JPH0882648A - Disconnection detecting device for connecting cable - Google Patents

Abstract

PURPOSE: To shorten a time required for an operation of detecting disconnection. CONSTITUTION: A disconnection detecting device 10 is equipped with a signal generator 12 generating detection signal S, a transmission-side switching part 14 which transmits the detection signal S generated from the signal generator 12 to one end of each of conductors 901 to 90n switched sequentially and a reception-side switching part 16 which is connected to the other end of each of the conductors 901 to 90n by sequential switching. The device is equipped with a fault discriminating part 18 which discriminates a fault of the conductor 90x (1<=x<=n) connected by the reception-side switching part 16, on the basis of the detection signal S received through the conductor 90x, and a faulty conductor display unit 20 which displays the faulty conductor discriminated by the fault discriminating part 18.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a disconnection detecting device for detecting disconnection of a connection cable used in an accelerated life test device for electronic parts.

[0002]

2. Description of the Related Art FIG. 3 is a block diagram showing an accelerated life test of electronic components.

Electronic parts 821 to 82 are used for the accelerated life test.
a thermostatic bath 84 for storing m and a signal for testing the electronic component 8
21-82m and electronic components 821-82m
Test device 86 for measuring the characteristics of electronic components and electronic components 821 to 8
A connection cable 88 that connects the 2 m and the test apparatus 86 is used. The connection cable 88 has a large number of core wires 901 to 901.
90n, a connector 881 provided at one end of the core wires 901 to 90n, and a connector 882 provided at the other end of the core wires 901 to 90n. Connector 881
Is connected to the connector 861 of the test apparatus 86, and the connector 882 is connected to the connectors 842 of the electronic components 821 to 82m.

An example of conditions for the accelerated life test will be described. A test voltage is applied to the electronic components 821 to 82m from the test device 86 via the connection cable 88. Constant temperature bath 84
Alternately repeats a high temperature atmosphere of 125 ° C. and a low temperature atmosphere of −55 ° C. many times to apply thermal stress to the electronic components 821 to 82 m for 48 hours. In this way, the lifespan of the electronic components 821 to 82m in the normal use state is predicted by measuring the lifespan of the electronic components 821 to 82m in the severe use state.

[0005]

At this time, since the connection cable 88 is also subjected to the same accelerated life test as the electronic components 821 to 82m, the core wires 901 to 90n are easily broken. Conventionally, after the abnormality of the connection cable 88 is discovered, the worker checks the continuity of the core wires 901 to 90n one by one with a tester to detect the disconnection. However, since the number of core wires 901 to 90n is extremely large at several hundreds, the disconnection detection work requires several hours to several days. Further, since the connection cable 88 cannot be used during the disconnection detection work, the accelerated life test device 80 cannot be used either.

[0006]

SUMMARY OF THE INVENTION Therefore, an object of the present invention is to provide a disconnection detecting device capable of shortening the time required for disconnection detection work.

[0007]

A disconnection detecting device according to a first aspect of the present invention comprises the following items. A signal generator that generates a detection signal. A transmission side switching unit that sequentially switches and transmits the detection signal generated from this signal generator to one end of each core wire of the connection cable. A receiving side switching unit that sequentially switches and connects to the other end of each core wire. A defect determination unit that determines a defect of the core wire based on a detection signal received through the core wire connected by the reception side switching unit. A defective core indicator that displays a defective core discriminated by the defect discrimination unit.

The disconnection detection device according to claim 2 is characterized by
It is provided with. A signal generator that generates a detection signal and simultaneously transmits the detection signal to one end of each core wire of the connection cable. A receiving side switching unit that sequentially switches and connects to the other end of each core wire. A defect determination unit that determines a defect of the core wire based on a detection signal received through the core wire connected by the reception side switching unit. A defective core indicator that displays a defective core discriminated by the defect discrimination unit.

A disconnection detecting device according to a third aspect is the second aspect.
An inductive noise removing circuit for removing inductive noise contained in the detection signal is attached to the defect determining section of the disconnection detecting device.

[0010]

The operation of the disconnection detecting device according to the first aspect will be described. The detection signal generated from the signal generator is sequentially switched by the transmission side switching unit and transmitted to one end of each core wire of the connection cable. This detection signal is received at the other end of the core wire if the core wire is conducting, and is not received at the other end of the core wire if the core wire is broken. That is, if the core wire connected in the receiving side switching unit is conducting, the detection signal is received from the other end of the core wire while the switching in the transmitting side switching unit makes one round. On the other hand, if the core wire is broken, the detection signal is not received even if the transmission side switching unit makes one cycle of switching. Thereby, the defect determination unit can determine the defect of the core wire.

The operation of the disconnection detecting device according to the second aspect will be described. The detection signal generated from the signal generator is simultaneously transmitted to one end of each core wire of the connection cable. Hereinafter, the operation is the same as that of the disconnection detection device according to the first aspect.

The operation of the disconnection detecting device according to the third aspect will be described. The detection signal generated from the signal generator is simultaneously transmitted to one end of each core wire of the connection cable. Therefore, even if the core wire is broken, induction noise may occur. The induced noise is removed by the induced noise removing circuit in the defect determining unit.

[0013]

DESCRIPTION OF THE PREFERRED EMBODIMENTS FIG. 1 is a block diagram showing a first embodiment of a disconnection detecting device according to the present invention. Hereinafter, description will be given with reference to this drawing. However, the same parts as those in FIG.

The disconnection detection device 10 sequentially switches the signal generator 12 for generating the detection signal S and the detection signal S generated by the signal generator 12 to one end of the core wires 901 to 90n of the connection cable 88 and transmits the signal. Switching unit 14 and core wire 90
The receiving side switching unit 16 that is sequentially switched and connected to the other ends of 1 to 90n, and the core wire 90 connected by the receiving side switching unit 16
The defect discriminating unit 18 for discriminating the defect of the core wire 90x based on the detection signal S received via x (1 ≦ x ≦ n).
And a defective core indicator 20 for displaying the defective core discriminated by the defect discrimination unit 18.

The signal generator 12 is, for example, a pulse generator that outputs a detection signal S having a constant pulse width of "H" level. The transmission side switching unit 14 includes a switching control circuit 30 and a switching switch 32. The changeover switch 32 includes normally open contacts 321, 322, ...
It consists of 32n. The switching control circuit 30 includes a counter, a decoder, a solenoid of a relay, etc., which are not shown,
Each time the switching signal C ₁ output together with the detection signal S from the signal generator 12 is input, the normally open contacts 321 to 32n are sequentially switched. The normally open contacts 321 to 32n are connected to the connector 3
The core wires 901 to 90n are connected via 4,881. However, normally open contacts 321 to 32n and core wires 901 to 9
There is no need to make a one-to-one correspondence with 0n.

The receiving side switching section 16 comprises a switching control circuit 40 and a switching switch 42. The changeover switch 42 includes normally open contacts 421, 422, ..., 42n of the relay.
Consists of The switching control circuit 40 includes a counter (not shown),
It is composed of a decoder, a solenoid of a relay, and the like, and switches the normally open contacts 421 to 42n sequentially each time the switching signal C ₂ output from the determination circuit 52 is input. Normally open contact 42
1 to 42n are connected to the core wire 9 via the connectors 44 and 881.
01-90n is connected.

The defect discriminating section 18 is composed of a receiving circuit 50 and a discriminating circuit 52. The receiving circuit 50 is composed of, for example, a resistor, and generates a detection voltage according to the detection signal S. The discriminating circuit 52 includes a comparator such as an operational amplifier and compares the detected voltage generated in the receiving circuit 50 with the reference voltage to discriminate between the H ”level and the“ L ”level. , for example, a microcomputer or the like (not shown) is provided, and outputs a switching signal C _2, and to be able to determine the core wire 90x in detecting disconnection by integration of the switching signal C _2.

The defective core line indicator 20 is composed of, for example, a decoder, an LED driver, an LED, etc., which are not shown, and displays the numbers of the core lines 901 to 90n determined to be defective by the discrimination circuit 52.

Next, the operation of the disconnection detecting device 10 will be described.

The signal generator 12 and the transmitting side switching unit 14 on one end side of the core wires 901 to 90n are referred to as a "signal generating block", the receiving side switching unit 16 on the other end side of the core wires 901 to 90n, the defect determining unit 18, and the defective core wire. The display unit 20 will be referred to as a "defective detection block". The signal generation block and the defect detection block operate completely independently. Therefore, since a signal line for synchronization connecting the signal generation block and the defect detection block is not required, the configuration is simple and it is possible to detect disconnection even with a very long connection cable 88 while it is extended.

[1. Operation of signal generation block]

From the signal generator 12, the first detection signal S
And the switching signal C ₁ is output, the switching control circuit 30
Closes the normally open contact 321. Subsequently, when the second detection signal S and the switching signal C ₁ are output, the switching control circuit 30 opens the normally open contact 321 and closes the normally open contact 322. Similarly, when the nth detection signal S and the switching signal C ₁ are output, the switching control circuit 3
0 opens the normally open contact 32 (n-1) and closes the normally open contact 32n. This completes a cycle of switching from the normally open contact 321 to the normally open contact 32n. Then n + 1
When the second detection signal S and the switching signal C ₁ are output, the switching control circuit 30 opens the normally open contact 32n and closes the normally open contact 321. In this way, the detection signal S is sequentially switched to the core wires 901 to 90n and repeatedly transmitted.

[2. Operation of defect detection block)

When the first switching signal C ₂ is output from the discriminating circuit 52 to the switching control circuit 40, the switching control circuit 40 closes the normally open contact 421, so that the receiving circuit 50 is provided at the other end of the core wire 901. Connected. On the other hand, core wires 901 to 9
The detection signal S is sequentially switched and repeatedly transmitted to one end of 0n. If the detection signal S is input to the receiving circuit 50 during one cycle of switching in the transmitting side switching unit 14, the determining circuit 52 determines the core wire 901 as “good”. If the detection signal S is not input to the receiving circuit 50, the determination circuit 52 determines that the core wire 901 is “defective” and outputs the number to the defective core wire indicator 20. The defective core wire indicator 20 is
The LED (not shown) corresponding to the number is turned on.

If the detection signal S is input, or if the detection signal S is not input even after the transmission side switching unit 14 has made one cycle of switching, the discrimination circuit 52 switches the _second switching signal C ₂ . Output to the control circuit 40. Then, the switching control circuit 40
Opens the normally-open contact 421 and opens the normally-open contact 42.
Cycle 2 Subsequently, in the same manner, the defect of the core wire 902 is determined.

In the same manner, when the discriminating circuit 52 outputs the nth switching signal C ₂ to the switching control circuit 40 to discriminate the defective core wire 90n, all the operations are completed.

FIG. 2 is a block diagram showing a second embodiment of the disconnection detecting device according to the present invention. Hereinafter, description will be given with reference to this drawing. However, the same parts as those in FIG.

The disconnection detection device 60 generates the detection signal S and also transmits the detection signal S to the core wire 901 of the connection cable 88.
To 90n at the same time, a signal generator 62 that simultaneously transmits to one end, a receiving side switching unit 16 that sequentially switches and connects to the other ends of the cores 901 to 90n, and a receiving via a core wire 90x connected by the receiving side switching unit 16. The core wire 9 based on the detected signal S
Defect discrimination unit 64 for discriminating 0x defects, and defect discrimination unit 1
Defective core line indicator 20 for displaying the defective core line determined in 8.
It is provided with.

Further, in the defect discriminating section 64, an induction noise removing circuit 66 is inserted between the receiving circuit 50 and the discriminating circuit 52. The induction noise removal circuit 66 is composed of, for example, a coil, removes induction noise from the detection signal S received by the reception circuit 50, and outputs the detection signal S to the determination circuit 52.

Next, the operation of the disconnection detecting device 10 will be described.

The signal generator 62 on one end side of the core wires 901 to 90n is referred to as a "signal generation block", the receiving side switching unit 16 on the other end side of the core wires 901 to 90n, the defect discriminating unit 64 and the defective core wire indicator 20 are indicated as "defective". It will be referred to as a “detection block”.
The signal generation block and the defect detection block operate completely independently as in the first embodiment.

[1. Operation of signal generation block]

The signal generator 62 continues to simultaneously transmit the detection signal S to one ends of all the core wires 901 to 90n.

[2. Operation of defect detection block)

When the first switching signal C ₂ is output from the discriminating circuit 52 to the switching control circuit 40, the switching control circuit 40 closes the normally open contact 421 so that the receiving circuit 50 is provided at the other end of the core wire 901. Connected. On the other hand, all core wires 90
The detection signal S continues to be transmitted to one end of 1 to 90n. When the detection signal S is input to the receiving circuit 50, the determining circuit 52 determines the core wire 901 as “good”. If the detection signal S is not input to the receiving circuit 50, the determining circuit 52
Judges that the core wire 901 is “defective” and outputs the number to the defective core wire display device 20. The defective core wire indicator 20 turns on the LED (not shown) corresponding to the number.

Subsequently, the discrimination circuit 52 outputs the _second switching signal C ₂ to the switching control circuit 40. Then, the switching control circuit 40 opens the normally open contact 421 and closes the normally open contact 422. Then, similarly, the core wire 90
A defect determination of 2 is made.

In the same manner, when the discrimination circuit 52 outputs the nth switching signal C ₂ to the switching control circuit 40 and the core wire 90n is discriminated to be defective, all the operations are completed.

In the second embodiment, the detection signal S is transmitted to all the core wires 901 to 90n at the same time, so that the detection time can be shortened and the configuration can be simplified as compared with the first embodiment. In addition, the detection signal S is sent to all the core wires 901 to 90n.
To the defective core wires 901-90
Inductive noise is generated even when n. Therefore, the detection accuracy may decrease. In this case, the induction noise can be removed by providing the defect determination unit 64 with the induction noise removal circuit 66.

In the above embodiment, the normally open contact 32
1 to 32n and 421 to 42n may be semiconductor switches or other contactless switches. The defective core line display device 20 is not limited to one that is displayed by light, but may be one that is displayed by sound. The detection signal S is a constant voltage,
It may be a plurality of pulse waves, AC waves, or the like. Needless to say, the “break” here means the core wire 901 to
This includes not only the case where 90n is completely separated but also the case where the contact portions of the core wires 901 to 90n or the connectors 44 and 882 have a high resistance due to oxidation or scratches.

[0040]

The disconnection detecting device according to the first aspect of the invention has the following effects. Since the detection signal is sequentially switched and transmitted to each core wire of the connection cable, the detection signal transmitted from each core wire is sequentially switched and received, whereby the defective core wire is automatically judged and displayed. The time required for disconnection detection work can be greatly reduced. Therefore, it is possible to save labor in the disconnection detection work and effectively use the accelerated life test apparatus.

In addition to the above effects, the disconnection detection device according to the second aspect of the invention has the following effects. Since the detection signal is transmitted to all the core wires at the same time, the detection time can be shortened and the configuration can be simplified.

In addition to the above effects, the disconnection detection device according to claim 3 has the following effects. Since the inductive noise removing circuit is attached to the defect determining unit, the inductive noise included in the detection signal is removed, so that the detection accuracy of the disconnection detecting apparatus according to the second aspect can be improved.

[Brief description of drawings]

FIG. 1 is a block diagram showing a first embodiment of the present invention.

FIG. 2 is a block diagram showing a second embodiment of the present invention.

FIG. 3 is a block diagram showing an accelerated life test of electronic components.

[Explanation of symbols]

 10,60 Disconnection detection device 12,62 Signal generator 14 Transmitting side switching unit 16 Receiving side switching unit 18,64 Defect discriminating unit 20 Defect core wire indicator 66 Inductive noise removing circuit 88 Connection cable 901 to 90n Connection cable core wire S detection signal

Claims (3)

[Claims] 1. A signal generator for generating a detection signal, a transmission side switching unit for sequentially switching and transmitting the detection signal generated by the signal generator to one end of each core wire of a connection cable, and the other end of each core wire. The receiving side switching unit that sequentially switches to and connects to the receiving side switching unit, the defect determining unit that determines the defect of the core wire based on the detection signal received through the core wire connected by the receiving side switching unit, and the defect determining unit. A disconnection detecting device for a connection cable, comprising: a defective core indicator that displays the determined defective core. 2. A signal generator for generating a detection signal and simultaneously transmitting the detection signal to one end of each core wire of a connection cable, and a receiving side switching unit for sequentially switching and connecting to the other end of each core wire, A defect determination unit that determines a defect of the core wire based on a detection signal received through the core wire connected by the receiving side switching unit, and a defective core wire display unit that displays the defective core wire that is determined by the defect determination unit. Disconnection detection device for connection cables. 3. The disconnection detecting device for a connection cable according to claim 2, wherein the defect determining unit is provided with an induction noise removing circuit for removing induction noise included in the detection signal.