaces that are not filled with inclusions 5, which facilitates terminal processing of the composite cable 2B.

As described above, according to the present embodiment, in addition to the actions and effects described in the first embodiment, the diameter of the composite cable 2B can be reduced, and eventually the composite cable 2B can be arranged. It will be possible to increase.

[Third Embodiment]
Next, a third embodiment of the present invention will be described with reference to FIG. 7. The composite cable 2C according to the third embodiment has a sheath 20, a pair of power lines 21 and 22, a first signal line 30, and a second signal line 30, similarly to the composite cable 2A according to the first embodiment. The signal line 40 and the inclusions 5 are provided, and the first signal line 30 and the second signal line 40 are separated by a pair of power lines 21 and 22, but the first signal line 30 and the second signal line 30 are separated from each other. The twist pitch of the signal line 40 of 2 is different. Hereinafter, this difference will be mainly described.

FIG. 7A is an explanatory view showing the internal structure of the composite cable 2C according to the present embodiment, and FIG. 7B is a cross-sectional view of the composite cable 2C. In FIG. 7A, the sheath 20 is cut in a semicircular cross section along the longitudinal direction, and the inclusions 5 are omitted from the illustration to illustrate the internal structure of the composite cable 2C.

In the composite cable 2C according to the present embodiment, similarly to the composite cable 2A according to the first embodiment, the first signal line 30 is formed by twisting a pair of insulated wires 31 and 32 to form a second signal. Although line 40 is formed by twisting a pair of insulated wires 41 and 42, the twist pitch P ₁ of the pair of insulated wires 31, 32 of the first signal line 30, a pair of insulated wires 41 in the second signal line 40 , 42 twist pitch P ₂ is different.

Further, in the present embodiment, than the twisting pitch P ₁ of the first signal line 30 larger in the twisting pitch P ₂ of the second signal line 40, the difference is more than twice. However, conversely, the twist pitch P _{1 of the first signal line 30 may be larger than the twist pitch P 2} of the second signal line 40, and further, the twist pitch of the first signal line 30 may be larger. P ₁ may be at least twice the twist pitch P _{2 of the second signal line 40.}

As a result, the composite cable 2C according to the present embodiment can suppress the winding habit as compared with the composite cable 2A according to the first embodiment. In other words, when a plurality of twisted pair wires are accommodated in one sheath, the entire cable may be curved like a swell due to the winding habit according to the winding direction of the twisted pair wires, and the arrangement may be deteriorated. According to the embodiment, the twisted pitch P1 of the pair of insulated wires 31 and 32 in the first signal line 30 and the twisted pitch P2 of the pair of insulated wires 41 and 42 in the second signal line 40 are different. For example, as compared with the case where the twisted pitch P2 of the second signal line 40 is equal to the twisted pitch P1 of the first signal line 30, the winding habit of the composite cable 2C is less likely to occur. This effect becomes more remarkable when the difference between the twist pitch P1 of the first signal line 30 and the twist pitch P2 of the second signal line 40 is twice or more.

In addition, when made different from the twist pitch P ₁ of the first signal line 30 and a twisting pitch P ₂ of the second signal line 40, the change cycle of the electrical signal to be transmitted to increase the twisting pitch of the longer signal lines Is desirable. In other words, twisted pair wires are more susceptible to electromagnetic noise by increasing the twisted pitch, but if the change cycle of the electrical signal is long, for example, among multiple detection results in multiple pumping cycles, other detection results. By ignoring those far from each other as abnormal values or averaging a plurality of detection results, it is possible to reduce the influence of electromagnetic noise even if the twisted pitch is increased.

Therefore, in the composite cable 2C according to the present embodiment, the second signal line for transmitting the detection signal of the air pressure sensor 132 is transmitted rather than _{the twist pitch P 1 of} the first signal line 30 for transmitting the signal for detecting the wheel speed. The twist pitch P _{2 of} 40 is increased.

Further, also in the composite cable 2C according to the present embodiment, the pair of power supply lines 21 and 22, the first signal line 30, and the second signal line are similar to the composite cable 2A according to the first embodiment. _{The areas A 31} and A ₃₂ surrounded by 40 are spaces that are not filled with inclusions 5, which facilitates terminal processing of the composite cable 2C.

As described above, according to the present embodiment, in addition to the actions and effects described for the first embodiment, it is possible to suppress the winding habit of the composite cable 2C.

[Fourth Embodiment]
Next, a fourth embodiment of the present invention will be described with reference to FIG. FIG. 8 is a cross-sectional view of the composite cable 2D according to the present embodiment.

The composite cable 2D according to the fourth embodiment has the sheath 20, the pair of power lines 21 and 22, the first signal line 30, and the second, as in the composite cable 2A according to the first embodiment. The first signal line 30 and the second signal line 40 are separated by a pair of power lines 21 and 22, but the pair of power lines 21 and 22 and the first signal line are separated from each other. The 30 and the second signal line 40 are held by the sheath 20 and have no inclusions 5.

_{Further, also in the composite cable 2D according to the present embodiment, the regions A 41} and A ₄₂ surrounded by the pair of power supply lines 21 and 22, the first signal line 30, and the second signal line 40 are exposed from the outside. It is said that the space can be compressed by the pressure of. This facilitates the terminal processing of the composite cable 2D as in the first embodiment.

Also in this embodiment, the same actions and effects as those described in the first embodiment can be obtained. Further, since the inclusions 5 are not arranged in the sheath 20, the manufacturing process is simplified.

The sheath 20 of the composite cable 2D may contain the above-mentioned artificial polypeptide fiber. By using the sheath 20 containing the artificial polypeptide fiber, the outer diameter of the sheath 20 itself can be reduced by increasing the strength, and the diameter and weight of the composite cable 2D can be reduced.

[Fifth Embodiment]
Next, a fifth embodiment of the present invention will be described with reference to FIG. FIG. 9 is a cross-sectional view of the composite cable 2E according to the present embodiment.

The composite cable 2E according to the fifth embodiment has a sheath 20, a pair of power lines 21 and 22, and first and second signal lines 30, 40 with respect to the composite cable 2D according to the fourth embodiment. The configuration in which the lubricant 6 for reducing the frictional resistance and improving the lubricity is arranged is different. That is, in the composite cable 2E according to the present embodiment, the pair of power lines 21 and 22 and the first and second signal lines 30 and 40 are held by the sheath 20 via the lubricant 6.

The lubricant 6 has a particle size of, for example, 5 to 50 μm, and talc (Mg ₃ Si ₄ O ₁₀ (OH) ₂ ), silica (SiO ₂ ), or the like can be preferably used as the material thereof. Here, the particle size means the size of the particles obtained by the sieving method, the microscopy method, the laser diffraction / scattering method, the electric detection method, the chromatography method, etc. defined by JIS8801. Further, as the lubricating material 6, paper tape or lubricating oil may be used.

According to the composite cable 2E according to the present embodiment, the pair of power lines 21 and 22 and the first and first power lines 21 and 22 inside the sheath 20 are provided with the lubricant 6 as compared with the composite cable 2D according to the fourth embodiment. The movement of the signal lines 30 and 40 of 2 can be smoothed, and the flexibility is enhanced.

[Sixth Embodiment]
Next, a sixth embodiment of the present invention will be described with reference to FIG. FIG. 10A is a cross-sectional view of the composite cable 2F according to the present embodiment, and FIG. 10B is an explanatory diagram showing a configuration example of the braided shield 7 of the composite cable 2F.

The composite cable 2F according to the sixth embodiment is obtained by adding a braided shield 7 to the composite cable 2A according to the first embodiment. That is, the composite cable 2F according to the present embodiment includes a sheath 20, a pair of power lines 21 and 22, a first signal line 30, a second signal line 40, and inclusions 5. Inside the sheath 20, a braided shield 7 that collectively covers a pair of power lines 21 and 22 and first and second signal lines 30 and 40 is provided.

In the braided shield 7, a plurality of wires 70 having good conductivity such as copper are braided together with the artificial polypeptide fiber 71 in a lattice pattern. More specifically, the braided shield 7 is an artificial spider silk fiber in which a plurality of well-conductive strands 70 such as copper and an artificial polypeptide fiber 71 (artificial spider yarn fiber) are woven in a lattice pattern at a “predetermined ratio”. It is a mixed braided shield. Here, the "predetermined ratio" is a ratio that does not lose the original shielding function. As the artificial polypeptide fiber 71, the same one as described in the first embodiment can be used.

Further, as a possible modification, the braided shield 7 is a braided shield layer in which a plurality of good conductive strands 70 such as copper are woven in a grid pattern, and an artificial polypeptide fiber 71 (artificial spider silk fiber) is latticed. It is a laminated braided shield in which an artificial spider yarn braided layer woven into a shape is laminated.

In this way, by using the artificial polypeptide fiber 71 (artificial spider silk fiber), the weight of the braided shield can be reduced.
The above-mentioned artificial spider silk braid (artificial spider yarn braid layer) can be applied not only to the cable field but also to the hose field such as a brake hose, and its application range is wide.

According to the present embodiment, in addition to the actions and effects described for the first embodiment, electromagnetic waves from the outside of the braided shield 7 adversely affect the transmission of electric signals by the first and second signal lines 30 and 40. Can be suppressed. In addition, it is possible to prevent electromagnetic waves generated by currents flowing through the pair of power lines 21 and 22 from adversely affecting communication via other cables. Furthermore, in the braided shield 7, since a plurality of wires 70 having good conductivity such as copper are braided in a lattice pattern together with the artificial polypeptide fiber 71, the strength of the braided shield 7 is increased and the composite cable 2F is repeatedly bent. Even if this is done, it is possible to suppress the tearing of the wire 70 made of a metal such as copper. As a result, the wire 70 having a small diameter can be used, and the flexibility of the composite cable 2F can be improved.

(Summary of embodiments)
Next, the technical idea grasped from the embodiment described above will be described with reference to the reference numerals and the like in the embodiment. However, each reference numeral in the following description is not limited to the member or the like in which the components in the claims are specifically shown in the embodiment.

[1] A vehicle composite cable (2A to 2F) wired between the vehicle body (10) and the wheels (11, 12) of the vehicle (1), and a braking force is generated after the vehicle (1) is stopped. Two power lines (21,22) formed by supplying a current to the electric parking brake device (130) and covering the central conductors (210, 220) with an insulator (211,221), and the vehicle (1). ) Is energized while the center conductor (310, 320) is covered with an insulator (311, 321), and a pair of first insulated wires (31, 32) are twisted together to form a first twist pair wire (1, 32). 30) and a pair of second insulated wires (41, 42), which are energized during traveling of the vehicle (1) and whose central conductors (410, 420) are covered with an insulator (411,421), are twisted together. A sheath (20) that collectively covers the second twist pair wire (40), the two power supply wires (21, 22), and the first and second twist pair wires (30, 40). , The two power lines (21, 22) have an outer diameter larger than that of the first (31, 32) and the second insulated wire (41, 42), respectively, and the two power supplies are provided. The distance between the wires (21, 22) is narrower than the thickness of the first insulated wire (31, 32) and the thickness of the second insulated wire (41, 32), and the two power lines (21, 32) are spaced apart from each other. 22) and the first and second twisted pair wires (30, 40) are not covered with shield conductors, respectively, and the first and second twisted pair wires (30, 40) are the two power supplies. Vehicle composite cables (2A to 2F) separated by wires (21,22) and spaced apart from each other with the two power lines (21,22) in between.

[2] The twisting direction of the pair of first insulated wires (31, 32) and the twisting direction of the pair of second insulated wires (41, 42) are the same, and the pair of first insulated wires (31, 42) are twisted in the same direction. The composite cable for a vehicle (2A to 2F) according to [1], wherein the insulated electric wire (31, 32) and the pair of second insulated electric wires (41, 42) have different twist pitches from each other.

[3] The ratio of the outer diameter of the first insulated wire (31, 32) to the outer diameter of the second insulated wire (41, 42) is 0.8 or more and 1.2 or less. ] Or the vehicle composite cable (2A to 2F) according to [2].

[4] The first and second twisted pair lines (30, 40) are signal lines for transmitting a detection signal of a vehicle state amount indicating the running state of the vehicle (1) when the vehicle (1) is running, respectively. The vehicle composite cable (2A to 2F) according to any one of the above [1] to [3].

[5] The vehicle composite cable (2A to 2F) according to any one of the above [1] 1 to [4] and the two power lines (21, 22) exposed from the sheath (20). , A vehicle composite harness having a connector attached to at least one of the ends of the first twisted pair wire (30) and the second twisted pair wire (40). 2F).

Although the embodiments of the present invention have been described above, the embodiments described above do not limit the invention according to the claims. It should also be noted that not all combinations of features described in the embodiments are essential to the means for solving the problems of the invention.

Further, the present invention can be appropriately modified and implemented without departing from the spirit of the present invention. For example, in the above embodiment, the case where the second signal line 40 transmits the detection signal of the pneumatic sensor 132 has been described, but the present invention is not limited to this. That is, the second signal line 40 may transmit a detection signal of a vehicle state amount indicating a running state of the vehicle 1, which is different from the rotation speed of the wheels. This vehicle state quantity may be, for example, a current supplied to the electric motor when the rear wheel 12 is driven by an electric motor (in-wheel motor), and the rear wheel 12 is steered at a predetermined angle. In some cases, the steering angle may be used.

When the electric parking brake device 130 is also provided on the front wheel 11, a wire harness having a connector or the like attached to any of the composite cables 2A to 2F may be used on the front wheel 11 side.

1 ... Vehicle 2 ... Wire harness 2A-2F ... Composite cable 5 ... Inclusion 6 ... Lubricator 7 ... Braided shield 10 ... Body 20 ... Sheaths 21 and 22 ... Power line 30 ... First signal line 40 ... Second signal Wires 31, 32, 41, 42 ... Insulated wire 70 ... Wire 71 ... Artificial polypeptide fiber 130 ... Electric parking brake device 130c ... Brake pad 131 ... Wheel speed sensor 132 ... Pneumatic sensor 132a ... Detection element 132b ... Antenna element

Claims (4)

Two power lines whose center conductor is covered with an insulator,
A first twisted pair wire made by twisting two first insulated wires whose center conductor is covered with an insulator,
A second twisted pair wire made by twisting two second insulated wires whose central conductor is covered with an insulator,
A sheath that collectively covers the two power lines and the first and second twisted pair wires, and
Equipped with
The two power lines and the first and second twisted pair wires are not covered with shield conductors, respectively.
The first and second twisted pair wires are arranged apart from each other so as to sandwich the two power lines.
The two power lines have a larger outer diameter than the first and second insulated wires, respectively.
The two power lines are separated from each other, and the distance between the two power lines is narrower than the thickness of the first insulated wire and the thickness of the second insulated wire.
Composite cable for vehicles. A lubricant for reducing frictional resistance and improving lubricity is arranged between the two power lines and between the first twisted pair wire and the second twisted pair wire.
The composite cable for a vehicle according to claim 1. The sheath is inserted between the power line and the first twisted pair line, and between the power line and the second twisted pair line.
The vehicle composite cable according to claim 1 or 2. The vehicle composite cable according to any one of claims 1 to 3 is provided.
The two power lines, the first twisted pair wire, and the second twisted pair wire extend from the end of the sheath.
A first connector is attached to the ends of the two power lines.
A wheel speed sensor is attached to the end of the first twisted pair wire.
A second connector is attached to the end of the second twisted pair wire.
The first connector, the wheel speed sensor, and the second connector are separate bodies.
Composite harness for vehicles.

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