SU1704110A1 - Device for control electric connector contact mating - Google Patents

Abstract

The invention relates to automation and can be used to control the docking of electrical connectors of multi-device systems. The purpose of the invention is to increase the efficiency and productivity of the control. The sensor parameter meter allows you to measure the input impedance of the sensors connected in parallel through the controlled contacts of the electrical connector. The nominal values of the parameters (e.g., conductance) of the sensors are members of the numerical series. Thus, knowing the impedance of the sensors connected via the electrical connector, it is possible to calculate the faulty contact (s) of the connector. 1 il.

Description

The invention relates to automation and can be used to control the docking of electrical connectors of multi-device systems.

A device is known for diagnosing the location of a malfunction of a complex object, containing a control unit connected to the main electrical circuit passing successively through all the connecting elements of a complex object, an additional electrical circuit and resistors connected to the input and output of each node of a complex object between the main and additional electrical circuits, with the input of the first and the input of the last node of a complex object connected to the measurement unit.

The closest in technical essence to the present invention is a device for automatically checking the correctness of wiring, containing a source of a control signal, a switch, a control unit, a block for fixing faults, the first resistors according to the number of checked

targets, the common output of the pilot signal source is connected to the common bus of the device, the output of the pilot signal source is connected to the control input and to the switch output, each input of which is connected to the beginning of the corresponding tested circuit, the end of which is connected to the first output of the first resistor. the control is connected to the output of the block for fixing faults, the second resistors are based on the number of tested circuits, each of which is connected in parallel to the corresponding tested circuit and the second rows of the first resistor connected to the common bus device, the pilot signal source is designed as a current generator, and a control unit - ie an analog decoder, the resistance of the first and second resistors are equal one.

The disadvantages of the known devices are structural complexity, due to the large number of control circuits, and limited diagnostic

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possibility of avc;: capturing the impossibility of determining the inconsistency with an accuracy of one connector.

The aim of the invention is to simplify the design by reducing the number of cable connections and deepening the diagnostic capabilities by detecting faults with an accuracy of one connector.

The goal is achieved by those. that in the device containing p electrical connectors, sensors, leads for connecting sensors to the contacts of monitored electrical connectors, a sensor condition monitoring unit, a fault fixing unit, terminals for connecting the electrical connector counterpart, a gauge parameters of the sensors, the output of which is connected to the block of fixation of malfunctions, and the input - with the leads for connecting the monitored contacts of the response part of the electrical is connected , while all of these sensors are connected through the contacts of a monitored electrical connector in parallel with each other, and the nominal values of the parameters of the sensors are members of a numerical series, for example, the geometric progression a + + ... + aRn, where R 2 and a any number and the input of the parameter meter is electrically connected to the fault fixing unit.

The drawing shows a block diagram of the proposed device.

The device consists of blocks containing n monitored connectors and n gauges 1, for example, resistors, pins 2 for connecting - gauges to the contacts of the monitored electrical connector. , coupled with the return part of /, the electrical connectors with the water 5, second through the cable network pa-pc-.ie-r: tHO are connected between ibey i- with the input of the unit 3 of the state of the control detchiko (for example, conductivity), the output of which is connected to the EXASDU unit 4 Fault fixation.

The device works as a speedometer.

Connect all the block and cable t 0-rollable connectors of a complex object. A 3 gauge sensor parameters are used for a total measurement of all 5 rztpoln sensors on, for example, the resistances of the resistors that are connected to the contacts of the block-controlled connectors by the leads 2.

The ratings of all sensors 1 (resistors) are compared with each other in the following way. they were read by a number of numbers, for example, a geometric progression with the property that by the sum of the known members of this row in any set it is always possible to identify the missing members (with incomplete connectors) of a complex object.

Let us assume that the geometric progress is chosen from the series as aR aR + aR +. ... +. where R 2. When R 2, p 5, and - the conductivity of the resistor and 10.

At the same time, the terms of the row (resistors - sensors) are as follows, 10. 2 x 10; 4 x 8x 103; 16 h.

Suppose that the second and fourth connectors are not joined, i.e. there are no members of the row 2 x and 8 x 103, then the sum of the remaining members is 21 x ohms.

The calculation of the missing members is carried out according to the following algorithm: the sum of prog.de is compared with the senior member of the series; if the sum is not less than the senior member, its presence is fixed and the senior member aRn is subtracted from the sum; if the sum is less than the senior aRn member, then its absence is fixed (i.e., the n-th connector mismatch), the subtraction is not performed.

Then the same actions are repeated for the remaining sum and n - 1 of the row member (aRn), etc.

For a numerical example: 1 step 21 x - 16 x 5 x x.

The 5th connector is docked; 2 step5x8 x 103 4th connect-, spruce is not docked; 3 step 5 x - 4 x, the 3rd connector is docked; 5 pitch 10 30m - 10 0m 1 0, the 5th connector is docked.

The conductivity value noted by the sensor monitoring unit 3 is converted by the non-reparable fixing unit 4 and given to the operator in the form of complete docking information or the numbers of unconnected connectors are reported if the fixing unit fails to turn on the computing device, or unit 4 of the fault malfunction informs the operator of the measurement result of the unit 3 for monitoring the state of the sensors, spertsr according to the table; -, .. computation 1 -. . matching numbers of non-detachable connectors.

5In the case of detectors 1, inductance capacitors or various combinations of resistors, capacitors and inductances can also be used, with the unit 3 for monitoring the status of sensors

must provide a measurement of the conductivity of the required type.

This allows the number of monitored connectors to be increased without increasing the requirements for the accuracy class of sensors 1 and sensor state monitoring unit 3.

The docking control subsystem of connectors has several thousand monitored connectors grouped into an average of 20 connectors in a group. The control of connectors in a group is performed by checking circuit integrity from the jumpers connected in series in the cable being tested and installed in blocks on the contacts of monitored connectors. At the same time, the absence of joining of any one or several connectors in the group by the control subsystem does not differ from each other and further troubleshooting is performed by means of a very laborious manual search.

It should be noted that some of the connectors are in hard-to-reach places and their control requires the dismantling of the devices and equipment already installed.

The use of devices that provide diagnostics for the absence of docking with an accuracy of one connector cannot practically be used, since it requires that the number of taps from connectors be not less than the number of connectors, which is unacceptable for developing enterprises that are critical to gabrritic-mass parameters.

When using the proposed device, regardless of the number of sensors, two wires are always used for one group of supported connectors, i.e., cable complications do not occur.

If, for example, geometric progress is used as a series, aR + aR2 + ... +. where R 2. the sensors consist of parallel connected resistors and capacitors, and 10 ohms can be accepted for resistors and 300 net for capacitors ac. taking for resistors l 8, we obtain the resistance of the eighth term in a row of 12E kΩ. for example, on resistor

Type S2-29V OZH0.467.099TU produced with tolerances of ± 0.05%.

For capacitors, it is possible to accept p 6 and realize the first members of the row on capacitors of the type "SOT OZH0.461.123TU, manufactured with a tolerance of ± 0.25%.

Thus, the total number of monitored connectors in a group is about 20, therefore, the approximate acceleration of the search for disconnected connectors can be considered equal to 20 times.

Since the total number of connectors in the system is several thousand hours, a significant number of them are in hard-to-reach places and cases of erroneous docking or inconsistencies are therefore frequent, the use of the proposed device will greatly simplify the commissioning during manufacture and troubleshooting during operation.

The objects in which it is advisable to use the proposed device are complex systems in which automatic control of the docking of connectors, including detachable

piping assemblies and other devices where plug-in connections need to be controlled.

Claims (1)

The invention The device for controlling the docking of the contacts of an electrical connector, comprising sensors, leads for connecting sensors to the contacts of a monitored electrical connector, a sensor condition monitoring unit, a block for fixing faults, leads for connecting the counterpart of an electrical connector, in order to increase the efficiency and productivity of the control, a sensor parameter meter, the output of which is connected to the fault-fixing unit, and the input with leads for connecting the monitored contacts of the counterpart electrical connection, all of these sensors are connected through the contacts of a monitored electrical connector in parallel with each other, and the nominal values of the sensor parameters are numeric members with yes. R I .. - I / i .. J ... ... J &