SU1764003A1 - Under-testing object group short circuit simulator - Google Patents

Abstract

Use: for testing electrical equipment and in stands for group testing of power sources, mainly electric welding. SUMMARY OF THE INVENTION: The simulator contains a power common switch (1), four distribution switches (7.1, 7.2, 7.3, 7.4), a load (3), and four control cells

Description

FI.4

The invention relates to electrical equipment testing and can be used in stands for group testing of power sources, mainly electric welding.

Known simulator short circuits in the aircraft electrical network (as. No. 773534, cl. G 01 R 21/02). The simulator contains a power common switch connected by its power output to a common bus, a group of distribution switches, each of which is connected by a control input to the output of its control cell, and a power output to the first output of the power source. Switching the source through appropriate resistors simulates various modes of intermittent short circuits.

The closest in technical essence to the claimed solution is the short circuit simulator in application 473541 / 24-21, a positive decision from 02.03.90. The simulator contains a power common switch connected by a power output to a common bus (load), and power inputs to a power output of distribution switches, each of which is connected to a common bus through a corresponding control object through a power input. The control cells, which specify the sequence of operations, are connected by their outputs to the control inputs of the distribution switches. As a result, the distribution switches are both turned on and off in a de-energized state, which allows for a significant service life of test short circuits. However, this simulator allows group testing of objects with only soft external characteristics, since the formation of switching control signals is carried out by varying the voltage at the terminals of the control object.

The aim of the invention is to enhance the functionality by providing testing of test objects with both soft and hard external characteristics.

This goal is achieved by the fact that in a well-known circuit simulator containing control cells with a signal input and distributing switches according to the number of control objects, a power common switch connected by a power output through the load to the first terminals of the objects to be monitored the outputs, respectively, are mine and odd distribution switches, the power input of each of which is connected to the second output of its control object, and the first control input of each distribution guide switch is connected to the control output of the previous cell according to the invention the second control input dispensing switch coupled to an output of the subsequent cell

0 control, the signal input of each of which is connected to the second output of its control object.

A comparison with the prototype reveals the presence of new connections between control cells, distribution switches and control objects, which allows to conclude that the technical solution meets the novelty criterion.

Comparison with other well-known technical solutions in this and adjacent areas of technology shows that circuit elements are known. However, the presence of new connections between them determines the appearance of new properties by the device, allowing

5 to form switching control signals according to the new output effect, i.e. by tone. Thus, the simulator allows the power supply (control objects) to be tested as soft,

0 and with hard external characteristics. It is also possible to conduct simultaneous tests of a mixed group, the composition of which includes power sources with different types of external characteristics.

5 The presence of new properties makes it possible to judge the compliance of a technical solution with a criterion of significant differences.

FIG. 1 shows a functional circuit simulator closures; in fig. 2 0 schematic diagram of a possible implementation.

The simulator closures contains the power common switch 1, connected by the power output 2 to the load 3, and the first power

5 input 4 and the second power input 5 - with power outputs 6.1 ... 6.4, respectively, even and odd distribution switches 7.1 ... 7.4, power input 8.I (where i is the number of the test object), each of which is connected to the second output 9.I of my control object 10.1, the first output 11.i of which is connected to the load 3. Each of the distribution switches 7.1 ,,. 7.4 has its own control cell

5 12.1 ... 12.4, with the first control input 13.1 of the distribution switches 7.1 connected to the output 14. (- 1) of the previous control cell, and the second control input 15.1 to the output 14 (1 + 1) of the subsequent control cell. Signal input 16.1

each control cell 12.1 is connected to the second terminal 9.1 of its control object.

Power common switch 1 can be performed on the basis of various semiconductor switches: transistors, thyristors, and triacs. The distribution switches 7.1 ... 7.4 are electromechanical devices. Current control can be used as control cells 12.1 ... 12.4. Control objects 10.1 ... 10.4 are power sources.

The load when simulating specific modes of closures of different types of equipment can be set from units of mΩ to units of ohms. In particular, when simulating the short-circuit modes of electric welding equipment, the load 3 is a bus with an impedance of 8-10 mΩ in accordance with GOST 13821-77.

The chains of the initial launch of Moryt are varied and unrepresented in the diagram.

The simulator closures works as follows.

In the initial state, power switch 1 is connected by output 2 to input 5, distribution switch 7.1 is turned on. When current of the control object 10.1 flows through the load 3 at the signal input 16.1 and the output 14.1 of the control cell 12.1, a signal is generated that turns on the distribution switch 7.2 in the de-energized state. When switching the output 2 of the power common switch 1 to the power input 4 via the circuit: the second output 9.2 of the control object 10.2. power input 8.2 and power output 6.2 of distribution switch 7.2, power common switch 1 common bus 3 devices, first output 11.2 of the control object 10.2 - current flows. The control cell 12.2, removing the current signal from the second output 9.2 of the control object 10.2, turns on distribution switch 7.2 at input 13.3, turns off distribution switch 7.1 at input 15.1, and the switching occurs in a de-energized state. Thus, by the time of the subsequent switching of the power common switch 1, the power circuit of the secondary circuit of the control object 10.3 turns out to be prepared for short circuit to load 3. With further switchings of the power common switch 1, the short circuit simulator works in the same way, connected via distribution switches 7.1 ... 7, 4 control objects 10.1 ... 10.4 to load 3. ensuring the sequence of commutations by means of control cells 12.1 ... 12.4 signal at output 14.1 ... 14.4 any of which occurs in the case of current flow corresponding to project control

An example of the use of the invention is a load simulator used for testing the reliability of a wide class of electric welding power sources (such as APR, VDM, VDG), including for groups resistant from power sources with external characteristics of various types. As a forceful general

switch 1 uses a semiconductor trigger on two thyristors T2-320, with an alternating current switching capacitor: on the quality of distribution switches 7.1 ... 7.4 - electromagnetic

self-locking starters; as control cells - current relay type PT.

Group tests are performed regardless of the type of external characteristic of power sources (control objects) and.

therefore, in comparison with the prototype, the functionality is extended while maintaining an increased switching resource due to switching of electromechanical distribution switches in a de-energized state.

Claims (1)

Formula of the Invention Simulator of closures of a group of objects control, containing control cells with a signal input and distribution switches according to the number of control objects, a power common switch connected by a power output through the load to the first the control object terminals and the first and second power inputs to the power outputs of the even and odd distribution switches, the power input of each of which is connected to the second output of the corresponding control object, while the first control input of each distribution switch is connected to the output of the previous control cell , characterized in that, in order to expand the use area, by controlling objects with both soft and hard characteristics, the second control input of the distribution switch is connected to the output of the subsequent control cell, the signal input of each of which is connected to the second output of the corresponding control object. in L