JPH05333084A - Discrimination method for a plurality of cables - Google Patents

Abstract

PURPOSE:To improve work efficiency by discriminating easily and surely each cable contained in protection pipes and the like. CONSTITUTION:In a discrimination method for a plurality of cables in which a plurality of cables contained in protection pipes and the like, are discriminated, a signal impression part 10 impresses a synthesized signal of three kinds of specific frequency signals with different combination among oscillating 6 kinds of specific frequency signals to each cable core line (a core line 31 of cable 30i among the above cables is shown in the figure). Then, the synthesized signal is detected by a detection circuit 22 by way of electrodes 21 connected with electrostatic capacity to the cable 30i and the synthesized signal is processed in signal processing circuits 23a to 23f to discriminate the three kinds of specific frequency signals constituting the synthetic signal and discriminate the cable 30i.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a method for identifying a plurality of cables for identifying a plurality of cables housed in a protection tube, for example.

[0002]

2. Description of the Related Art Usually, for cable laying work, a plurality of cables are pierced in the same protection tube, and each cable is branched in the next relay box and pierced in the next protection tube to lead to each destination. There are cases. In such a case, there has been a demand for a method of reliably identifying each of the above cables in the relay box.

Conventionally, in response to the above demands, a protective tube is used as a ground, an operator sequentially connects each cable to the ground at the inlet of the protective tube, and another worker uses a tester at the outlet of the protective tube. There is a continuity check method for finding a cable that is conducting and confirming each cable using. In addition, after attaching an identification label to the tip of each cable, insert the above cables into the protective tube,
There is also a labeling method for identifying each cable by the above label.

[0004]

However, in the above continuity check method, a vinyl chloride protective tube is often used as the protective tube in order to reduce the cost. In such a case, a new ground is provided. It is necessary to provide. Also, since the workers at the entrance and exit check the cables while responding to each other, if the entrance and exit of the protective tube are long distances, a communication tool for both is required, and if there are many relay boxes, There was a problem that the working efficiency was poor because the worker had to wait on the insertion end side of the cable.

In addition, in the labeling method, there is a risk that the label may fall off while the cable is moving inside the protective tube, and a label that is easy to identify for each cable and that does not get in the way when passing through the protective tube is provided. Therefore, various measures have to be taken, resulting in a problem that work efficiency is deteriorated. The present invention has been made in view of the above problems, and an object of the present invention is to provide a method for identifying a plurality of cables that can easily and surely identify each cable to improve work efficiency.

[0006]

In order to achieve the above object, in the present invention, in a method of identifying a plurality of cables for identifying a plurality of accommodated cables, a plurality of combinations of signals of different specific frequencies are combined, The composite signal is directly applied to each of the cables, and the composite signal is detected from each of the cables by an electrostatic coupling method,
Further, there is provided a method of identifying a plurality of cables for identifying each of the cables by identifying signals of a plurality of specific frequencies that constitute the composite signal.

[0007]

From the plurality of frequency signals, for example, a composite signal of three kinds of frequency signals having different combinations is applied to each cable from the signal applying section, and the non-contact signal detecting section of the capacitive coupling is used for the above-mentioned The combined signal is detected, and three types of frequency signals forming the detected combined signal are identified.

Therefore, the composite signal applied to each cable has a substantially zero probability that potential signals of the same level are simultaneously input, so that each cable can be efficiently identified without making an erroneous determination.

[0009]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS An embodiment of the present invention will be described with reference to the drawings of FIGS. FIG. 1 is a block diagram showing a configuration of an identification device using the method for identifying a plurality of cables according to the present invention.
In the figure, the identification device, a plurality of combined potential signals of a specific frequency, is inserted into a protective tube (not shown),
A signal applying unit 10 for applying to the core wire of each insulation-coated cable, and a relay box (not shown) separated from the signal applying unit 10 in a non-contact manner with one of the cables, for example, the cable 30i, Alternatively, it comprises a signal detection unit 20 which contacts with each other to detect the applied potential signal of a specific frequency and sequentially identify each cable.

As shown in FIG.
6 different specific frequencies f ₁~ F₆Potential signal
(Hereinafter referred to as "frequency signal")
From the wave number oscillation circuits 11a to 11f and these frequency signals,
Combination combining circuit for combining three kinds of signals in different combinations
12 and a mark for applying the composite signal to the core wire of each cable
It is sandwiched between the additional circuits 13a to 13t and the respective core wires, and
The composite signal from the adder circuits 13a to 13t is applied to each core wire.
Clips 14a-14t such as worm clip
It is configured.

[0011] The specific frequency oscillation circuit 11a~11f is, for example, usually are not being used or so six types of frequency f ₁ ~
It is a signal source for oscillating the sine wave potential signal of f ₆ . Note that the oscillator circuit according to the present invention may use, for example, a circuit that oscillates a specific frequency signal at regular time intervals, in addition to this embodiment. Combination synthesis circuit 1
2 synthesizes three types of signals in different combinations from the above-mentioned six types of frequency signals to be input and outputs them. The number K of different combinations is K = N! / N!・ (NM)! However, N is the number of signal sources and M is the number of samples of the combination. In the case of this embodiment, N = 6 and M =
Therefore, if this value is substituted into the above equation, K = 20. That is, in this embodiment, up to 20 cables can be identified at the same time. Therefore, in this embodiment, 20 application circuits and 20 clips are required.

The signal detecting section 20 is connected to the metal electrode 21 arranged in a non-contact manner or in contact with the insulation-coated specific cable 30i and the metal electrode 21 to detect a potential signal from the core wire 31. Detection circuit 22 and a signal processing circuit 23 that performs predetermined signal processing on the detected potential signal.
a to 23f and the above-mentioned processed six outputs CH1 to CH
6 is composed of three combination circuits 24 each, AND circuits 25a to 25t each performing a logical AND operation on each of the three combined outputs, and display circuits 26a to 26t displaying the calculation results. There is.

In the detection section 20, there is a very small electrostatic capacitance between the metal electrode 21 and the core wire 31 of the specific cable 30i, and by this electrostatic capacitance coupling, the core wire 31 is present. In order to detect the potential of, the detection circuit 22 uses a buffer circuit having a very high input impedance, in this embodiment, a voltage flower circuit using a field effect transistor, for example, to detect an input signal.

The magnitude of the potential signal detected by the detection circuit 22 has the following main factors (1) The distance between the metal electrode 21 and the core wire 31 (2) The dielectric constant (3) of the insulating layer material of the specific cable 30i ) It changes with the impedance of the detection circuit 22. Therefore, in order to cope with such a change, an amplifier circuit for amplifying the input signal is required.

6-channel signal processing circuits 23a-23
f is the amplification circuit (not shown), a bandpass filter that allows a specific frequency signal to pass from the input signal, the frequency signal that has passed through the bandpass filter is smoothed, and the frequency signal is a reference signal. And a smoothing / comparator circuit for comparing
In addition, each band pass filter is a specific frequency oscillation circuit 1
1a to 11f, and their center frequencies are set to be equal to the frequencies f _{1 to} f ₆ of the six types of signals oscillated by the specific frequency oscillation circuits 11a to 11f, respectively. Therefore, the noise component contained in the input signal is
It is removed by this bandpass filter. The smoothing / comparator circuit is provided corresponding to each of the above bandpass filters, and compares the smoothed frequency signal with a predetermined reference signal, that is, each frequency signal passed through each bandpass filter is smoothed / compressed. It is determined whether each is above or below a predetermined threshold level set in the comparator circuit, and when the frequency signal is greater than the reference signal, the outputs CH1 to CH6 to the combination circuit 24 are set to "1", respectively. ..

The combination circuit 24 includes the signal processing circuits 23a.
.About.23f, the six outputs CH1 to CH6 are combined in the same manner as in the combination / combination circuit 12, and are output to the AND circuits 25a to 25t. AND circuit 2
5a to 25t set the outputs to "1" when all three outputs from the combination circuit 24 are "1". These AND circuits 25a to 25t are applied circuits 13a to 13t.
And AND circuits 25a to 25t
The output of indicates that three types of frequency signals applied to each cable from the applying circuits 13a to 13t are detected.

The display circuits 26a to 26t are AND circuits 2.
5a to 25t respectively have lamps (not shown), and when the output of any one of the AND circuits 25a to 25t is "1", the display circuit corresponding to the AND circuit turns on the lamp, This indicates the order of the cable to which the electrode 21 is adjacent. In this embodiment, since 20 cables can be identified at the same time, 20 AND circuits and 20 display circuits are required.

Next, the operation of the identification device shown in FIG. 1 will be described. In addition, in FIG. 1, the electrode 21 is assumed to be in non-contact proximity to the ninth cable 30i. Also,
The clips 14a to 14t of the signal applying unit 10 are respectively sandwiched between the cores of the cables in the protective tube, but the ninth clip 14i of the signal applying unit 10 is the cable 30.
It is sandwiched between the core wires 31 of i, and the specific frequency oscillation circuits 11c to 1c from the application circuit 13i via the clip 14i.
It is assumed that a synthesized signal having a waveform shown in FIG. 3, for example, synthesized from three types of frequency signals f ₃ , f ₄ , and f ₅ oscillated from 1e is applied.

Therefore, the detection circuit 22 is connected via the electrode 21.
The input signal detected in step 3 has a waveform shown in FIG. 4 that includes the above-mentioned three types of frequency components f ₃ , f ₄ , and f ₅ and other noise components. The input signal is input to each of the 6-channel signal processing circuits 23a to 23f, but depending on the frequency component of the input signal, the specific frequency oscillation circuits 11c to 11e.
Output CH of only the signal processing circuits 23c to 23e corresponding to
3-CH5 becomes "1". Therefore, the combination circuit 24
Then, only the output of the AND circuit 25i input by combining the outputs CH3 to CH5 becomes “1”, the display circuit 26i connected to the AND circuit 25i lights the lamp, and the metal electrode 20 approaches. Cable 30i is 9
The second cable can be represented. And
If the electrodes 21 are sequentially brought close to other cables, all the cables in the protective tube can be identified in the same manner as above.

Here, the influence of the coupling capacitance between the cables in the protective tube will be described. There is also a capacitive coupling capacitance between the cables in the protective tube, which in some cases may be much larger than the capacitive coupling capacitance between the electrodes and the cable. Therefore, it is necessary to consider the mutual influence between the cables. In such a case, actually, if the impedance between the core wire of each cable in the protective tube and the application circuit is made small to some extent, the influence of the coupling capacitance between the cables can be suppressed to a negligible level. For example, the electrostatic coupling capacitance between cables is usually on the order of several PF or less, and even for a signal of 100 KHz, its impedance is on the order of several MΩ. If all cables are connected to the voltage application circuit via clips, the impedance between each cable and the voltage application circuit is at most several hundred Ω.
Is the order of.

FIG. 5 shows an equivalent circuit between the cables A and B for explaining the influence of the coupling capacitance between the cables. The impedance of the coupling capacitance between the cables A and B is Rc, Assuming that the impedance between the cables A and B and the application circuit is Ra and Rb, the signal voltage applied to the cable A is Va, and the signal voltage Va passes through the coupling capacitance between the cables A and B and the cable B. Affect. Here, when the signal voltage of the cable B is Vb, the above Vb is obtained by Vb = Va.Rb / (Rb + Rc). Actually, in the case of Rc >> Rb, Va << V
It becomes b. That is, if the impedance between the cables is sufficiently small, the influence of the coupling capacitance between the cables becomes negligible.

Therefore, in the present embodiment, the signal application section normally applies different combinations of three kinds of frequency signals to each cable out of six kinds of frequency signals whose probability of being used at the same time is equal to zero. Since the frequency signal is detected by the signal detection unit that is not in contact with the cable, each cable can be efficiently identified without making an erroneous determination, and the reliability of cable identification can be improved. In addition, since the signal detection unit is formed by capacitive coupling with the cable, the current flowing through the cable can be made extremely weak, and when the identification device of the present embodiment is used for portable use, dry battery consumption is reduced. This makes it suitable as a portable device.
Further, it is not necessary to provide a common ground, and label attaching work is not required, so that one worker can easily perform the cable identifying work.

In this embodiment, the synthesized signal is a combination of three types of frequency signals, but the present invention is not limited to this, and a combination of two or four or more types of frequency signals is used. May be. The display circuit may have various configurations. For example, the output of the signal processing circuit is input to a specific decoder circuit, and the decoder directly connects the cable to the liquid crystal panel according to the channel number whose output becomes "1". It is also possible to display the number of.

[0024]

As described above, according to the present invention, in a method of identifying a plurality of cables for identifying a plurality of accommodated cables, a plurality of combinations of signals having different specific frequencies are combined, and the combined signals are combined. In addition to directly applying to each of the cables, the composite signal is detected from each of the cables by an electrostatic coupling method, and signals of a plurality of specific frequencies forming the composite signal are identified to identify each of the cables. Therefore, each cable can be easily and surely identified to improve the work efficiency.

[Brief description of drawings]

FIG. 1 is a block diagram showing a configuration of an identification device using a cable identification method according to the present invention.

FIG. 2 is a block diagram showing a configuration of a signal applying unit shown in FIG.

FIG. 3 is a waveform diagram showing an example of a composite signal applied to a core wire of a cable.

FIG. 4 is a waveform diagram showing an example of an input signal detected from a cable core wire.

FIG. 5 is a diagram showing an equivalent circuit between cables A and B for explaining the influence of the coupling capacitance between the cables.

[Explanation of symbols]

 10 signal application part 11a-11f specific frequency oscillation circuit 12 combination synthesis circuit 13a-13t application circuit 14a-14t clip 20 signal detection part 21 metal electrode 22 detection circuit 23a-23f signal processing circuit 24 combination circuit 25a-25t AND circuit 26a- 26t display circuit 30i, A, B cable 31 core wire

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[Procedure amendment]

[Submission date] June 12, 1992

[Procedure Amendment 1]

[Document name to be amended] Statement

[Name of item to be corrected] 0023

[Correction method] Change

[Correction content]

In this embodiment, the synthesized signal is a combination of three types of frequency signals, but the present invention is not limited to this, and a combination of two or four or more types of frequency signals is used. May be. The display circuit may have various configurations. For example, the output of the signal processing circuit is input to a specific decoder circuit, and the decoder directly connects the cable to the liquid crystal panel according to the channel number whose output becomes "1". It is also possible to display the number of. Also, the measured
The target is not only ordinary electric cables but also iron pie.
Iron wire armor with iron wire wrapped around a plastic pipe
As a tension wire for plastic pipes, bridges, etc.
Stranded steel wire (steel wire) and metal auxiliary
According to the present invention, any conductive long object such as a strong fluid transport pipe can be used.
Can be identified.

Claims (1)

[Claims] 1. A method for identifying a plurality of cables for identifying a plurality of cables to be housed, wherein a plurality of combinations of signals having different specific frequencies are combined, and the combined signals are directly applied to the respective cables, and A method for identifying a plurality of cables, characterized in that the composite signal is detected from each of the cables by an electric coupling method, and signals of a plurality of specific frequencies forming the composite signal are identified to identify each of the cables. ..