SU411391A1 - - Google Patents

Description

The invention relates to electrical measuring equipment and can be applied in the development, manufacture and control of relays, contactors, coordinate connectors and other products containing periodically activated contacts.

Devices for measuring the resistance of closed electrical contacts with vibrations are known, comprising a digital voltmeter and a digital time meter, an oscilloscope, a pulse generator, a switch, and an exemplary and adjustable resistance. By adjusting the current through this resistance, a calibration mark is moved on the oscilloscope screen that is moved vertically along the curve section under study. The resistance of the closed contacts under the influence of vibration is counted and the resistance value is read by a multi-scale instrument connected in series to the sample resistance and calibrated in resistance units. However, these devices do not measure the dynamic resistance that occurs with each contact closure due to internal forces generated by the movement of the contacts and other parts of the relay containing these contacts, regardless of the effect of external vibration. In addition, B connection with the specific nature of the dynamic resistance arising

at each contact closure, it is necessary to measure not only the instantaneous value of the contact resistance, but also such characteristics of dynamic resistance as the duration of the process of resistance change to a relatively stable value (static contact resistance), the time interval between the moment of the first contact of the contacts and the moment when resistance reaches a maximum value, as well as other time intervals that are important for the study and control of the considered detection in digital form.

The purpose of the invention is to simplify the measurement of the parameters of the dynamic resistance of the contacts after they are closed; This is achieved by placing a measuring key between the oscilloscope input and the switch output, protecting the measuring system from overloading, and the calibration mark being formed on the screen, made of a L-shape and moving both vertically and horizontally, for which the switching relay is connected through the delay unit, and the moment it is turned on can be adjusted relative to, for example, the time the relay winding is turned on (off) or the closing time of the contacts under study. To read the parameters parallel to the reference impedance of a digital voltmeter, and between the input and output of the block, an adjustable delay is a digital time interval meter.

The drawing shows fuiczio 1a 11a diagram of the proposed device.

The device works as follows.

The monitored pair of contacts 1 of relay 2 periodically closes, and the signal in the form of a voltage drop on the contacts enters through the switch 3 to the measuring switch 4. At the same time, the delay node 5 is turned on, its output signal starts the sweep of the oscilloscope 6 and opens the key 4 via the tapping control input 7. The signal arrives at the oscilloscope, and the operator adjusts the time, the task; its node of node 5 so that key 4 is open no earlier than the bounce of the closing contacts 1. At the same time, an image of the process will appear on the screen of the oscilloscope The contact voltage-time relationship is used to establish the contact resistance (the current in the contact circuit is kept constant).

An adjustable delay unit 8 is connected by its input, for example, to the output} of a pulse generator 9, the threading relay 2 under test (as shown in the drawing), or to the output of the delay node 5, and the output of unit 8 is connected to the lock input of control 10 of key 4. In addition , to the output of block 8, there is a relay switch winding 3 and a fixed delay block 11, the output of which is connected to the unlocking control input 12 of key 4. The delay time of block 11 is chosen equal to the switching time of the relay 3 switch, including the bounce of its contacts and others vlivayuschies processes. With this inclusion on the screen at the end of the measurement cycle, a calibration mark of L-shaped form is formed. The operator moves the horizontal part of this tag vertically, changing the current flowing through the reference resistance 14 by a rheostat 13 and horizontally changing the latency of the block 11 and thus moving the calibration mark to the test section of the contact resistance curve. The measurement cycle ends with the key 4 being closed via the locking control input 15 of the generator 9 pulses when the winding of the relay 2 is turned off (on), i.e., before opening of the contacts 1 being investigated.

The measurement results are counted: when determining the instantaneous dynamic resistance value - by indicator

an electronic digital voltmeter 16 connected to the reference resistance 14. To obtain measurement results directly in units of resistance, the comma is shifted by one bit to the right each time by 10 times the load current; when determining the time parameters, use the digital time meter indicator 17, the first input of which (start) is connected in parallel to the input of block 8, and the second (stop) - to the output of block 8 or block 11 (as shown in the drawing).

In drawing 18 - the load resistance of the investigated contacts 1.

Subject invention

A device for measuring the dynamic resistance of electrical contacts, containing an exemplary and adjustable resistance, a digital volt meter and a digital time meter, an oscilloscope, a pulse generator, a switch for alternately connecting to the input "Y of the oscilloscope of the contacts being investigated and the sample resistance, characterized in that the purpose is to simplify the measurement of the parameters of the dynamic resistance of the contacts after they are closed, it is equipped with a block

a fixed delay connected to one digital time interval meter input, a measuring key with two unlocking and two locking control inputs connected between the switch output and the input "On the oscilloscope, an adjustable delay node whose input is connected to the contacts being studied, the first output to the first unlocking the input of the measuring key, and the second output to the synchronization input of the oscilloscope sweep, an adjustable delay unit whose input is connected to the first output of the pulse generator owls, occasionally connected to the second input of a digital interval meter

time, and the second output of the pulse generator to the first locking input of the measuring key; the first and second outputs of the adjustable delay unit are connected to the relay coil of the switch and to the second locking input of the measuring key, and the third output to the input of the fixed delay unit, the output of which is connected to the second unlocking input of the measuring key, and parallel to the exemplary

resistance connected digital voltmeter.