SU1569980A1 - Relay distributor - Google Patents

Abstract

The invention relates to automation and may find application in electrical circuit switching devices. The aim of the invention is to increase the stability of switching loads. Relay distributor contains odd and even switching cells on electromagnetic relays 1-4 with locking contacts 5-8 and closing contacts 9-12 in neighboring switching cells, odd 25 and even 26 buses, input electromagnetic relay 29 with closing contact 31 and switching contact 30 , a frequency divider 27 with a switching contact 28. Optocouplers 17-20, diodes 13-16 and resistors 21-24 are inserted into cells to increase the stability of switching loads. Switching optocouplers is performed by inserting a closing contact 31 into 29. Noe electromagnetic relay 1 yl.

Description

The invention relates to automation and can be used in devices for switching electrical circuits with alternate connection of circuits.

The aim of the invention is to increase the stability of switching loads.

The drawing shows the electrical circuit diagram of the relay distributor.

The relay distributor contains odd and even switching cells consisting of electromagnetic relays with windings 1–4 and closing contacts 5–12, diodes 13–16, optocouplers 17–20 and resistors 21–24, odd 25 and even 26 buses switching, a frequency divider 27 into two with a switching contact 28, an input electromagnetic relay with a winding 29, a switching contact 30 and a closing contact 31, an installation unit 32, a discharge diode 33, a power bus 34 and 35, and an auxiliary bus 36.

In each switching cell, the first terminals of the windings 1-4 of the electromagnetic relay are connected to the power bus 35, and the second terminals are connected through the corresponding closing contacts 5-8 and diodes 13-16 to the corresponding odd 25 or even 26 buses. In addition, the second terminals of the windings 1-4 are connected via the closing contacts of the relay of the previous cell with the corresponding odd 25 or even 26 bus lines. The inputs of the optocouplers 17-20 through the corresponding resistors 21-24 are connected between the additional bus 36 and the power bus 35. The outputs of the optocouplers 17-20 are connected between the additional bus 36 and the connection point of the diodes 13-16 with the corresponding closing contacts 5-8.

As part of the relay distributor, the power bus 34 is connected via an i-plug contact 31 of the input electromagnetic relay with an additional bus 36. Switching contact 30

this relay is a divider input

27 frequencies for two, and the output switching contact 28 of the splitter frequency 27 for two is connected to the odd 25 and even 26 buses. The sliding contacts of the switching contacts 28 and 30 are connected to the power bus 34. The input of the installation unit 32 is connected to the power bus 34, and the output is connected to the second terminal of the winding 1 of the electromagnetic relay.

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five

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five

Relay distributor works as follows.

When voltage is applied to the power busbars 34 and 35, the installation unit 32 generates a voltage pulse that is applied to the winding 1 of the electromagnetic relay and trips the closing contacts 5. As a result of the contacts 5 closing, the supply voltage is applied to the winding 1 through the opening contact 28, the odd bus 25 of the commutation, the diode 13, which causes the winding 1 to block. The winding 2 of the next switching cell is prepared to operate on the even switching bus 26 by closing the contact 10. After the specified switching of the relay This distributor is prepared for operation. When the first input pulse arrives at the winding 29 of the input electromagnetic relay, the switching contact 30 is triggered and switches the frequency divider 27 to another position. In this case, the power bus 34 is connected via the closing contact 28 to the even switching bus 26.

As a result of the switching, the electromagnetic relay is activated and its winding 2 is blocked through the closing (Pin 6 and diode 14. The blocking circuit of the winding 1 is broken, as the odd switching bus 25 is switched off by the switching contact 28. Simultaneously with the turning of the winding 29 of the input electromagnetic relay through the closing contact 31, the optocouplers 17–20 turn on by supplying the supply voltage to the additional bus 36. Switching the supply voltage by the switching contact 28 from the odd bus 25 to the even bus 26 causes about The winding 1 is connected via the transfer power supply circuit 25 and is switched on via the output of the optocoupler 17, since the supply bus voltage 34 is present on the auxiliary bus 36. This voltage is applied to the winding 1 during which time the winding 29 input electromagnetic relay. To ensure reliable operation of the relay distributor - the input electromagnetic relay must have a time delay for switching contacts higher than other electromagnetic relays, which is achieved by shunting the winding 29 using a diode a 33

The work of the remaining cells occurs in a similar way by the arrival of another pulse on the winding 29 of the input electromagnetic relay and switching the bus supply voltage from the even bus 26 to the odd bus 25. I

Compared to the known introduction to the relay distributor of the closing contact 31 and in each cell of the optocoupler switching, it eliminates the storage capacitors in the switching cells and increases the switching stability by eliminating the overlapping of the signals of neighboring cells.

image formula

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Relay distributor containing even and odd switching cells, in which the electromagnetic relay is connected to bus Minus power by the first output of the winding, and the second output is connected via switching contact of the electromagnetic relay of the previous cell to the corresponding switching bus, frequency divider by two, whose inputs are connected to fixed stationary contacts, the input electromagnetic relay, and the outputs are made in the form of switching contacts and are connected to fixed contacts with even and odd tires,

at the same time, the moving contacts of the input electromagnetic relay and the frequency divider by two are connected to the bus Plus power, which is different from the fact that, in order to increase stability, a closing contact is introduced into the input electromagnetic relay, which is connected between the bus Plus power and the additional bus, and an optocoupler is inserted into each switching cell,

0 a diode and a resistor, with the input of the optocoupler through a resistor connected between the additional bus and the bus Minus, the output of the optocoupler connected to the first output with an additional bus, and the second output

5 through the diode - with the corresponding switching bus and through the closing contacts of the corresponding electromagnetic relay - with the second winding terminal.

Claims (1)

The claims 20 Relay distributor containing even and odd switching cells, in which the electromagnetic relay is connected to the 25 Minus ”power supply line by the first output of the winding, and the second output is connected via the make contact of the electromagnetic relay of the previous cell to the corresponding switching bus, the frequency divider is two, the inputs of which connected to the switching fixed contacts of the input electromagnetic relay, and the outputs are made in the form of switching contacts and connected by fixed contacts to even and odd buses, p and the movable contacts of the input electromagnetic relay and the frequency divider are connected in two to the Plus power bus, characterized in that, in order to increase stability, a closing contact is introduced into the input electromagnetic relay, which is connected between the Plus power bus and the additional bus, and in each the switching cell is equipped with an optocoupler, a diode and a resistor, and the optocoupler input through the resistor is connected between the additional bus and the Minus bus, the optocoupler output is connected by the first output to the additional bus, and the second output through the diode, respectively through the switching bus and through the closing contacts of the corresponding electromagnetic relay - with the second terminal of the winding. ! Compiled by A. Bomko