SU403063A1 - STEP DISTRIBUTOR - Google Patents

Description

This invention relates to the field of automation.

Stepper distributors are known which contain a source of direct voltage, a normally open switch, a source of clock pulses and a cell, each of which is made on a remote switch with switching and breaking windings, one moving and two fixed contacts that form a cell selection circuit.

A disadvantage of the known devices is reduced reliability and significant power consumption. Reliability is reduced due to sensitivity to interference propagating along the supply circuits, and also due to the fact that the contacts of the remote switches switch the currents of inductive loads. Power consumption increases due to the presence of large capacitors.

The aim of the invention is to increase reliability and reduce energy consumption. This is achieved by the fact that a thyristor connected by the anode to the end of the turning-on winding of the remote switch of its cell and to the end of the break-through winding of the remote switch of the previous cell, to the control electrode to the second non-moving contact of the remote switch and the previous one is inserted into each cell.

cells, and the cathode - to a common bus, connected to the second end. windings of all remote switches via a successive circuit from a constant voltage source and a normally open-open key, the input of which is connected to the output of a clock source source connected through a capacitor to the remote contact of the last switch.

The essence of the invention is illustrated in a drawing.

Stepper distributor assembled from cells,. . . I-.Y, each of which contains a remote switch with an energizing winding 1 and a breakaway winding 2, a moving contact 3 and two fixed contacts 4 and 5. The contact 5 of the remote switch of each cell is connected to the control electrode 6 of the thyristor 7 connected to the Winding 2 switch of the given circuit and at the price of winding 1 of the remote switch of the next cell. The contact 4 of the switch of each cell, except the cell, is connected to the mobile shock of the 3 remote switch of the previous cell. The contact 4 of the cell switch is connected to the contact 5 of the remote switch of the last cell, the movable contact 3 of which is connected via capacitor 8 to the output of the source of 9 TOTAL pulses connected to the input of the trigger switch 10 connected in series with the source II of constant voltage. In the initial state, the key 10 is open, the thyristors 7 are disconnected from the voltage source 11, and in each remote switch contact 3 is closed with contact 4. In this case, the supply of voltage to the winding 1 triggers the remote switch 10, and to the winding 2 - to confirm the initial state. The first clock pulse arrives at the input of the key 10 and through a shortening capacitor, to the control electrode 6 of the trist- 15 of the 7 of the 4H 4i. The key 10 is closed for the duration of the clock pulse, and the voltage of the input voltage 11 is applied to the thyristors 7. The thyristor 7 of cell I4 is opened, because current from the first clock pulse flows through its control electrode 20, and energizes the winding of cell 1 and winding 2 cells of cell I4. . As a result, the remote switch of the cell R4 is activated and the initial state of the switch of the RN cell is confirmed. The contact 3 of the remote switch of the cell 41 is transferred to another position (closes with the contact 5) and, thus, connects the control electrode 6 30 of the thyristor 7 of the next cell to the source 9 of clock pulses. However, at this point in time, the capacitor 8 is already charged, the current in the thyristor control circuit drops to almost 35 n, and the thyristor 7 of the cell does not turn on. The key 10 remains closed for the time required for the remote switch to operate, after it is activated it opens, disconnecting the thyristors 7 from 40 constant voltage source 11. With the arrival of the second clock pulse, the key 10 closes again, the thyristor 7 of the H4z cell is already opened, since the control electrode 6 of this thyristor is connected 45 to the source of the 9 clock pulses. When the thyristor 7 cell is turned on, the winding of 1 cell H4z and the winding 2 cell are energized, which triggers the cell switch H4z and returns to the initial state of the cell switch. Thus, each clock pulse advances the operation of the remote distributor switches by one step. The power supply And most of the time (in the interval between clock pulses) is disconnected from the windings 1, 2 and thyristors 7, which increases the reliability of operation and efficiency of the device. Improving the reliability also contributes to the fact that the contacts of remote switches commute low-power thyristor control circuits. Subject of the invention Stepper distributor containing a source of constant voltage, a normally open key, and a source of clock pulses and a cell, each of which is made on a remote switch with switching and breaking windings, one moveable and two fixed coitacts, the first fixed contact of the first switch connected to the second fixed contact of the switch of the last cell, and the first fixed contact of the switch of each cell, starting from the second, is connected to the movable In order to increase reliability and reduce power consumption, a thyristor is inserted into each cell, connected by an anode to the end of the switching winding and remote switch of the previous switch, controlling electrode - to the second fixed contact of the remote switch of the previous cell, and the cathode to the common bus connected to the second ends of the windings of all remote switches through the last A supply circuit from a constant voltage source and a normally open key, the input of which is connected to the output of the clock source, connected through a capacitor to the moving contact of the remote switch of the last cell.