DE3924763A1 - Test device for multi-wire electric cable - compares voltages in corresp. resistors of resistance networks, one supplied directly and one via cable under test - Google Patents

Abstract

The test arrangement checks individual wires successively in steps, displays test results, interrupts the test procedure when a fault is detected and indicates the faulty wire. A step switched test signal generator (IC2,IC3,IC5) is connected directly to a first resistance network (R1-9) with a number of resistors corresp. to the number of wires in the cable, and, via the cable (A1-9) to a second resistance network (R10-18). The voltages across resistors of the two networks are compared (OP1,OP2). ADVANTAGE - Arrangement is improved for automatic testing with minimal labour costs.

Description

The invention relates to a test device accordingly the preamble of claim 1.

Such a device is from DE-PS 28 11 154 known. With this setup, the two Connection ends and the wires of a cable to be tested directly connected to the test facility. So that's it not possible with such a facility, already laid cables, especially those of greater length check. With such cables, the must for a long time known test method are used, in which a Connection between the two connection ends of one Wire manufactured and the passage and the connection order can be checked by two people.

The invention is based, the test to improve the direction of the type mentioned at the beginning, that an automatic test of multi-core, laid cable with the lowest possible personnel expenditure can be reached.

This object is achieved according to the invention by those specified in the characterizing part of claim 1 Characteristics. Appropriate embodiments of the invention result itself from the subclaims.

With the proposed training, this is to be examined Cable connected to the test equipment at one end. At the other, far end of the cable the second resistor network connected. So that is each vein a certain resistance in the first and assigned or imprinted second resistance network. The on the same resistors of the two resistors  voltage drops occurring in networks can be avoided by means of the comparator circuit can be detected and evaluated. The key advantage is that the common Connection point of the second, to the far end of the cable connected resistor network with the conductive Shielding a cable can be connected. These Shielding is on one side, on the test facility connected end of the cable with the comparator circuit connected.

So when doing an exam, the two Cable ends connected in the manner described, d. H. that on the other, distant cable end one the second Resistor network containing test plug inserted becomes. Then the cable can be checked by the Test facility made from. This test can be done by a Person.

For cables that have no shielding, the Connection from the step switch test signal generator to the first Resistance of the first and second resistance networks be interrupted within the test facility. Soon A connection will be established within the test facility at an early stage from connecting the first wire to the comparator circuit manufactured, this allows this first wire individually are not checked, but results in the check, the conclusion that all other veins are flawless be pulled that the first wire is flawless is. A corresponding connection is made in the first resistance network established.  

When testing a cable without shielding and connection the first resistance of the first and second resistance network to the comparator circuit can use these resistors also be short-circuited, so that regarding of the determined voltages no differences to the test procedure for cables with shielding.

Depending on the length of the cable used, it can be appropriate to the first resistor network Potentiometer downstream to adjust the resistance to cause resistance to the veins.

The invention is described below with reference to the accompanying Drawing showing a circuit diagram of the test equipment, for example explained.

The test facility described below is used to test up to 9-wire cable connections with or without shielding, in particular PC connections. A 9V battery serves as the voltage source for the device. The device essentially consists of three parts, namely test electronics with operating and display elements, a first resistor network R 1 to R 9 and connections for a device under test C, a 9-core cable, and one containing a second resistor network R 10 to R 18 Test plug T.

The first resistor network consists of resistors R 1 to R 9 connected in parallel, which have different resistance values. The second resistor network with the resistors R 10 to R 18 is designed accordingly. The cable to be tested C is connected at one end E 1 to the testing device and at the other end with the test plug T. The resistors R 10 to R 18 in the second resistance network are connected to the test device via the common connection point S 2 and the cable shield SH, although not shown, this connection runs through the shield SH to a cable end E 1 and within the test device to a switch SW, to which the common connection point S 1 of the resistors R 1 to R 9 of the first resistor network is also connected.

The connections of the test facility with the two resistance networks are decoupled per wire by diodes D 1 to D 9 and D 10 to D 18 . Both resistor networks are connected to a stepper test signal generator and a comparator circuit, which will be explained in more detail.

The test procedure for the cable C will now be described. The test electronics are put into operation by means of a switch E. By pressing switch E, voltage is applied to the test electronics and a POWER-ON-RESET is triggered for a counter IC 2 and two FLIP-FLOPs FF 1 and FF 2 , and a clock generator IC 3 begins to generate counting pulses. The high state of the inverting output of the FF 1 causes a red LED to light up and at the same time blocks the counting process of the step signal test signal generator, which consists of the clock generator IC 3 , the counter IC 2 and a decimal decoder IC 5 . An LED display is therefore zero. A short pulse is applied to the set input of FF 1 by pressing button P. Setting the FF 1 has the following effects:

• 1. The red LED goes out;
• 2. A green LED gn starts to light up;
• 3. The FF 2 is prepared for setting by a pulse H at the J input;
• 4. The blocking of the counter IC 2 is canceled.

With the next H pulse of a clock generator IC 3 , the stepping test signal generator IC 2 , IC 5 begins to run.

The principle of the test procedure is that each cable core A 1 to A 9 is imprinted with a very specific, individual ohmic resistance in the kiloohm range corresponding to the second resistance network. This resistance is in the kilo-ohm range, so that the total resistance was available, which also depends on the resistance of the respective cable wire. is influenced as little as possible. This total resistance also limits the length of a cable to be tested. During the test process, the resistance values R 1 to R 9 are compared in succession with the corresponding values from R 10 to R 18 . The individual resistors are compared by measuring the voltage drops across measuring resistors R 19 and R 20 , which are each assigned to the two resistor networks within the comparator circuit.If the voltages UR 19 and UR 20 are the same in a specific test situation, the resistances flowed through are also the same . This state is only possible if the corresponding wire and its conclusion are also correct with regard to the assignment.

If there is no galvanic connection to the respective resistor R 10 to R 18 , UR 20 is "0". If there is contact with an adjacent cable core, two resistors are connected in parallel in the test connector T, and the voltage UR 20 is significantly greater than the comparison voltage UR 19 . When swapping z. B. the connections of the wires A 2 and A 9 , the test process is interrupted for both wires. The same test result is obtained without swapping and with galvanic interruption of both wires. A manual check of the individual wires is then required. The touch of non-adjacent connections of the wires can be detected. In the prior art, this can only be done with great effort, since all wires must be checked individually for contact with the others.

The voltages occurring at the measuring resistors R 19 and R 20 are amplified within the comparator circuit by two identical operational amplifiers IC 8 . If there is a perfect connection within cable C, both amplifier outputs provide the logical value L, in the event of a fault, one of the two outputs supplies the signal H.

In the following logic, which comprises three NOR gates, the amplifier outputs are linked to one another in such a way that in the event of a fault, state L is present at output 10 of IC 6 within a counter pause. The FF 1 and FF 2 are reset by the three NOR gates following. This will stop the test process. The counter IC 2 remains exactly at the value that corresponds to the defective cable wire connection.

This means that the corresponding wire in the LED display assigned number is reproduced. At the same time also lights up the red LED stops.

The test procedure can be repeated by pressing button T to be continued. The green LED gn lights up again, until a new error occurs, appears in the LED display again the same number, so it can be concluded that the relevant wire of the cable is not galvanic Has contact.

Lights up after the second start after briefly lighting up the green LED immediately turns on the red LED, and the display has only increased by one value, so one can conclude that there is a metallic contact between two neighboring veins. But it can also be two neighboring de-energized conductors act, which is relative  rarely occurs. Become two non-adjacent cable cores located as an error, you can touch the concerned wires or two independent currentless Close veins.

If the red LED lights up immediately after starting the first test procedure in connection with the "1", this does not necessarily have to be a fault in the first wire, but it may also be because the cable connection has a defective or no shield at all Has. In order to be able to carry out the test anyway, the switch U, SW is provided, by means of which the output 14 of the counter IC 5 of the stepping test signal generator IC 2 , IC 5 to the resistor R 1 of the first resistor network and to the resistor R 10 of the second resistor network is interrupted becomes. This means that no test current can flow in counter state "1" and the counter jumps to the value "2". The test current flows in this case on the one hand via R 2 and R 1 and via R 19 to ground, and on the other hand via the second cable lead A 2 to be tested, via R 11 and R 10 and via the first cable lead and R 20 to ground. If the connection is perfect, the two are the same after branching through flowing resistors and thus the voltage drop at R 19 and R 20 . All wires A 2 to A 9 are checked via wire A 1 , which serves as a return conductor. This also indirectly tests the first wire. If an error is displayed for all wires A 2 to A 9 , it is certain that only the first wire A 1 is not faultless.

Claims (9)

1. Device for the electrical testing of multi-core electrical cables, in which the individual wires are tested step by step in succession, the test result is displayed, the test process is interrupted when a fault condition is detected and the faulty wire is displayed, characterized by the following features:

• a) Within the test device there is a first resistor network (R 1 to R 9 ) with different resistors connected to one connector (S 1 ) and to the other connector with test signals in a number equal to the number of cable cores (A 1- A 9 ), whereby one resistor is assigned to one wire,
• b) a second resistor network (R 10 to R 18 ) with different resistors connected to one connector (S 2 ) and to the other connector to which test signals can be applied, in a number equal to the number of cable cores, with resistance values equal to those of the first resistor network (R 1 to R 9 ) and with the same resistance assignment to the wires can be connected with the cable (C) connected to the test device at one end (E 1 ) to the other end (E 2 ) of the test device,
• c) a stepper test signal generator (IC 2 , IC 3 , IC 5 ) within the test device is connected directly to the first resistance network (R 1 to R 9 ) and to the second resistance network (R 10 to R 18 ) via the test Cable (C) connectable,
• d) a comparator circuit (OP 1 , OP 2 ) within the test device compares the voltage drops occurring at the same resistances of the two resistor networks (R 1 to R 9 , R 10 to R 18 ) and generates a comparison signal, and
• e) the connection of the second resistor network (R 10 to R 18 ) to the comparator circuit (2 × IC 8 ) leads with a shielded cable from the common connection point (S 2 ) of the second resistor network (R 10 to R 18 ) the shield (SH) or, in the case of a cable without shielding, via a selected wire (A 1 ) and the associated, upstream resistor (R 10 ) of the second resistor network back to the test device.

2. Device according to claim 1, characterized in that the resistors of the first and second resistor network (R 1 to R 9 , R 10 to R 18 ) are ohmic resistors. 3. Device according to claim 1 or 2, characterized in that each resistance network (R 1 to R 9 , R 10 to R 18 ) is assigned a respective measuring resistor (R 19 , R 20 ), which are of the same size. 4. Device according to claim 2, characterized in that for a PC cable, the resistance values in the kilo-ohm range lie. 5. Device according to one of claims 1 to 4, characterized in that the connection of the first and second resistor network (R 1 to R 9 , R 10 to R 18 ) with the stepper test signal transmitter (IC 2 , IC 3 , IC 5th ) is decoupled via diodes (D 1 to D 9 , D 10 to D 18 ). 6. Device according to one of claims 1 to 5, characterized by a changeover switch (SW, U) for switching over to testing cables without shielding, in which the connection of the stepping test signal transmitter (IC 2 , IC 5 ), each with the same resistor the first and second resistor network (R 1 to R 9 , R 10 to R 18 ) interrupted and the comparator circuit (OP 1 , OP 2 ) is connected to the corresponding wire at one end (E 1 ) of the cable. 7. Device according to claim 1, characterized in that when switching by means of the switch (SWU) when testing a cable without shielding a connection via the resistance of the first resistor network, which is assigned to the wire under test, and the resistor (R 1 ) of the first resistance network, which corresponds to the selected wire (A 1 ), is produced for the comparator circuit (OP 1 , OP 2 ). 8. Device according to claim 1 or 7, characterized in that when testing a cable without shielding the resistor (R 10 ) of the second resistor network, which corresponds to the selected wire (A 1 ), and the corresponding resistor (R 1 ) of the first Resistor network are short-circuited. 9. Device according to one of claims 1 to 8, marked by a downstream of the first resistor network Resistance potentiometer to adapt to the resistance the veins to be measured.