JPH11108979A - Cable monitoring apparatus - Google Patents

Abstract

PROBLEM TO BE SOLVED: To enable accurately determining of disconnected condition of a plurality of cables, even when monitoring disconnection of the cables sequentially as installed at a location where noises are easily received. SOLUTION: A controller 40 sends a signal to a terminal changeover switch 27 to electrically connect a first detection terminal 28 of a current detector 26 to a second input terminal 22 (at rest for measurement), while sending a signal to a cable connection switch 20 to connect first and second tip terminals 11 and 12 of a cable CAk respectively to first and second input terminals 21 and 22. After a time ta passes, a second detection terminal 29 of the current detector 26 is electrically connected to the second input terminal 22 (in measurement). Thereafter, the value of a current flowing through a first pilot wire L1, a terminal resistance Re and a second pilot wire L2 from the current detector 26 to judge whether any of the first and the second pilot wires L1 and L2 is disconnected or not or others.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a cable monitoring device for detecting a cable break.

[0002]

2. Description of the Related Art Generally, a cable has a plurality of core wires insulated from each other. As a method for grasping that the insulation between the core wires of the cable has decreased, the following method has been conventionally known. That is, two pilot wires are provided on the insulator of the cable, the ends of both pilot wires are open, and a voltage is applied to the tips. Then, the current flowing at this time is measured, and if the current value exceeds a predetermined current threshold value, it is determined that the insulation of both pilot lines is defective. If it is determined that both pilot wires have insulation failure, the core wires of the cable may also have insulation failure or may be in danger.

[0003]

However, as described above, there has been known a method of detecting insulation failure between core wires of a cable, but no method of determining disconnection of a cable has been known. Therefore, the inventor of the present invention, as exemplified in FIG. 4, has the terminal 1 of both pilot lines L1, L2.
A device for connecting a terminal resistor Re between the terminals 3 and 14 and applying a voltage between the terminals 11 and 12 of the pilot lines L1 and L2 and detecting a current flowing at that time by a current detector is devised. did. In this case, current flows if neither of the pilot lines L1 and L2 is disconnected, and no current flows if at least one of the pilot lines L1 and L2 is disconnected. Here, if at least one of the pilot lines L1 and L2 is disconnected, the core line (signal line) of the cable may be disconnected or may be disconnected. For this reason, based on the detection signal (current value) of the current detector, the disconnection state of the core wire of the cable can be grasped.

[0004] By the way, if the place where the cable is laid is a place with much noise, for example, in the station yard of a railway car,
Because the cable picks up noise, both pilot lines L1, L
2 cannot be accurately measured. To avoid this inconvenience, it is conceivable to incorporate a capacitor as a noise cut filter circuit (see FIG. 5).

However, when a plurality of cables are sequentially inspected for disconnection as shown in FIG. 5, if such a filter circuit is present, both pilot lines L which have been inspected last time are examined.
If at least one of L1 and L2 is disconnected, the capacitor of the filter circuit remains charged and not discharged. Therefore, the current flowing through the pilot lines L1 and L2 of the cable to be tested this time is checked. Initially, it will be covered by a capacitor. For this reason, since the current detected by the current detector is small, there is a possibility that it is erroneously determined that both pilot lines L1 and L2 are disconnected even though neither of them is disconnected.

SUMMARY OF THE INVENTION The present invention has been made in view of the above problems, and has a cable monitoring device capable of accurately grasping a disconnection state even when a plurality of cables laid in a place susceptible to noise are sequentially monitored for disconnection. It is intended to provide a device.

[0007]

Means for Solving the Problems and Effects of the Invention To solve the above problems, the present invention provides a first pilot line having a first end terminal and a first end terminal, a second pilot terminal and a second end terminal. A cable monitoring device for sequentially monitoring a plurality of cables including a second pilot line having a terminal,
A terminal resistance connected between the first and second terminal terminals, cable connection means for connecting each of the first and second terminal terminals to each of first and second input terminals,
One of the two power terminals has a power source connected to the first input terminal, a first and a second detection terminal, and measures a current flowing between the two detection terminals. A current detecting means connected to a power terminal of the two power terminals opposite to the first input terminal; and one of the first and second detecting terminals of the current detecting means. Terminal switching means connected to the second input terminal;
A signal path connecting the terminal switching means-the second input terminal and the first input terminal-the first power supply terminal of the two power supply terminals;
A capacitor connected between the input terminal and a signal path connecting the power supply terminal.

In this cable monitoring device, a terminal resistor is connected between the ends of both pilot lines provided in the cable, a voltage is applied to the ends of both pilot lines by a power supply, and a current flowing at that time is applied. Detected by current detection means. In this case, a current flows if neither of the pilot lines is disconnected, and no current flows if at least one of the pilot lines is disconnected. Here, if at least one of the two pilot lines is disconnected, the core line (signal line) of the cable may be disconnected or may be disconnected. For this reason, based on the detection signal (current value) of the current detection means, the disconnection state of the core wire of the cable can be grasped.

Further, in this cable monitoring device, each of the first and second end terminals of each pilot line of the predetermined cable is connected to each of the first and second input terminals by the cable connecting means. Before or simultaneously with this connection, the terminal switching means causes the capacitor to discharge for a time sufficient to discharge the capacitor (the first detection terminal of the current detection means and the second input terminal are connected to each other, and (State in which no current flows through the detection means). Here, if at least one of the two pilot lines of the cable tested last time is broken, the capacitor of the filter circuit remains charged without being discharged. And then switch to a measurement state (a state in which the second detection terminal and the second input terminal of the current detection means are connected and a current is supplied to the current detection means) to measure the current flowing through both pilot lines of the cable to be inspected this time. Since detection is performed, the detected current value is not affected by the capacitor. Even if the cable picks up noise, the noise is cut by the capacitor, so that the detected current value is not affected by the noise.

Therefore, according to the cable monitoring apparatus, even when the disconnection is monitored sequentially for a plurality of cables laid in a place susceptible to noise, the effect that the disconnection state can be accurately grasped can be obtained. . The cable monitoring device according to the present invention, when each of the first and second end terminals and each of the first and second input terminals are connected by the cable connection unit, instructs the terminal switching unit to output the capacitor. The first detection terminal of the current detection means and the second detection terminal for a time sufficient to discharge
Terminal switching control means for connecting the input terminal to the input terminal, and then instructing the terminal switching means to connect the second detection terminal of the current detection means to the input terminal; and After the switching unit connects the second detection terminal of the current detection unit and the input terminal,
Determining means for determining whether or not the first or second pilot line has been disconnected based on a detection signal detected by the current detecting means; and determining that the first or second pilot line has been disconnected by the determining means. Notification means for notifying the outside when the judgment is made may be provided.

In this case, the terminal switching control unit instructs the terminal switching unit to switch between the measurement suspension state and the measurement state so that the detected current value is not affected by the capacitor. Based on the detected current value, it is determined whether or not the first or second pilot line has been disconnected. If the first or second pilot line has been disconnected, the notification unit notifies the outside. For this reason, the operator does not need to check the current value detected by the current detecting means to determine the presence / absence of a disconnection by himself, and the effect of reducing the work load can be obtained. The determining means may compare the detected current value with a current threshold value for disconnection determination and determine whether or not a disconnection has occurred according to the result. The resistance (line-to-line resistance) may be obtained, the line-to-line resistance value may be compared with a resistance threshold value for disconnection determination, and it may be determined whether or not a disconnection has occurred according to the result.

Here, the judging means further judges whether or not insulation between the first pilot line and the second pilot line has become defective based on the detection signal detected by the current detecting means. The notifying unit may be configured to notify the outside when the judging unit judges that the insulation failure has occurred between the first pilot line and the second pilot line. In this case, the judging means also judges an insulation failure between the two pilot lines, and in the case of an insulation failure, the notifying means notifies outside. For this reason, the disconnection state of the cable can be grasped by one device, and the insulation state of the cable can be grasped. In this case, the measurement suspension state is set to the longer of the time sufficient for discharging the capacitor and the time sufficient for charging the capacitor. The determining means may compare the detected current value with a current threshold value for determining insulation failure, and determine whether or not insulation is defective according to the result. (Line resistance), the line resistance value may be compared with a resistance threshold value for determining insulation failure, and it may be determined whether or not insulation is defective according to the result.

Further, the cable monitoring device of the present invention sequentially selects one cable from the plurality of cables, and connects each of the first and second end terminals of the selected cable to the first cable by the cable connection means. And a cable connection control means for connecting to each of the second input terminal and the second input terminal. In this case, since the cable connection control means sequentially switches the cables, the operator's work load is further reduced.

Further, it is preferable that the first and second pilot wires are provided outside a core wire of the cable. In this case, for example, even if either one of the two pilot lines is broken, the two pilot lines are arranged outside the core line (signal line), so that the inner core line is also broken. Not exclusively. For this reason, it is possible to grasp not only when the core of the cable is disconnected but also when the core of the cable is shortly disconnected. Further, for example, even if the insulation between the two pilot wires is defective, the insulation is not always defective up to the core wire. For this reason, in addition to the case where the insulation between the core wires of the cable becomes defective, the situation where the insulation between the core wires of the cable soon becomes defective can be grasped.

[0015]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Preferred embodiments of the present invention will be described below with reference to the drawings. FIG. 1 is a schematic configuration diagram of the present embodiment, and FIG. 2 is a sectional view of a cable. As shown in FIG. 1, this cable monitoring device includes a plurality of (n) cables C
A ₁ to CA _n, the cable connection switch 20, a current measuring circuit 30, the controller 40 includes an alarm device 41, the resistance display 42.

As shown in FIG. 2, the cable CA _k (k is an integer from 1 to n) includes a plurality of core wires 15, 15,.
, And the first and second parts provided outside these core wires 15.
Pilot lines L1, L2 and inclusions 1 surrounding them
6, a sheath 17 surrounding the outer periphery of the inclusion 16, and a sheath 1
7 and a steel strip 18 provided in the inside. The core wire 15 has a structure in which a conductor 15a is covered with an insulator 15b, and the first and second pilot wires L1 and L2 have the same structure. In addition, as shown in FIG.
1 has a first end terminal 11 and a first end terminal 13, and the second pilot line L2 is connected to the second end terminal 12 and the second end terminal 13.
An end terminal 14 is provided. A terminal resistance Re (here, 2 MΩ) is provided between the first and second terminal terminals 13 and 14.
Is connected.

The cable connection switch as cable connection means 20, respectively of the first and second input terminals 21 and 22, first and second primary cable CA _k of the plurality of cables CA ₁ to CA _n This is for connecting each of the tip terminals 11 and 12. The cable connection switch 20 is operated by a command from the outside, and in this embodiment, is operated by a command signal from the controller 40.

The current measuring circuit 30 is a circuit for measuring the current flowing through the first pilot line L1- terminal resistor Re- second pilot line L2 in the cable CA _k.
In the current measuring circuit 30, the first input terminal 21 is connected to one (negative) power supply terminal 24 of the DC power supply 23. A current detector 26 as a current detecting means measures a current flowing between the first and second detection terminals 28 and 29. The first detection terminal 28 is connected to the other (plus) power supply terminal 25 of the DC power supply 23. It is connected to the.

Terminal switch 2 as terminal switching means
7 are first and second detection terminals 28, 2 of the current detector 26;
9 is a switch for selectively connecting any one of the switches 9 to the second input terminal 22. In this embodiment, the terminal changeover switch 27 is controlled by the controller 4 in accordance with an external command.
It is activated by a command signal from 0. The state in which the first detection terminal 28 of the current detector 26 is connected to the second input terminal 22 by the terminal changeover switch 27 is a measurement pause state, and the second detection terminal 29 of the current detector 26 is connected to the second input terminal 22. The connected state is referred to as a measurement state.

The capacitor C is connected to a terminal switch 27-
The signal path Lb connecting the second input terminal 22 and the first input terminal 2
1-DC power supply 23 is connected to a signal path La connecting one power supply terminal 24. Resistors R2 and R4 for limiting the current flowing into the capacitor C are provided in the signal path La.
Are provided, and the resistors R1 and R3 are also provided in the signal path Lb. These capacitors C and resistors R1 to R
Reference numeral 4 denotes a filter circuit 31 for cutting off noise when the first and second pilot lines L1 and L2 of the cable CAk (k is any integer from 1 to n) pick up surrounding noise. That is, the filter circuit 31 prevents the current detector 26 from erroneously detecting due to noise. Such a filter circuit 31 is useful when monitoring a cable provided in a noisy place such as in a railway station. Note that a plurality of filter circuits 31 may be provided according to the magnitude of noise.

The controller 40 includes a well-known CPU, RO
M, RAM, clock, counter, etc. The device is connected so that the detection signal from the current detector 26 can be input, and is connected to the cable connection switch 20, terminal switch 27, alarm device 41, and resistance display device 42. It is connected so that a control signal can be output. Alarm device 41 is used for displaying the monitoring status of the cable CA ₁ to CA _n to a display (not shown), the cable C of the resistor display device 42 during measurement
It is intended to display a line-to-line resistance of the A first and second pilot lines _k L1, L2. The controller 40 corresponds to a cable connection control unit, a terminal switching control unit, and a determination unit, and the alarm device 41 corresponds to a notification unit.

Next, the operation of the cable monitoring device of the present embodiment will be described. FIG. 3 is a flowchart of the cable monitoring process executed by the controller of the cable monitoring device. Various control programs are recorded in a ROM (not shown) of the controller 40, and one of them is a cable monitoring program. When a not-shown monitoring execution switch is turned on, the CPU (not shown) of the controller 40 executes the cable monitoring process shown in FIG. 3 based on the cable monitoring program.

When this processing is executed, first, in S201
In, the controller 40 resets the value k of the cable number counter (not shown), and then in S202, increments the value k of the cable number counter. In the following S203, the controller 40 sends a signal to the terminal changeover switch 27 and the first
The detection terminal 28 and the second input terminal 22 are electrically connected (that is, brought into a measurement pause state), and a signal is sent to the cable connection switch 20 to connect the first and second end terminals 11 and 12 of the cable CA _k . Each is connected to each of the first and second input terminals 21 and 22.

In the following S204, the controller 40
Determines whether a predetermined time ta (a time sufficient for charging or discharging the capacitor C, whichever is longer) has elapsed. If the predetermined time ta has elapsed in S204, a signal is sent to the terminal switch 27 in S205, and the second
The detection terminal 29 and the second input terminal 22 are electrically connected (that is, brought into a measurement state), and the process proceeds to S206. on the other hand,
If the predetermined time ta has not elapsed in S204,
It waits until the predetermined time ta elapses.

If it is determined in S206 that the wire is broken, in S207, the controller 40 sends a signal to the alarm device 41 to notify the alarm device 41 to the outside. For example, the alarm device 41 uses the cable CA _k
The first or at least one of the second pilot line L1, L2 is that the disconnected or displayed on a display not shown (or core wire or cable CA _k is disconnected, or there that its risk) of, Or sound an alarm. Then, the process proceeds to S208. On the other hand, if it is determined in S206 that there is no disconnection, the process proceeds to S2.
Proceed to 08.

[0026] In S208, the controller 40 based on a detection signal of the current detector 26, in turn determines whether insulation failure between the first and second pilot lines L1, L2 of the cable CA _k . Specifically, the current value Im detected by the current detector 26 is compared with a current threshold value It2 for judging insulation failure, and if the current value Im is equal to or smaller than the current threshold value It2, insulation is satisfactory and current is not increased. If it exceeds the threshold value It2, it is determined that the insulation is defective. Alternatively, the current detector 2
6, the pilot lines L1, L2
Is determined, and the line resistance Rm is compared with a resistance threshold Rt2 for determining insulation failure. If the resistance Rt2 exceeds the resistance threshold Rt2, insulation is satisfactory, and the resistance threshold Rt2 is determined.
If it is below, it may be determined that insulation is defective.

If it is determined in S208 that the insulation is defective, in S209, the controller 4
0 sends a signal to the alarm device 41, and the alarm device 41 notifies the outside. For example, the alarm device 41, or the insulation between that insulation between the first and second pilot lines L1, L2 of the cable CA _k is defective (or cable CAk core is defective, or there is the possibility Is displayed on a display (not shown) or an alarm is sounded. Then, the process proceeds to S210. On the other hand, if it is determined in S208 that the insulation is good, the process proceeds to S210.
Proceed to.

In S210, it is determined whether or not the value k of the cable number counter matches a predetermined number n (total number of cables). If they do not match, the processing from S202 onward is repeated. Repeat the process. In the present embodiment, the controller 40 determines the first value of the cable CA _k from the current value Im from the current detector 26.
Then, the line resistance Rm of the second pilot lines L1 and L2 is calculated, and the resistance display device 42 displays the line resistance Rm. Line resistance Rm displayed on the resistance display device 42
Is a value obtained by the controller 40 calculating the combined resistance Rs from the current value Im and calculating 1 / Rs = 1 / Re + 1 / Rm. The operator determines that both pilot lines L1 and L2 are normal if the line resistance Rm displayed on the resistance display device 42 is, for example, 1 to 3 MΩ. If the line resistance Rm is 1 MΩ or less, insulation between the two pilot lines L1 and L2 is defective. (Cable C
Determines that A core wires of _k is or fear that a poor insulation), if more than 3MΩ both pilot line L1,
At least one of L2 can be determined that the disconnection (core of the cable CA _k there is or risk thereof is broken).

In the cable monitoring process described above,
In step S205, the measurement is suspended before the predetermined time ta elapses, and the terminal changeover switch 27 is controlled to be in the measurement state after the predetermined time ta elapses. The fluctuation of the detection value of the current detector 26 is eliminated.

[0030] That is, for example, previous and cable CA _k-1 which is connected to the first and second input terminals 21 and 22 short-circuited, when the current cable CA _k is assumed that the normal, the cable CA _k Immediately after the connection is switched, the capacitor C is charged from a state where it is not sufficiently charged. At this time, if the second detection terminal 29 and the second input terminal 22 are connected by the terminal switch 27, that is, if a current flows through the current detector 26,
Since the current detector 26 detects the value of the current flowing to charge the capacitor C, it detects a large current value. For this reason, even though the first and second pilot lines L1 and L2 of the cable CA _k are normal, a large current value is detected, and thus the first and second pilot lines L1 and L2 of the cable CA _k are detected. May be judged as insulation failure. To overcome this fear, is immediately after switching is connected to the cable CA _k, a measurement hibernation is had to detect the current thereafter switched from lost the influence of the capacitor C to the measurement state.

The first and second input terminals 21, 2
Cable CA to which 2 was connected_{k- 1}Is disconnected,
This time cable CA_kIs normal,
Bull CA_k Immediately after the connection is switched, the capacitor C
Will discharge from a fully charged state,
Bull CA_kOf the first pilot line L1-terminal resistance Re-
2 The current flowing through pilot line L2 is
It's not covered by the capacitor C
Will be At this time, the second detection is performed by the terminal switch 27.
If the output terminal 29 and the second input terminal 22 are connected,
The current detector 26 detects a small current value. For this reason,
Cable CA_kOf the first and second pilot lines L1, L2
Is normal, but a small current value is detected.
Cable CA_kFirst and second pilots
It is determined that one of the lines L1 and L2 is disconnected.
There is it. In order to eliminate this fear, the cable C
A _kImmediately after the connection is switched to
After that, the effect of the capacitor C disappears,
They switched to measure the current.

[0032] As described above in detail, according to the cable monitoring apparatus, the effect is obtained that the breakage situation of the cable CA _k can be easily grasped. Further, the operator may judge the presence or absence of disconnection by watching the line resistance Rm of the resistance display device 42. However, if the cable CA _k is disconnected or there is a possibility of disconnection, the alarm device 41 is used. Since the notification is made, it is not necessary to judge the presence or absence of disconnection by itself, and the effect that the work load is reduced is obtained. Moreover, since both pilot line L1, L2 is provided outside the core 15, grasp of course when the core wire 15 of the cable CA _k is disconnected, even a situation where the core wire 15 of the cable CA _k will shortly break it can. Furthermore, since a so-called polling method (a method of sequentially switching cables) is employed, an effect that the device configuration is compact can be obtained. In addition, since the ends of the first and second pilot lines L1 and L2 are connected to each other, it is possible to obtain the effect of being able to grasp the disconnection state of the cable and the insulation state of the cable with one device.

In particular, according to the above cable monitoring device, the following effects can be obtained. That is, the detected current value is not affected by the noise because the noise is cut by the capacitor C of the filter circuit 31, and the detection current value is temporarily stopped after the cable is switched, and then switched to the measurement state to detect the current. It is not affected by C. Therefore, even in the case of monitoring the sequential breakage plurality of cables CA ₁ to CA _n laid in place susceptible to noise, the effect is obtained that the breakage situation can be accurately grasped.

The embodiments of the present invention are not limited to the above-mentioned embodiments at all, and it goes without saying that various forms can be adopted as long as they fall within the technical scope of the present invention. For example, the controller 40 switches the cable connection switch 20 and the terminal switch 27 at a predetermined timing.
It is good also as a structure which switches 0 and 27 manually.

The cables CA _{1 to} C to be monitored are
_An is not necessarily required to be plural, but may be one.
Furthermore, the cable CA _k used in the above embodiment, the first and second pilot line L1, L2 is provided on the outside of the core 15, any two first and second pilot plurality of core wires 15 It may be a line.

[0036] Furthermore, omitting the cable CA _k per second pilot line L2 used in the above embodiment, the steel strip 1
8 may be used instead of the second pilot line L2. In this case, the cable monitoring device determines whether the first pilot line L1 or the steel strip 18 is disconnected,
The state of insulation between them will be understood.

[Brief description of the drawings]

FIG. 1 is a schematic configuration diagram of the present embodiment.

FIG. 2 is a sectional view of a cable.

FIG. 3 is a flowchart of a cable monitoring process according to the embodiment.

FIG. 4 is a schematic configuration diagram of a cable monitoring device capable of grasping a cable break.

FIG. 5 is a schematic configuration diagram of a cable monitoring device with a filter circuit.

[Explanation of symbols]

30: current measuring circuit, 11: first terminal, 1
2 ... second end terminal, 13 ... second end terminal, 14
... 2nd terminal terminal, 15 ... core wire, 20 ... cable connection switch, 21 ... first input terminal, 22 ...
· A second input terminal, 23 · · · DC power supply, 24 · · · one power supply terminal, 25 · · · the other power supply terminal, 26 · · · current detector, 27 · · · terminal switch, 28 · · · · 1st detection terminal, 29: 2nd detection terminal, 31: filter circuit, 40: controller, 41: alarm device, 42: resistance display device, C: capacitor, C
A ₁ to CA _n · · · cable, L1 · · · first pilot line, L2 · · · second pilot line, Re · · · terminal resistor.

 ──────────────────────────────────────────────────続 き Continuing on the front page (72) Inventor Takeo Katsumoto 1-4-1 Meiji Station, Nakamura-ku, Nagoya, Aichi Prefecture Inside Tokai Passenger Railway Co., Ltd. (72) Inventor Masayuki Yamamoto Meiji Station, Nakamura-ku, Nagoya-shi, Aichi 1-4-1 Tokai Passenger Railway Co., Ltd. (72) Inventor Akihiko Yagi 1-4-1 Meieki, Nakamura-ku, Nagoya-shi, Aichi Prefecture 1-4-1 Tokai Passenger Railway Co., Ltd. (72) Inventor Masaaki Yanagawa Meguro-ku, Tokyo 1-6-30 Meguro Inside Toho Denki Kogyo Co., Ltd. (72) Inventor Masunori Kataoka 1-6-30 Meguro Meguro-ku Tokyo

Claims (5)

[Claims] 1. A plurality of cables having a first pilot line having a first terminal and a first terminal and a second pilot line having a second terminal and a second terminal are sequentially monitored. And a terminal resistor connected between the first and second terminal terminals, and connecting each of the first and second terminal terminals to a first and second input terminal, respectively. A cable connecting means, a power supply having one of the two power supply terminals connected to the first input terminal, and a first and second detection terminal, and measuring a current flowing between the two detection terminals, A current detection means having a first detection terminal connected to a power supply terminal of the two power supply terminals opposite to the first input terminal; and any one of the first and second detection terminals of the current detection means Alternatively connected to the second input terminal. A terminal switching means for the terminal switching means - the second signal path connecting the input terminal and the first input terminal - the first of said two power supply terminals
A cable monitoring device comprising: a capacitor connected between the input terminal and a signal path connecting a power supply terminal. 2. The cable monitoring device according to claim 1, wherein each of the first and second end terminals and each of the first and second input terminals are connected by the cable connection unit. Connecting the first detection terminal and the second input terminal of the current detection means for a time sufficient to instruct the terminal switching means to discharge the capacitor;
Terminal switching control means for instructing the terminal switching means to connect the second detection terminal of the current detection means to the input terminal; and in response to a command from the terminal switching control means, the terminal switching means sets the current detection means After connecting the second detection terminal and the input terminal, the determination means for determining whether the first or second pilot line is disconnected based on a detection signal detected by the current detection means, A cable monitoring device comprising: a notifying unit that notifies the outside when the first or second pilot line is disconnected by the determining unit. 3. The cable monitoring device according to claim 2, wherein the judging unit further insulates between the first and second pilot lines based on a detection signal detected by the current detecting unit. A cable for judging whether or not the cable is defective, and further comprising: notifying to the outside when the judging means judges that the first or second pilot wire is defective in insulation. Monitoring device. 4. The cable monitoring device according to claim 1, wherein one cable is sequentially selected from the plurality of cables, and the first and second end terminals of the selected cable are selected. Cable connection control means for connecting each of the first and second input terminals to each of the first and second input terminals by the cable connection means. 5. The cable monitoring device according to claim 1, wherein the first and second pilot lines are provided outside a core of the cable. Cable monitoring device.