JP2022102737A - Inspection apparatus for multicore cable and inspection method for multicore cable - Google Patents

Abstract

To provide a technique for accurately identifying correspondence between ends of a plurality of insulation wires at both ends of a multicore cable including the insulation wires.SOLUTION: An inspection apparatus for multicore cable identifying correspondence between ends of insulation wires comprises: signal input means for inputting an inspection signal to one end of the insulation wire via capacitive coupling; signal output means for outputting an inspection signal from the other end of each of the insulation wires via capacitive coupling; and corresponding identifying means for measuring inspection signal voltage to identify the other end of the insulation wire. At least one of the signal input means and the signal output means includes a signal transmission cable and a substrate. A first electrode to which the signal transmission cable is connected is provided on one primary surface of the substrate while a second electrode capacitively coupled to the insulation wire is provided on the other primary surface of the substrate. A transmission path connected to the first electrode and the second electrode and transmitting the inspection signal is provided within the substrate. The substrate is provided with a shield layer inhibiting noise from intruding into the transmission path.SELECTED DRAWING: Figure 1

Description

The present invention relates to a multi-core cable inspection device and a multi-core cable inspection method.

Conventionally, a multi-core cable having a plurality of insulated wires has been known. For example, as a multi-core cable for medical use, a probe cable having tens to hundreds of insulated wires is known.

In a multi-core cable having dozens to hundreds of insulated wires, it is difficult to make the identification color assigned to identify the insulator different among all the insulated wires. Further, when a plurality of insulated wires are twisted together inside the multi-core cable, the position of the insulated wire in the multi-core cable becomes undefined in the end cross section, and the correspondence between the ends of the insulated wires can be identified. Becomes difficult. Therefore, when connecting a multi-core cable to a connector, a circuit board, or the like, an inspection is required to identify the correspondence between the ends of the insulated wires exposed from both ends of the multi-core cable.

When performing the above inspection, for example, an inspection signal is input to the conductor of any insulated wire exposed at one end of the multicore cable, and the conductor of the insulated wire exposed at the other end of the multicore cable. A device that measures the inspection signal output from the device may be used.

When performing an inspection using the above-mentioned device, if an inspection signal is to be directly input to the conductor of the insulated wire, it becomes necessary to physically contact the electrodes with all of the conductors of the plurality of insulated wires, and the inspection is performed. It takes a lot of time to prepare and implement. Therefore, an inspection technique in which an electrode is arranged on an insulator and an inspection signal is input by capacitive coupling has been proposed (see, for example, Patent Document 1).

Japanese Unexamined Patent Publication No. 2004-251771

The present invention provides a multi-core cable inspection device and a multi-core cable inspection method capable of accurately specifying the correspondence between the ends of the insulated wires at both ends of the multi-core cable having a plurality of insulated wires. The purpose is to do.

According to the first aspect of the present invention.
A multi-core cable inspection device that specifies the correspondence between the insulated wires at both ends of a multi-core cable having a plurality of insulated wires.
A signal input means for inputting an inspection signal by capacitive coupling to the end of the insulated wire to be inspected among the ends of the plurality of insulated wires exposed at one end of the multi-core cable.
A signal output means for outputting an inspection signal by capacitive coupling from each end of the plurality of insulated wires exposed at the other end of the multi-core cable.
A corresponding specifying means for measuring the voltage of the inspection signal obtained from the signal output means and specifying the other end of the insulated wire to be inspected based on the measured voltage is provided.
At least one of the signal input means and the signal output means has a signal transmission cable for transmitting an inspection signal and a substrate to which the signal transmission cable is connected.
A first electrode to which the signal conductor of the signal transmission cable is connected is provided on one main surface of the substrate.
A second electrode capacitively coupled to the end of the insulated wire is provided on the other main surface of the substrate.
Inside the substrate, a transmission path for transmitting the inspection signal between the first electrode and the second electrode is provided.
The substrate is provided with a shield layer for suppressing noise from entering the transmission line, and an inspection device for a multi-core cable is provided.

According to the second aspect of the present invention.
A method for inspecting a multi-core cable that specifies the correspondence between the insulated wires at both ends of the multi-core cable having a plurality of insulated wires.
A signal input step of inputting an inspection signal by capacitive coupling to the end of the insulated wire to be inspected among the ends of the plurality of insulated wires exposed at one end of the multi-core cable.
A signal output step of outputting an inspection signal by capacitive coupling from each end of the plurality of insulated wires exposed at the other end of the multi-core cable.
A corresponding identification step of measuring the voltage of the inspection signal obtained by performing the signal output step and specifying the other end of the insulated wire to be inspected based on the measured voltage.
Have,
At least one of the signal input step and the signal output step
It has a first electrode on one main surface to which the signal conductor of a signal transmission cable for transmitting an inspection signal is connected, a second electrode on the other main surface, and the first electrode and the second electrode inside. Using a substrate having a transmission path for transmitting an inspection signal between the electrodes, the second electrode and the end of the insulated wire are capacitively coupled.
The shield layer provided on the substrate provides a method for inspecting a multi-core cable that suppresses noise intrusion into the transmission line.

According to the present invention, a multi-core cable inspection device and a multi-core cable inspection method capable of accurately specifying the correspondence between the ends of the insulated wires at both ends of the multi-core cable having a plurality of insulated wires. Can be provided.

FIG. 1 is a diagram showing a circuit configuration of an inspection device 1 according to an embodiment of the present invention. FIG. 2 is a schematic view showing a state in which the multi-core cable 2 is set in the inspection device 1. FIG. 3A is a cross-sectional view schematically showing a cross section of the multi-core cable 2 perpendicular to the longitudinal direction. FIG. 3B is a cross-sectional view schematically showing a cross section of the insulated wire 3 perpendicular to the longitudinal direction. 4 (a) and 4 (b) are diagrams illustrating a method of fixing the insulated wire 3 to the inspection table 45, respectively. FIG. 5 is a partial cross-sectional enlarged view schematically showing a cross section of the substrate 44 along the thickness direction according to the embodiment of the present invention. FIG. 6 is a perspective view in which the main part of the substrate 44 according to the embodiment of the present invention is partially extracted. FIG. 7 is a flow chart showing a control flow when inspecting the correspondence between the ends of the insulated wires 3.

<One Embodiment of the present invention>
(1) Configuration of Inspection Device for Multi-Core Cable The inspection device 1 according to the present embodiment is configured as a device for specifying the correspondence between the insulated wires 3 at both ends of the multi-core cable 2 having a plurality of insulated wires 3. There is.

First, the configuration of the multi-core cable 2 to be inspected will be described.

As shown in the cross-sectional view in FIG. 3A, the multi-core cable 2 includes a plurality of insulated wires 3 and a shield 21 provided so as to collectively surround the outer periphery of the bundled plurality of insulated wires 3. It includes a jacket 22 provided so as to cover the outer periphery of the shield 21. The shield 21 can be formed, for example, by braiding a metal wire made of copper (Cu), a Cu alloy, or the like. The jacket 22 can be made of a flexible and slidable material such as silicone rubber. The number of insulated wires 3 included in the multi-core cable 2 is not particularly limited, but may be, for example, about 10 to 300.

As shown in the cross-sectional view in FIG. 3B, the insulated wire 3 includes a conductor 31 as a core wire and an insulating coating layer 32 provided so as to cover the outer periphery of the conductor 31. The conductor 31 can be made of, for example, Cu, a Cu alloy, aluminum (Al), an Al alloy, or the like. The insulating coating layer 32 can be made of, for example, an insulating material (dielectric) such as polyimide, enamel, polyethylene, or polypropylene. The outer diameter of the insulated wire 3 including the insulating coating layer 32 can be, for example, about 0.2 mm to 0.5 mm. Further, the insulated wire 3 may have a coaxial structure.

Next, the overall configuration of the inspection device 1 will be described.

As shown in FIG. 2, the inspection device 1 includes a signal input means 4 and a signal output means 6. The signal input means 4 inputs an AC inspection signal by capacitive coupling to the end of the insulated wire 3 to be inspected among the ends of the insulated wire 3 exposed at one end of the multi-core cable 2. It is configured to do. The signal input means 4 has a voltage source 41 that generates an inspection signal, and a substrate 44 that inputs an inspection signal to the insulated wire 3 by capacitive coupling by contacting the outer peripheral surface of the insulated wire 3.

The signal output means 6 is configured to output an output signal from the insulated wire 3 by capacitive coupling via a substrate 61 pressed against each insulated wire 3. The signal output means 6 has an arithmetic unit 8 that receives the output signal and specifies the correspondence relationship of the insulated wire 3 based on the received inspection signal.

Subsequently, a specific configuration of the inspection device 1 will be described.

As shown in FIG. 1, the inspection device 1 includes a signal input means 4, a signal output means 6, and an arithmetic unit 8 configured as a computer that realizes the corresponding identification means 81. The above-mentioned multi-core cable 2 is set between the signal input means 4 and the signal output means 6, so that the correspondence between the insulated wires 3 at both ends of the multi-core cable 2 can be inspected. ing.

The signal input means 4 inspects the end of the conductor 31 of the insulated wire 3 to be inspected by capacitive coupling among the ends of the plurality of insulated wires 3 exposed at one end of the multi-core cable 2. It is configured to input the signal V.

Specifically, the signal input means 4 inputs the voltage source 41 that generates the inspection signal V, the first amplifier 42 that amplifies the inspection signal V, and the inspection signal V amplified by the first amplifier 42. The board to which the first switch device 43 for selecting the above by switching the circuit, the signal transmission cable 47 for transmitting the inspection signal V output from the first switch device 43 to the board 44, and the signal transmission cable 47 are connected. 44 and.

The signal transmission cable 47 has a plurality of insulated wires, a shield provided so as to collectively surround the outer periphery of the bundled plurality of insulated wires, and a jacket provided to cover the outer periphery of the shield. In that respect, it is configured in substantially the same manner as the above-mentioned multi-core cable 2. The core wire of the insulated wire included in the signal transmission cable 47 functions as a signal conductor for transmitting the inspection signal V. In particular, the insulated wire used for the signal transmission cable 47 preferably has a coaxial structure in order to make it less susceptible to external noise.

A first electrode 441 to which the signal conductor of the signal transmission cable 47 is connected is provided on one main surface of the substrate 44, and an insulated wire of the multicore cable 2 is provided on the other main surface as described later. A second electrode 442 that is capacitively coupled to the subject is provided. Further, inside the substrate 44, a transmission line 430 for transmitting the inspection signal V between the first electrode 441 and the second electrode 442 is provided. The detailed configuration of the substrate 44 will be described later.

With the above configuration, the inspection signal V is transmitted from the voltage source 41 to the first electrode 441 via the signal transmission cable 47 or the like, and is transmitted from the first electrode 441 to the inside of the substrate 44. The inspection signal V is transmitted toward the second electrode 442 via the path 430.

Further, the signal input means 4 further includes an inspection table 45 shown in FIGS. 4 (a) and 4 (b). The plurality of insulated wires 3 exposed at one end of the multi-core cable 2 are fixed on the inspection table 45 in an aligned state. Specifically, the inspection table 45 includes a pedestal 451 and a pair of locking walls 452 arranged so as to face each other on the main surface of the pedestal 451. A plurality of locking grooves 452a capable of locking (pinching) the insulated wire 3 are arranged in each of the pair of locking walls 452, for example, at equal intervals. The plurality of insulated wires 3 are arranged in parallel on the pedestal 451 while maintaining a predetermined interval by sandwiching and fixing their respective ends in the locking grooves 452a. The method of fixing the plurality of insulated wires 3 on the inspection table 45 is not limited to the method shown here, and for example, an adhesive tape attached on the pedestal 451 may be used. Further, the arrangement spacing of the insulated wires 3 can be changed as appropriate.

As described above, the inspection signal V is transmitted to the second electrode 442. As shown in FIG. 4A, the second electrode 442 is an insulated wire 3 on one main surface of the substrate 44 while maintaining the same arrangement spacing as the plurality of insulated wires 3 fixed on the inspection table 45. A plurality of them are provided so as to be arranged in a row so as to be arranged along the alignment direction of. The number of the second electrodes 442 can be about the same as the number of the insulated wires 3 fixed to the locking groove 452a, and can be larger than the number of the insulated wires 3.

By pressing each of the plurality of second electrodes 442 provided on the substrate 44 against each of the plurality of insulated wires 3 fixed on the pedestal 451, the plurality of second electrodes 3 are placed on the outer periphery of the plurality of insulated wires 3. The 442s can be brought into contact with each other. That is, the conductor 31 of the insulating electric wire 3 and the second electrode 442 can be arranged (capacitively coupled) so as to face each other with the insulating coating layer 32 made of a dielectric interposed therebetween. In this state, by transmitting the inspection signal V to the second electrode 442, the inspection signal V can be input to the conductor 31 of the insulated wire 3 arranged opposite to the second electrode 442 by capacitive coupling. It will be possible.

In addition, in order to improve the input efficiency of the inspection signal using the capacitive coupling, it is preferable to use an AC signal as the inspection signal V instead of the DC signal. In this case, the frequency of the inspection signal V can be appropriately set according to the structure of the multi-core cable 2 and the like, and can be, for example, a frequency smaller than the resonance frequency peculiar to the multi-core cable 2. The frequency of the inspection signal V can be, for example, a predetermined frequency in the range of 1 MHz to 10 MHz.

Note that FIGS. 4 (a) and 4 (b) show only a part of the various configurations included in the substrate 44 for convenience. The detailed configuration of the substrate 44 will be described later.

The signal output means 6 is configured to output an inspection signal by capacitive coupling from each end of a plurality of insulated wires 3 exposed at the other end of the multi-core cable 2.

Specifically, the signal output means 6 includes an inspection table (not shown) configured in the same manner as the inspection table 45 described above, a substrate 61, and a signal transmission cable 47 configured in the same manner as the signal transmission cable 47 described above. It is equipped with a cable 67.

The configuration of the substrate 61 is substantially the same as the configuration of the substrate 44 described above. That is, a third electrode (not shown) to which the signal conductor (core wire) of the signal transmission cable 67 is connected is provided on one main surface of the substrate 61, and the above-mentioned is provided on the other main surface. Similar to the second electrode 442, a fourth electrode 661 (see FIG. 1) that is capacitively coupled to the insulated wire of the multicore cable 2 is provided. Further, inside the substrate 61, a transmission line (not shown) for transmitting the inspection signal V between the third electrode and the fourth electrode 661 is provided. The third electrode, the fourth electrode 661, and the transmission path included in the substrate 61 are configured in substantially the same manner as the first electrode 441, the second electrode 442, and the transmission path 430 included in the substrate 44, respectively.

A plurality of insulations are provided by pressing each of the plurality of fourth electrodes 661 provided on the substrate 61 toward each of the insulated wires 3 fixed in an aligned state on the pedestal of the inspection table (all not shown). A plurality of fourth electrodes 661 can be brought into contact with each other on the outer periphery of the electric wire 3. That is, the conductor 31 of the insulating electric wire 3 and the fourth electrode 661 can be arranged (capacitively coupled) so as to face each other with the insulating coating layer 32 made of a dielectric interposed therebetween. In this state, when the inspection signal V is input to the conductor 31 of the insulated wire 3, the inspection signal V is generated by capacitive coupling with respect to the fourth electrode 661 arranged opposite to the conductor 31 of the insulated wire 3. Be transmitted. Then, the inspection signal V is transmitted from the fourth electrode 661 toward the third electrode (all not shown) via the transmission path provided inside the substrate 61.

Further, the signal output means 6 outputs from the second switch device 62 and the second switch device 62 that select the output destination of the inspection signal V transmitted from the third electrode via the signal transmission cable 67 by switching the circuit. A new inspection signal V is generated by multiplying the inspection signal V amplified by the second amplifier 63 that amplifies the obtained inspection signal V and the reference signal V that is amplified by the second amplifier 63 by the reference signal output from the reference signal generation circuit 7. It has a multiplier 64 and a low-pass filter 65 that removes high frequency components from the new inspection signal V generated by the multiplier 64.

The reference signal generation circuit 7 has a phase shifter 71 that adjusts the phase of the inspection signal V branched from the voltage source 41 to be a reference signal, and a multiplier 64 that amplifies the reference signal from the phase shifter 71. It has a third amplifier 72 that outputs to. The phase shift amount in the phase shifter 71 is appropriately adjusted so that the inspection signal V and the reference signal are in phase in the multiplier 64 in consideration of the phase shift when transmitting the capacitive coupling and the multi-core cable 2. Will be done. In the multiplier 64, when the inspection signal V amplified by the second amplifier 63 is multiplied by a reference signal having the same phase and frequency as the inspection signal V output from the reference signal generation circuit 7, a new inspection obtained thereby is obtained. The signal V will have a DC component and a component having a frequency twice the original frequency. The low-pass filter 65 removes a component having twice the frequency, sets only the DC component as the final inspection signal V, and outputs this to the arithmetic unit 8.

The arithmetic unit 8 sequentially measures the voltage of the above-mentioned inspection signal V obtained from the signal output means 6, that is, the final inspection signal V having only a DC component, while performing the switching operation of the second switch device 62. Based on the measured voltage of the inspection signal V, the isolated wire 3 to be inspected, that is, the other side of the insulated wire 3 in which the inspection signal V is input to the conductor 31 with the switching operation of the first switch device 43. It has a corresponding specifying means 81 for specifying an end portion of the above. The arithmetic unit 8 is configured as a computer equipped with a memory such as a CPU, RAM, and ROM, a storage device such as a hard disk, software, an interface, and the like, and the above-mentioned correspondence specifying means 81 is provided by the cooperative operation of these resources. It is configured to be realized.

The corresponding specifying means 81 is a switch control unit 811 that controls each switching operation of the first switch device 43 and the second switch device 62, and the end portions of the insulated wire 3 based on the voltage measurement result of the inspection signal V and the like. It has a determination unit 812 and a determination unit 812 for determining the correspondence between the two.

The determination unit 812 controls the first switch device 43 via the switch control unit 811 so that the inspection signal V is input to the end of the specific insulated wire 3 to be inspected at one end of the multicore cable 2. The second switch device 62 is controlled to sequentially measure the voltage of the inspection signal corresponding to all the insulated wires 3 at the other end of the multicore cable 2.

Then, the determination unit 812 determines that among the ends of the insulated wires 3 exposed at the other end of the multi-core cable 2, the one having the largest voltage of the inspection signal V is the other end of the insulated wires 3 to be inspected. It is identified as a unit, and the corresponding relationship is stored in the storage unit 82.

The correspondence between the ends of the insulated wires 3 is, for example, the numbers sequentially assigned to the ends of the insulated wires 3 arranged and arranged at one end of the multicore cable 2 and the correspondence between the ends of the insulated wires 2. It is represented by associating the numbers sequentially assigned to the ends of the arranged insulated wires 3. The determination unit 812 sequentially changes the insulated wire 3 to be inspected, identifies the correspondence between the ends of all the insulated wires 3, and stores them in the storage unit 82.

(2) Configuration of the Substrate 44 Hereinafter, the configuration of the substrate 44 will be described in detail mainly with reference to FIGS. 5 and 6. The plan view shape of the substrate 44 is a rectangular shape as an example in FIG. 4, but the shape is not limited to this.

As described above, one main surface of the substrate 44 (the surface on the upper end side in FIG. 5) is provided with a first electrode 441 to which the signal conductor of the signal transmission cable 47 is connected. Further, on the other main surface of the substrate 44 (the surface on the lower end side in FIG. 5), a second electrode 442 capacitively coupled to the conductor 31 of the insulated wire 3 is provided at a position facing one end of the insulated wire 3. It is provided.

Inside the substrate 44, a transmission line 430 for connecting the first electrode 441 and the second electrode 442 and transmitting the inspection signal V between the first electrode 441 and the second electrode 442 is provided.

The transmission line 430 in the present embodiment extends not only in the portion extending along the thickness direction of the substrate 44 (hereinafter, vertical transmission line 431) but also in the main surface inward direction (planar direction) of the substrate 44. It has a portion (hereinafter, creepage transmission line 432).

Further, in addition to the above-mentioned first electrode 441, second electrode 442, and transmission line 430, the substrate 44 in the present embodiment includes a shield layer 449 that suppresses noise (electrostatic noise, etc.) from entering the transmission line 430. Further prepared.

The shield layer 449 has a first shield layer 447 that surrounds the circumference of the first electrode 441 while maintaining a non-contact state with the first electrode 441 on one main surface, and a second electrode 442 on the other main surface. It has at least one of the second shield layers 448 that surrounds the periphery of the second electrode 442 while maintaining a non-contact state. In this embodiment, as an example, the case where the shield layer 449 has both the first shield layer 447 and the second shield layer 448 is shown. However, the present embodiment is not limited to this, and among the first shield layer 447 and the second shield layer 448, only the first shield layer 447 may be provided, and the second shield layer 448 may be provided. May have only.

As described above, a plurality of first electrodes 441 are provided on one main surface of the substrate 44. With respect to these first electrodes 441, the first shield layer 447 is provided on one main surface of the substrate 44 so as to collectively surround the entire plurality of first electrodes 441, as shown in FIG. ing.

Further, as described above, a plurality of second electrodes 442 are also provided on the other main surface of the substrate 44. With respect to these second electrodes 442, as shown in FIG. 6, a plurality of second shield layers 448 are provided on the other main surface of the substrate 44 so as to individually surround each of the plurality of second electrodes 442. Has been done. Further, these plurality of second shield layers 448 are provided on the other main surface of the substrate 44 so as to maintain a non-contact state with each other.

Further, the shield layer 449 further has a third shield layer 444 that extends in a plane shape along the inward direction of the main surface of the substrate 44 inside the substrate 44. The shield layer 449 is configured such that the above-mentioned creepage transmission line 432 is sandwiched between the third shield layer 444 and at least one of the first shield layer 447 and the second shield layer 448. 5 and 6 show, as an example, a case where the third shield layer 444 and the first shield layer 447 sandwich the above-mentioned creepage transmission line 432. The creepage transmission line 432 may be provided between the third shield layer 444 and the second shield layer 448, and may be provided between the third shield layer 444 and the first shield layer 447, and the third shield. It may be provided both between the layer 444 and the second shield layer 448.

The above-mentioned substrate 44 can be manufactured by using a known method such as a build-up method. The configuration of the substrate 44 manufactured by using the build-up method will be described in more detail below.

As shown in FIG. 5, the substrate 44 has a flat plate-shaped core material 440 and a first prepreg layer 445 provided so as to be joined (or additionally molded) to each of both main surfaces of the core material 440. A second prepreg layer 446 and the like are provided. As the core material 440, for example, a known insulating material such as glass fiber impregnated with an epoxy resin and cured can be used. The first prepreg layer 445 and the second prepreg layer 446 can be formed by joining flat plates made of the above-mentioned insulating material, respectively. The first prepreg layer 445 and the second prepreg layer 446 may be an insulator layer made of a thermosetting or photocurable insulating molding material or the like.

A first electrode 441 and a first shield layer 447 are provided on the surface of the first prepreg layer 445 that constitutes one main surface of the substrate 44. The first electrode 441 and the first shield layer 447 can be formed by patterning a copper foil attached to the surface of the first prepreg layer 445, respectively. As described above, a plurality of first electrodes 441 are formed on the surface of the first prepreg layer 445, and the first shield layer 447 is formed on the surface of the first prepreg layer 445 of the plurality of first electrodes 441. It is formed so as to surround the whole together.

A second electrode 442 and a second shield layer 448 are provided on the surface of the second prepreg layer 446 that constitutes the other main surface of the substrate 44. The second electrode 442 and the second shield layer 448 can be formed by patterning a copper foil attached to the surface of the second prepreg layer 446, respectively. As described above, a plurality of second electrodes 442 are formed on the surface of the second prepreg layer 446, and the second shield layer 448 is formed on the surface of the second prepreg layer 446 of the plurality of second electrodes 442. A plurality of them are formed so as to surround each of them individually. Further, the plurality of second shield layers 448 are formed on the surface of the second prepreg layer 446 so as to maintain a non-contact state with each other.

Inside the substrate 44, a transmission line 430 for connecting the first electrode 441 and the second electrode 442 is provided. As described above, the first electrode 441 and the second electrode 442 are provided at positions that do not face each other with the substrate 44 interposed therebetween, and the transmission line 430 is a vertical transmission line extending along the thickness direction of the substrate 44. It has a 431 and a creepage transmission line 432 extending along the inward direction (creepular direction) of the main surface of the substrate 44. The vertical transmission line 431 is formed by forming a via hole that penetrates at least one of the core material 440, the first prepreg layer 445, and the second prepreg layer 446 in the thickness direction, and filling the inside thereof with copper plating or the like. Can be done. The creepage transmission line 432 can be formed by patterning a copper foil attached to one main surface of the core material 440 or the like.

A third shield layer 444 is provided at the bonding interface between the core material 440 and the second prepreg layer 446. As the third shield layer 444, a copper foil attached to the other main surface of the core material 440, for example, which is left almost as it is as a solid pattern can be used.

The first shield layer 447, the second shield layer 448, and the third shield layer 444 are all configured so as not to be electrically connected (contact) with the first electrode 441, the second electrode 442, and the transmission line 430. There is. Further, the first shield layer 447, the second shield layer 448, and the third shield layer 444 are all grounded via a ground wire (not shown) or the like.

(3) Multi-core cable inspection method In the multi-core cable inspection method according to the present embodiment, first, the jacket 22 and the shield 21 are removed by a predetermined length at both ends of the multi-core cable 2, and a plurality of them are removed. Each of the insulated wires 3 of the above is exposed. After that, at both ends of the multi-core cable 2, each exposed insulated wire 3 is fitted and fixed in the locking groove 452a of the inspection table 45 without removing the insulating coating layer 32, and the inspection table 45, not shown. The substrates 44 and 61 are pressed against each of the insulated wires 3 fixed to the inspection table of the above to build the above-mentioned capacitive coupling. After that, an inspection is performed to identify the correspondence between the ends of the insulated wires 3 by the following procedure.

FIG. 7 is a flow chart showing a control flow in the arithmetic unit 8 when performing an inspection for specifying the correspondence between the ends of the insulated wires 3. Here, the number of the insulated wires 3 is n, and the order of the insulated wires 3 arranged on the inspection table 45 is No. 1, 2, ..., N. Further, the number "n" of the insulated wires 3 is manually input to the arithmetic unit 8.

As shown in FIG. 7, first, in step S51, the determination unit 812 substitutes the initial value 1 into each of the variables a and b. After that, in step S52, the determination unit 812 controls the first switch device 43 via the switch control unit 811 and applies the inspection signal V to the a-th insulated wire 3. That is, among the ends of the insulated wire 3 exposed at one end of the multi-core cable 2, the inspection signal V is input to the end of the ath insulated wire 3 to be inspected by capacitive coupling. No other signal including the inspection signal V is input to the insulated wire 3 other than the a-th insulated wire 3 to be inspected.

The inspection signal V transmitted from the voltage source 41 included in the signal input means 4 is transmitted to the first electrode 441 via the signal conductor of the signal transmission cable 47. The inspection signal V transmitted to the first electrode 441 is transmitted to the second electrode 442 via the transmission line 430. The inspection signal V transmitted to the second electrode 442 is input to the end of the conductor 31 of the insulated wire 3 pressed against the second electrode 442 by capacitive coupling.

After that, in step S53, the determination unit 812 controls the second switch device 62 via the switch control unit 811, and the end of the b-th insulated wire 3 exposed at the other end of the multicore cable 2. The voltage of the inspection signal V (here, the final inspection signal V having only a DC component) output from the unit is measured, and the measurement result is the variable b (that is, the number of the end of the insulated wire 3 on the other end side). ) And stores it in the storage unit 82.

In step S54, the determination unit 812 determines whether or not the variable b is equal to n. If it is determined that they are not equal (NO) in step S54, b is incremented in step S55, and then the process returns to step S53. If it is determined to be equal (YES) in step S54, that is, if the measurement for all the ends of the insulated wires 3 on the other end side (signal output means 6 side) of the multicore cable 2 is completed, the measurement is completed in step S56. Then, the determination unit 812 corresponds to the number having the largest voltage of the inspection signal V (the number at the end of the insulated wire 3 on the other end side) corresponding to the ath insulated wire 3 currently being inspected. It is specified that it is the end portion on the other side, and the specified correspondence is stored in the storage unit 82.

In step S57, the determination unit 812 determines whether or not the variable a is equal to n. If it is determined that they are not equal (NO) in step S57, a is incremented in step S58, the variable b is returned to the initial value 1, and then the process returns to step S52. If it is determined to be equal (YES) in step S57, that is, if the correspondence relationship is specified for all the insulated wires 3 on one end side (signal input means 4 side) of the multicore cable 2, the process proceeds to step S59. In step S59, the arithmetic unit 8 outputs the specific result of the correspondence stored in the storage unit 82 to, for example, a monitor. After that, the process ends.

(4) Effects of the present embodiment According to the present embodiment, one or more of the following effects are exhibited.

(A) Since the substrate 44 according to the present embodiment is provided with the shield layer 449, it is possible to suppress the intrusion of noise into the transmission line 430 when the inspection signal V is transmitted. As a result, the correspondence between the ends of the insulated wire 3 can be specified stably and accurately.

(B) On one main surface of the substrate 44 according to the present embodiment, the first shield layer 447 surrounding the circumference of the first electrode 441 and the substrate 44 while maintaining a non-contact state with the first electrode 441. The other main surface has at least one of the second shield layers 448 that surrounds the periphery of the second electrode 442 while maintaining a non-contact state with the second electrode 442. As a result, it is possible to suppress the intrusion of noise into the transmission line 430 from at least one of the direction of one main surface of the substrate 44 and the direction of the other main surface of the substrate 44. As a result, the correspondence between the ends of the insulated wire 3 can be specified stably and accurately.

(C) The first shield layer 447 according to the present embodiment is provided so as to collectively surround the entire plurality of first electrodes 441. As a result, it is possible to suppress the intrusion of noise into the transmission line 430 connected to each of the plurality of first electrodes 441 from the direction of one main surface of the substrate 44. As a result, the correspondence between the ends of the insulated wire 3 can be specified stably and accurately.

(D) A plurality of second shield layers 448 according to the present embodiment are provided so as to individually surround each of the plurality of second electrodes 442. As a result, it is possible to suppress noise from entering the transmission line 430 connected to each of the plurality of second electrodes 442 from the direction of the other main surface of the substrate 44. As a result, the correspondence between the ends of the insulated wire 3 can be specified stably and accurately.

(E) The plurality of second shield layers 448 according to the present embodiment are provided so as to maintain a non-contact state with each other. As a result, the shielding force of the second shield layer 448 can be appropriately adjusted (decreased), and as a result, the decrease in the detection sensitivity of the correspondence between the ends of the insulated wires 3 can be suppressed. As a result, the correspondence between the ends of the insulated wire 3 can be specified stably and accurately.

(F) The transmission line 430 according to the present embodiment extends inside the substrate 44 along the main surface inward direction (planar direction) of the substrate 44 so as to connect the first electrode 441 and the second electrode 442. It has a portion (creeping transmission line 432). With such a configuration, it is possible to increase the arrangement spacing of the plurality of insulated wires 3 fixed on the inspection table 45 and secure a wide spacing between the adjacent insulated wires 3. As a result, the insulated wire 3 can be easily and quickly fixed on the inspection table 45, and the correspondence between the ends of the insulated wire 3 can be specified stably and accurately.

(G) The third shield layer 444 according to the present embodiment is provided inside the substrate 44 so as to spread in a plane along the inner direction of the main surface of the substrate 44, and the third shield layer 444 and the first shield layer are provided. The transmission line 430 is configured to sandwich a portion (creeping transmission line 432) extending along the inward direction (creeping direction) of the main surface of the substrate 44 in the transmission line 430. As a result, it is possible to suppress the intrusion of noise into the creeping transmission line 432 where noise easily invades. As a result, the correspondence between the ends of the insulated wire 3 can be specified stably and accurately.

<Other embodiments>
Although one embodiment of the present invention has been specifically described above, the present invention is not limited to the above-described embodiment and can be appropriately modified without departing from the gist thereof.

In the above-described embodiment, the case where both the signal input means 4 and the signal output means 6 include a substrate having a shield layer for suppressing noise from entering the transmission line has been described, but the present invention is not limited thereto. .. For example, only one of the signal input means 4 and the signal output means 6 may include a substrate having a shield layer. Even in this case, substantially the same effect as that of the above-described embodiment can be obtained.

In the above-described embodiment, the case where the substrate has all of the first shield layer 447, the second shield layer 448, and the third shield layer 444 is shown, but the present invention is not limited to this, and the first It suffices to have at least one of the shield layer 447, the second shield layer 448, and the third shield layer 444. Even in this case, substantially the same effect as that of the above-described embodiment can be obtained.

In the above-described embodiment, the first shield layer 447 is provided on one main surface of the substrate 44 so as to collectively surround the entire plurality of first electrodes 441, but the present invention has been made. It is not limited to this. For example, a plurality of first shield layers 447 may be provided on one main surface of the substrate 44 so as to individually surround each of the plurality of first electrodes 441. Further, in this case, the plurality of first shield layers 447 may be provided on one main surface of the substrate 44 so as to maintain a non-contact state with each other. Even in this case, substantially the same effect as that of the above-described embodiment can be obtained.

In the above-described embodiment, the case where the plurality of second shield layers 448 are formed so as to be in a non-contact state with each other on the other main surface of the substrate 44 has been described, but the present invention is limited thereto. Two or more of the plurality of second shield layers may be selected in any combination and electrically bonded to each other. Further, the second shield layer 448 may be provided on the other main surface of the substrate 44 so as to collectively surround the entire plurality of second electrodes 442. Even in this case, substantially the same effect as that of the above-described embodiment can be obtained.

In the above-described embodiment, the arrangement spacing of the second electrodes 442 on the other main surface of the substrate 44 is made larger than the arrangement spacing of the first electrodes 441 on one main surface of the substrate 44, and the arrangement spacing is increased with the first electrode 441. The second electrode 442 and the second electrode 442 are provided at positions that do not face each other across the substrate 44, but the present invention is not limited to this. These arrangement spacings can be freely set and can be the same size on both main surfaces, and the magnitude relationship of the arrangement spacings can be reversed on both main surfaces. Even in this case, substantially the same effect as that of the above-described embodiment can be obtained.

<Preferable Aspect of the Present Invention>
Hereinafter, preferred embodiments of the present invention will be described.

(Appendix 1)
According to one aspect of the invention
A multi-core cable inspection device that specifies the correspondence between the insulated wires at both ends of a multi-core cable having a plurality of insulated wires.
A signal input means for inputting an inspection signal by capacitive coupling to the end of the insulated wire to be inspected among the ends of the plurality of insulated wires exposed at one end of the multi-core cable.
A signal output means for outputting an inspection signal by capacitive coupling from each end of the plurality of insulated wires exposed at the other end of the multi-core cable.
A corresponding specifying means for measuring the voltage of the inspection signal obtained from the signal output means and specifying the other end of the insulated wire to be inspected based on the measured voltage is provided.
At least one of the signal input means and the signal output means has a signal transmission cable for transmitting an inspection signal and a substrate to which the signal transmission cable is connected.
A first electrode to which the signal conductor of the signal transmission cable is connected is provided on one main surface of the substrate.
A second electrode capacitively coupled to the end of the insulated wire is provided on the other main surface of the substrate.
Inside the substrate, a transmission path for transmitting the inspection signal between the first electrode and the second electrode is provided.
The substrate is provided with a shield layer that suppresses noise from entering the transmission line.
A multi-core cable inspection device is provided.

(Appendix 2)
Preferably,
The shield layer is a first shield layer that surrounds the circumference of the first electrode while maintaining a non-contact state with the first electrode on one of the main surfaces, and the second electrode on the other main surface. It has at least one of the second shield layers surrounding the second electrode while maintaining a non-contact state with the second electrode.
The multi-core cable inspection device described in Appendix 1 is provided.

(Appendix 3)
Preferably,
A plurality of the first electrodes are provided on one of the main surfaces.
The first shield layer is provided on one of the main surfaces so as to collectively surround the entire plurality of the first electrodes.
The multi-core cable inspection device described in Appendix 2 is provided.

(Appendix 4)
Preferably,
A plurality of the second electrodes are provided on the other main surface, and the second electrodes are provided on the other main surface.
A plurality of the second shield layers are provided on the other main surface so as to individually surround each of the plurality of the second electrodes.
The multi-core cable inspection device according to Appendix 2 or 3 is provided.

(Appendix 5)
Preferably,
The plurality of second shield layers are provided on the other main surface so as to maintain a non-contact state with each other.
The multi-core cable inspection device described in Appendix 4 is provided.

(Appendix 6)
Preferably,
The first electrode and the second electrode are provided at positions that do not face each other with the substrate interposed therebetween.
The transmission line has a portion inside the substrate extending along the inward direction (planar direction) of the main surface of the substrate so as to connect the first electrode and the second electrode.
The multi-core cable inspection device according to any one of Supplementary note 2 to 5 is provided.

(Appendix 7)
Preferably,
The shield layer has a third shield layer that spreads in a plane along the inside direction of the main surface of the substrate inside the substrate.
A portion of the transmission line extending along the inward direction (planar direction) of the main surface of the substrate in the third shield layer and at least one of the first shield layer and the second shield layer. Is configured to sandwich
The multi-core cable inspection device described in Appendix 6 is provided.

(Appendix 8)
According to another aspect of the invention.
A method for inspecting a multi-core cable that specifies the correspondence between the insulated wires at both ends of the multi-core cable having a plurality of insulated wires.
A signal input step of inputting an inspection signal by capacitive coupling to the end of the insulated wire to be inspected among the ends of the plurality of insulated wires exposed at one end of the multi-core cable.
A signal output step of outputting an inspection signal by capacitive coupling from each end of the plurality of insulated wires exposed at the other end of the multi-core cable.
A corresponding identification step of measuring the voltage of the inspection signal obtained by performing the signal output step and specifying the other end of the insulated wire to be inspected based on the measured voltage.
Have,
At least one of the signal input step and the signal output step
It has a first electrode on one main surface to which the signal conductor of a signal transmission cable for transmitting an inspection signal is connected, a second electrode on the other main surface, and the first electrode and the second electrode inside. Using a substrate having a transmission path for transmitting an inspection signal between the electrodes, the second electrode and the end of the insulated wire are capacitively coupled.
The shield layer provided on the substrate suppresses noise from entering the transmission line.
A method for inspecting multi-core cables is provided.

1 Inspection device 2 Multi-core cable 3 Insulated wire 4 Signal input means 6 Signal output means 44, 61 Board 47, 67 Signal transmission cable 81 Corresponding specific means 441 1st electrode 442 2nd electrode 430 Transmission line 431 Vertical transmission line 432 Transmission line 449 Shield layer 447 1st shield layer 448 2nd shield layer 444 3rd shield layer

Claims (8)

A multi-core cable inspection device that specifies the correspondence between the insulated wires at both ends of a multi-core cable having a plurality of insulated wires.
A signal input means for inputting an inspection signal by capacitive coupling to the end of the insulated wire to be inspected among the ends of the plurality of insulated wires exposed at one end of the multi-core cable.
A signal output means for outputting an inspection signal by capacitive coupling from each end of the plurality of insulated wires exposed at the other end of the multi-core cable.
A corresponding specifying means for measuring the voltage of the inspection signal obtained from the signal output means and specifying the other end of the insulated wire to be inspected based on the measured voltage is provided.
At least one of the signal input means and the signal output means has a signal transmission cable for transmitting an inspection signal and a substrate to which the signal transmission cable is connected.
A first electrode to which the signal conductor of the signal transmission cable is connected is provided on one main surface of the substrate.
A second electrode capacitively coupled to the end of the insulated wire is provided on the other main surface of the substrate.
Inside the substrate, a transmission path for transmitting the inspection signal between the first electrode and the second electrode is provided.
The substrate is provided with a shield layer that suppresses noise from entering the transmission line.
Multi-core cable inspection device. The shield layer is a first shield layer that surrounds the circumference of the first electrode while maintaining a non-contact state with the first electrode on one of the main surfaces, and the second electrode on the other main surface. It has at least one of the second shield layers surrounding the second electrode while maintaining a non-contact state with the second electrode.
The multi-core cable inspection device according to claim 1. A plurality of the first electrodes are provided on one of the main surfaces.
The first shield layer is provided on one of the main surfaces so as to collectively surround the entire plurality of the first electrodes.
The multi-core cable inspection device according to claim 2. A plurality of the second electrodes are provided on the other main surface, and the second electrodes are provided on the other main surface.
A plurality of the second shield layers are provided on the other main surface so as to individually surround each of the plurality of the second electrodes.
The multi-core cable inspection device according to claim 2 or 3. The plurality of second shield layers are provided on the other main surface so as to maintain a non-contact state with each other.
The multi-core cable inspection device according to claim 4. The first electrode and the second electrode are provided at positions that do not face each other with the substrate interposed therebetween.
The transmission line has a portion extending inside the substrate along the inward direction of the main surface of the substrate so as to connect the first electrode and the second electrode.
The multi-core cable inspection device according to any one of claims 2 to 5. The shield layer has a third shield layer that spreads in a plane along the inside direction of the main surface of the substrate inside the substrate.
The third shield layer and at least one of the first shield layer and the second shield layer sandwich the portion of the transmission path extending along the inward direction of the main surface of the substrate. It is configured,
The multi-core cable inspection device according to claim 6. A method for inspecting a multi-core cable that specifies the correspondence between the insulated wires at both ends of the multi-core cable having a plurality of insulated wires.
A signal input step of inputting an inspection signal by capacitive coupling to the end of the insulated wire to be inspected among the ends of the plurality of insulated wires exposed at one end of the multi-core cable.
A signal output step of outputting an inspection signal by capacitive coupling from each end of the plurality of insulated wires exposed at the other end of the multi-core cable.
A corresponding identification step of measuring the voltage of the inspection signal obtained by performing the signal output step and specifying the other end of the insulated wire to be inspected based on the measured voltage.
Have,
At least one of the signal input step and the signal output step
It has a first electrode on one main surface to which the signal conductor of a signal transmission cable for transmitting an inspection signal is connected, a second electrode on the other main surface, and the first electrode and the second electrode inside. Using a substrate having a transmission path for transmitting an inspection signal between the electrodes, the second electrode and the end of the insulated wire are capacitively coupled.
The shield layer provided on the substrate suppresses noise from entering the transmission line.
How to inspect a multi-core cable.

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