JP2003315401A - Device of testing cable wiring - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a device of testing cable wiring which is small and light and is carried easily, and by which a test of wiring is executed readily and rapidly. <P>SOLUTION: The device of testing cable wiring is composed of a main side connector which can be electrically connected to a terminal of a cable unit or a connector of a cable assembly with connector to be tested, and a main checker which is electrically connected to the main side connector and executes such cable tents as to whether breaking of conductors of the cable unit or the cable assembly with connector, the lack of wiring, crossing and bridging faults between a pair of identical wires, crossing between different pairs and the like are present or not. The main checker has an electric circuit composed of a diode in which current only flows in one direction, an LED which is turned on in the case the cable unit or the cable assembly with connector is in a normal state and turned off in the case the faults or the like is present, and a rotary switch which is switched in accordance with a purpose of the test. <P>COPYRIGHT: (C)2004,JPO

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a cable wiring inspection device. More specifically, the present invention relates to the presence or absence of conductor breakage of a cable unit or a cable assembly with a connector, the presence or absence of wiring failure, the presence / absence of a teleco (cross) in the same pair, the presence / absence of a teleco (cross) between other pairs, and The present invention relates to a cable wiring inspection device capable of inspecting a pair of short circuits.

[0002]

2. Description of the Related Art In recent years, electric and electronic devices are becoming smaller and lighter, and the performance is becoming higher and higher. Along with this, the electric / electronic device wiring cables and connectors attached to the terminals of the electric / electronic device wiring cables have become complicated in structure.

Cables for wiring electric and electronic devices are provided for wiring as they are, or as a cable assembly with a connector in which connectors are attached to their terminals, and then provided for wiring.

Therefore, it is necessary to accurately inspect whether or not the electric / electronic equipment wiring cable and the connector having these complicated structures are accurately connected.

FIG. 6 is a partially omitted front view showing a current sensor device capable of detecting a current flowing in an electric line in a live state.

In FIG. 6, 10 is an electric circuit, 11 is a magnetic core, 12 is a current detection coil, 13 is a two-core code signal line, 13a and 13b are coil-side conductor terminal lines, 13c and 1c.
3d is a connector-side conductor terminal wire, 14 is an output P connector,
14a is a P flange portion, 14b is a P pin standing portion, 14c
Is a P pin insertion portion, 14d is a P pin, 15 is a J connector on the measuring instrument input side, 15a is a J flange portion, 15b is a J pin standing portion, 15c is a J pin insertion portion, 15d is a J pin, 15f
Is a connection terminal line.

This current sensor device encloses the electric circuit 10,
And a magnetic core 11 configured to be openable and closable, a current detection coil 12 wound around the magnetic core 11 in a fixed direction,
A code signal line 13 connected to both terminal lines of the current detection coil 12, an output P connector 14 connected to the terminals of the code signal line 13, and a measuring instrument input side J connected to the detection side P connector 14. It is composed of a connector 15 and a current measuring device body (not shown) provided in the measuring device input side J connector 15.

In the operation of this current sensor device, first, the current detection coil 12 detects the current detection signal of the current flowing in the electric path 10.

Next, the detected current detection signal is the code signal line 13, the output P connector 14 and the measuring instrument input side J.
It is transmitted to the current measuring device body (not shown) via the connector 15.

Finally, the main body of the current measuring instrument which has received the current detection signal can convert the current detection signal into the value of the current flowing in the electric path 10, and display and record it.

As can be seen from FIG. 6, the output P connector 14
Has a P flange portion 14a in the middle, a P pin upright portion 14b on the left side in the drawing, and a P pin insertion portion 14c on the right side in the drawing. Six P pins 14d are axially erected on the left end face of the P pin standing portion 14b in the drawing, and are not shown on the right end face of the P pin insertion portion 14c in the drawing. Six P pin holes 14e are opened in the axial direction.

Similarly, as can be seen from FIG. 6, the J connector 15 on the measuring instrument input side has a J flange portion 15a at an intermediate portion in the drawing and a J pin standing portion 15 on the left side in the drawing.
b, the right side toward the drawing is the J pin insertion portion 15c. Three J pins 15d are axially erected on the left end face of the J pin upright portion 15b in the drawing, and two J pin insertion portions 15c are two on the right end face of the drawing. The connection terminal wire 15f is erected in the axial direction.

As can be seen from FIG. 6, both ends of the current detection coil 12 are connected to the ends of the two conductor terminal lines 13a and 13b on the left side of the code signal line 13 in the drawing. The ends of the two conductor terminal wires 13c and 13d on the right side of the two-core code signal line 13 in the drawing are the six P-pins standing on the left end surface of the output P connector 14 in the drawing. It is adapted to be connected to two of 14d.

On the other hand, the J pin upright portion 15b of the measuring instrument input side connector 15 is inserted into the P pin insertion portion 14c on the right side of the output P connector 14 in the drawing, and thereby electrically connected. It is like this.

By the way, generally, the connection position of the ground wire (GND), which is the reference of connection, is determined by the connection position of the measuring unit main body (not shown). Therefore, the P pin standing portion 14b on the left side of the output P connector 14 in the drawing is shown.
The six P pins 14d that are erected on the end surface of the connector are connected to the three pins 15d that are erected on the J pin erected portion 15b on the left side of the measuring instrument input side J connector 15. Become.

For example, when a code signal line assembly with a P connector is manufactured using the code signal line 13 and the output P connector 14, a wiring work diagram of the code signal line 13 and the P pin 14d of the output P connector 14 is prepared. To do.

Next, based on the wiring work diagram, wiring connection work of the code signal line assembly with P connector is performed using the code signal line 13 and the output P connector 14.

Finally, a pin continuity inspection and a pin wiring inspection of the P-connector cord signal line assembly having the wiring connection work are performed.

First, the continuity test of the code signal line assembly with the P connector is to test the presence or absence of a mistake in the wiring connection work by measuring the resistance value between the output pins with an ohmmeter. That is, the continuity test of the P connector-attached code signal line assembly may be performed by measuring the resistance value between the P pins 14d with an ohmmeter.

On the other hand, the pin wiring inspection of the code signal line assembly with the P connector cannot be inspected separately. Conventionally, the pin wiring inspection of the code signal line assembly with the P connector has been performed as follows.

FIG. 7 is a front view showing a conventional method for inspecting pin wiring of a cord signal line assembly with a P connector.

In FIG. 7, 13I is a code signal line I, 1
3II is a code signal line II, 14I is an output P connector I, 1
Reference numeral 4II is an output P connector II, 16 is an oscillator, 17 is a loop conductor, 18I is a reference current sensor, 18II is a current sensor to be inspected, and 19 is a dual wavelength oscilloscope.

That is, in the pin wiring inspection of the conventional cord signal line assembly with a P connector, an oscillator 16 is installed as a signal source for current detection of a sensor, and a loop conductor 17 is arranged between its output terminals. Has been done. Further, the reference current sensor 18I and the current sensor 18II to be inspected are arranged in the same direction in the vicinity of both ends on the tip side of the arranged loop-shaped conductor 17,
Moreover, it is packaged at a predetermined interval. A terminal of the code signal line I13I, which is a main component of the code signal line assembly with a P connector, is connected to the terminal of the externally enclosed reference current sensor 18I.
One end side terminal of the output P connector I14I is connected to the other end side terminal of the code signal line I13I which is a main constituent member of the code signal line assembly with a connector. Further, a dual wavelength oscilloscope 19 is connected to the other end of the output P connector I14I.

Similarly, this inspected current sensor 1 to be inspected
The terminal of 8II is connected to one end of the code signal line II which is a main constituent member of the code signal line assembly with a P connector, and the code signal line which is a main constituent member of the code signal line assembly with a P connector. An end of the output P connector II14II is connected to the other end of the II13II. Further, a dual wavelength oscilloscope 19 is connected to the other end of the output P connector II14II.

When performing the inspection work by the conventional pin wiring inspection method for the cord signal line assembly with the P connector, the power of the oscillator 16 is first turned on. When the oscillator 16 is powered on in this manner, a transmission signal is sent to the connector-equipped cord signal line assembly connected to the reference current sensor 18I and the connector-equipped cord signal line assembly connected to the current sensor 18II to be tested.

Next, the output waveform of the cord signal line assembly with a connector which receives the transmitted signal is displayed on the dual wavelength oscilloscope 19 as shown in FIG.

In FIG. 7, W ₁ is a reference current sensor 18I.
The standard output waveform of the cord signal line assembly with a connector connected to W, W ₂ is the pass output waveform of the cord signal line assembly with a connector connected to the current sensor 18II to be tested, W
Reference numeral ₃ is a reject output waveform of the cord signal line assembly with a connector connected to the current sensor 18II to be inspected.

That is, the code signal line assembly with a connector that outputs W ₂ has the same waveform as the standard output waveform of the code signal line assembly with a connector connected to the reference current sensor 18I, so that the pin wiring is correctly performed. It is shown that the product is acceptable.

On the other hand, the connector-equipped cord signal line assembly that outputs W ₃ has an opposite phase to the standard output waveform of the connector-equipped cord signal line assembly connected to the reference current sensor 18I, and therefore, there is a mistake in the pin wiring. It indicates that there is, and it turns out that it has failed.

As shown in FIG. 7, the conventional method for inspecting pin wiring of a cord signal line assembly with a P connector is P
It is possible to accurately inspect whether or not there is a mistake in the pin wiring of the code signal line assembly with connector.

[0031]

However, as shown in FIG.
In the conventional pin wiring inspection device for the cord signal line assembly with P connector shown in Fig. 2, two large measuring instruments, the oscillator 16 and the dual wavelength oscilloscope 19, are indispensable, and as a result, the pin wiring inspection device is large and It was difficult to carry and expensive.

The present invention has been made in view of the above points, and its purpose is to solve the above-mentioned drawbacks of the prior art, to make it compact and lightweight, to be easily carried, and to easily perform wiring inspection. Another object of the present invention is to provide a cable wiring inspection device that can be quickly and quickly performed.

[0033]

SUMMARY OF THE INVENTION The gist of the present invention is to provide a main body connector to which a terminal of a cable to be inspected or a connector of a cable assembly with a connector can be electrically connected, and to the main body connector. Of the cable alone or the connector-equipped cord / signal line assembly by disconnecting the conductor, presence / absence of wiring leakage, presence / absence of telco (crossing) in the same pair, presence / absence of telco (crossing) between other pairs, In a cable wiring inspection device including a pair of checkers capable of inspecting a cable for the presence or absence of a short circuit, the checker body includes a diode through which a current flows only in one direction, and the cable unit or the cable assembly with a connector. Signal LED that lights up when normal and goes off when there is a problem
And a rotary switch that can be switched according to the purpose of inspection.

[0034]

BEST MODE FOR CARRYING OUT THE INVENTION Next, an embodiment of a cable wiring inspection device of the present invention will be described with reference to the drawings. FIG. 1 is a front view showing an embodiment of the cable wiring inspection device of the present invention. In FIG. 1, 20 is a main body, 21 is a power switch, 22 is an A side rotary switch, 23 is a B side low number rotary switch, 24 is a B side high number rotary switch, 25 is an A side signal LED, 26 is a B side low number Signal L
ED, 27 is a B-side high number signal LED, 28 is an A-side main body connector, and 29 is a B-side main body connector.

That is, two A connectors 28 and two B connectors 2 are provided on the upper portion of the cable wiring inspection apparatus according to the embodiment of the present invention.
9 are installed. That is, these two A-side body connectors 2 are included in the cable wiring inspection device according to the embodiment of the present invention.
The 8, B side body connector 29 is installed so that two types of connectors of the cable assembly with a connector to be mounted for the test can be selected. That is, when performing a connection inspection of the cable assembly with a connector, these two A-side body connectors 28 and B-side body connectors 2
9. The connector portions of the cable assembly with a connector to be tested are electrically connected to each other.

Although not shown in the drawing, the power source for operation of the cable wiring inspection apparatus of one embodiment of the present invention is DC 5V. This DC 5V is A side signal LED25, B side low signal LED2
6, the signal LED such as the B-side high number signal LED 27 can be turned on and the cable assembly with a connector is not broken down. Therefore, the present invention is not limited to DC 5V as long as these conditions are satisfied. When testing a cable assembly with a connector or a cable alone which is a main component thereof, first, an electrical connection is made to the A-side main body connector 28 or the B-side main body connector 29 or both of them in the cable wiring inspection apparatus according to one embodiment of the present invention. Connecting.

Next, the power switch 21 installed on the lower side of the front surface of the main body 20 of the cable wiring inspection apparatus according to the embodiment of the present invention is turned on. Power switch 2
When 1 is turned on, 5 V DC is output to the cable assembly with a connector electrically connected to the A-side main body connector 28 or the B-side main body connector 29 or the cable unit which is a main component thereof.

Next, the A-side main body connector 2 installed on the upper front surface of the cable wiring inspection apparatus according to the embodiment of the present invention.
8 or B side main body connector 29, or rotary switches related to both, for example, A side rotary switch 22, B side low number rotary switch 23, B side high number rotary switch 24, etc. are turned as necessary.

Next, a signal LED, for example, an A-side signal L, installed on the front upper surface of the cable wiring inspection device according to the embodiment of the present invention relating to the connector and the rotary switch.
ED25, B side low number signal LED26, B side high number signal LE
Observe the presence or absence of lighting of D27.

Next, a cord signal line assembly with a connector or its main constituent members, which are inspected by checking whether or not the related signal LEDs, for example, the A side signal LED 25, the B side low number signal LED 26, and the B side high number signal LED 27 are turned on. Whether the cable is broken or not, whether it is incorrectly connected, wiring is leaked, whether or not there is a short circuit in the same pair, telco (intersection) of wiring in the same pair, telco (intersection) of wiring between other pairs, short circuit in the same pair Etc. can be detected quickly and easily. In these cases, if the signal LED lights up, it is determined as a normal acceptable product, and conversely, if the signal LED does not light up, it is determined as a defective product. (Inspection Example of Disconnection and Wiring Leakage) FIG. 2 is a circuit explanatory view showing an example of inspection of a cable assembly with a connector for disconnection using the cable wiring inspection apparatus according to one embodiment of the present invention.

As shown in the figure, a diode is incorporated in the circuit of FIG. 2 so that current can flow only in the same direction in the circuit. That is, when there is disconnection or wiring leakage, the signal LED of the corresponding number does not light up, so that the presence or absence of disconnection or wiring leakage can be easily inspected.

First, as shown in FIG. 2, the cable assembly with a connector was electrically connected to the A connector installed on the upper portion of the cable wiring inspection apparatus according to one embodiment of the present invention. This electrical connection is circuit-wise, and the number 1-2 of the A-side rotary switch 22 installed at the lower front portion of the cable wiring inspection apparatus of the embodiment of the present invention and also the cable wiring inspection apparatus of the embodiment of the present invention. No. 1-2 of the A-side signal LED 25 installed on the upper part of the front surface of the.

Next, the power switch 21 installed in the lower front portion of the cable wiring inspection apparatus of one embodiment of the present invention was turned on. In FIG. 2, POW is turned on, and 5 V DC flows in the circuit of FIG.

Next, the A-side rotary switch 22 was turned to set it to 1-2.

Next, the A-side signal LED 25 installed on the upper front surface of the cable wiring inspection apparatus according to the embodiment of the present invention.
Whether or not the No. 1-2 signal LED was turned on was observed. As a result, the No. 1-2 signal LEDs of the A-side signal LED 25 were not turned on and remained off.

Next, the No. 1-2 signal LEDs of the A-side signal LED 25 do not light up because the cable which is the main constituent member of the inspected connector-coded signal line assembly has a broken wire as shown by a cross mark in FIG. It was judged that there was a place. That is, the inspected cable assembly with the connector was determined to be a rejected product.

Although the cable wiring inspection apparatus according to the embodiment of the present invention is used to inspect the code signal line assembly with the connector for disconnection, the wiring leakage can be inspected in the same manner. (Inspection example of wiring telecoupling in the same pair) FIG. 3 is a circuit diagram showing an example of inspection of wiring telecoupling in the same pair of a cable assembly with a connector using the cable wiring inspection apparatus according to an embodiment of the present invention. It is a figure.

As shown in the figure, a diode is also incorporated in the circuit of FIG. 3 so that the current can flow only in the same direction in the circuit. That is, when there is a telecom of the wiring in the same pair, the signal LED of the corresponding number does not light up, so that it is possible to easily inspect the presence or absence of the telecom of the wiring in the same pair.

First, as shown in FIG. 3, the cable assembly with a connector was electrically connected to the A connector installed on the upper portion of the cable wiring inspection apparatus according to one embodiment of the present invention. This electrical connection is related to the No. 1-2 and No. 3-4 of the A-side rotary switch 22 installed on the lower front surface of the cable wiring inspection apparatus according to one embodiment of the present invention in a circuit manner and is also one of the present invention. Nos. 1-2 and 3 of the A-side signal LED 25 installed on the front upper part of the cable wiring inspection device of the embodiment
-4 was done as related to.

Next, the power switch 21 installed in the lower part of the front surface of the cable wiring inspection apparatus according to the embodiment of the present invention was turned on. In FIG. 3, POW is turned on, and 5 V DC flows in the circuit of FIG.

Next, the A-side rotary switch 22 was turned to set the position 1-2.

Next, the A-side signal LED 25 installed on the upper front surface of the cable wiring inspection apparatus according to the embodiment of the present invention.
The presence or absence of lighting of the No. 1-2 and No. 3-4 signal LEDs was observed. As a result, Nos. 1-2 and 3-4 of the A-side signal LED 25
No. signal LED did not light up, but remained off.

Next, Nos. 1-2 and 3 of the A-side signal LED 25
The No. -4 signal LED did not light up because it was determined that the cable, which is the main component of the inspected connector-coded signal line assembly, had a crossing point as indicated by a crossing circuit mark in FIG. That is, the inspected code signal line assembly with connector was determined to be a rejected product. (Inspection Example of Telecopies for Wiring Between Other Pairs) FIG. 4 is a circuit diagram showing an example of inspection of telecopies for wiring between other pairs of a cable assembly with a connector using the cable wiring inspection apparatus according to one embodiment of the present invention. It is a figure.

As shown in the figure, a diode is also incorporated in the circuit of FIG. 4, and the current flows only in the same direction in the circuit. That is, when there is a telecom of the wiring between the other pairs, the signal LED of the corresponding number does not light up, so that it is possible to easily inspect the presence or absence of the telecom of the wiring between the other pairs.

First, as shown in FIG. 4, the cable assembly with a connector was electrically connected to the A connector installed on the upper portion of the cable wiring inspection apparatus according to one embodiment of the present invention. This electrical connection is related to the No. 1-2 and No. 3-4 of the A-side rotary switch 22 installed on the lower front surface of the cable wiring inspection apparatus according to one embodiment of the present invention in a circuit manner and is also one of the present invention. Nos. 1-2 and 3 of the A-side signal LED 25 installed on the front upper part of the cable wiring inspection device of the embodiment
-4 was done as related to.

Next, the power switch 21 installed in the lower front portion of the cable wiring inspection apparatus according to the embodiment of the present invention was turned on. In FIG. 4, POW is turned on, and 5 V DC flows in the circuit of FIG.

Next, the A-side rotary switch 22 was turned to set it to 1-2.

Next, the A-side signal LED 25 installed on the front upper surface of the cable wiring inspection apparatus according to the embodiment of the present invention.
The presence or absence of lighting of the No. 1-2 and No. 3-4 signal LEDs was observed. As a result, Nos. 1-2 and 3-4 of the A-side signal LED 25
No. signal LED did not light up, but remained off.

Next, Nos. 1-2 and 3 of the A-side signal LED 25
The signal LED No. -4 did not light up because it was determined that the cable, which is the main constituent member of the cable assembly with a connector tested, had an intersection as shown by the crossing circuit mark in FIG. That is, the inspected cable assembly with the connector was determined to be a rejected product. (Inspection Example of Short Circuit in Same Pair) FIG. 5 is a circuit explanatory diagram showing an inspection example of short circuit in the same pair of a single cable by using the cable wiring inspection apparatus according to one embodiment of the present invention.

As shown in the figure, a diode is also incorporated in the circuit of FIG. 5 so that current flows only in the same direction in the circuit. That is, when there is a short circuit in the same pair, the signal LED of the corresponding number does not light up, so that the presence or absence of a short circuit in the same pair can be easily inspected.

First, as shown in FIG. 5, a single cable without a connector was electrically connected to the A connector installed on the upper portion of the cable wiring inspection apparatus according to one embodiment of the present invention. This electrical connection is circuit-wise, and the number 1-2 of the A-side rotary switch 22 installed at the lower front portion of the cable wiring inspection apparatus of the embodiment of the present invention and also the cable wiring inspection apparatus of the embodiment of the present invention. No. 1-2 of the A-side signal LED 25 installed on the upper part of the front surface of the.

Next, the power switch 21 installed at the lower front portion of the cable wiring inspection apparatus according to the embodiment of the present invention was turned on. In FIG. 5, POW is turned on, and 5 V DC flows in the circuit of FIG.

Next, the A-side rotary switch 22 was turned to set it to 1-2.

Next, the A-side signal LED 2 installed in the upper front portion of the cable wiring inspection apparatus according to the embodiment of the present invention.
The presence or absence of lighting of the No. 1-2 signal LED of No. 5 was observed. As a result, the No. 1-2 signal LEDs of the A-side signal LED 25 were not turned on and remained off.

Next, it was determined that the No. 1-2 signal LEDs of the A-side signal LED 25 did not light because there was a short circuit in the same pair as shown in the inspected cable alone. That is,
The tested cable alone was determined to be a rejected product.

[0066]

According to the cable wiring inspection apparatus of the present invention, a large measuring instrument such as a transmitter or a dual-wavelength oscilloscope is not required, which makes it compact and lightweight and excellent in portability. It can be performed quickly and easily and is industrially useful.

[Brief description of drawings]

FIG. 1 is a front explanatory view showing an embodiment of a cable wiring inspection device of the present invention.

FIG. 2 is a circuit explanatory view showing an example of inspection of disconnection of a cable assembly with a connector by using the cable wiring inspection apparatus according to one embodiment of the present invention.

FIG. 3 is a circuit explanatory diagram showing an example of inspecting a telco for wiring in the same pair of a cable assembly with a connector using the cable wiring inspecting device according to an embodiment of the present invention.

FIG. 4 is a circuit diagram showing an example of inspecting a telco for wiring between other pairs of the cable assembly with a connector by using the cable wiring inspection apparatus according to the embodiment of the present invention.

FIG. 5 is a circuit explanatory diagram showing an example of a short circuit inspection in the same pair of cable units using the cable wiring inspection apparatus according to the embodiment of the present invention.

FIG. 6 is a partially omitted front explanatory view showing a current sensor device capable of detecting a current flowing in an electric line in a hot line state.

FIG. 7 is a front view showing a method for inspecting a pin wiring of a conventional cord signal line assembly with a P connector.

[Explanation of symbols]

10 electric circuits 11 magnetic core 12 Current detection coil 13 code signal line 13a Coil side conductor terminal wire 13b Coil side conductor terminal wire 13c Connector-side conductor terminal wire 13d Connector side conductor terminal wire 13I Code signal line I 13II Code signal line II 14 Output P connector 14a P Flange part 14b P pin standing part 14c P pin insertion part 14d P pin 14I Output P connector I 14II Output P connector II 15 Measuring instrument input side J connector 15a J Flange 15b J pin standing part 15c J pin insertion part 15d J pin 15f connection terminal wire 16 transmitter 17 Loop conductor 18I Reference current sensor 18II Inspected current sensor 19 Dual wavelength oscilloscope 20 body 21 Power switch 22 A side rotary switch 23 B side low number rotary switch 24 B side high number rotary switch 25 A side signal LED 26 B side low signal LED 27 B side high signal LED 28 A side body connector 29 B side body connector

Claims (2)

[Claims] 1. A main body connector capable of electrically connecting a terminal of a cable to be inspected or a connector of a cable assembly with a connector, and the cable itself or the cord with a connector electrically connected to the main body connector. Conduct cable inspections such as the presence or absence of conductor breaks in the signal line assembly, the presence or absence of wiring leaks, the presence or absence of telco (crossing) in the same pair, the presence or absence of telco (crossing) between other pairs, and the presence or absence of short circuits in the same pair. In a cable wiring inspection device comprising a checker main body capable of performing a checker, the checker main body is turned on when a current flows only in one direction and the cable alone or a cable assembly with a connector is normal, and is turned off when there is a problem. Signal L
A cable wiring inspection device having an electric circuit including an ED and a rotary switch that can be switched according to an inspection purpose. 2. The cable wiring inspection device according to claim 1, wherein a plurality of main body connectors are installed.