SU1018247A1 - Step-by-step distributor - Google Patents

Description

00

Yu

four

-si

The invention relates to automation and can be used in devices for discrete information processing, counting and control.

A step switch is known that contains a single-ended ring scaling circuit with a series-connected thyristor and a relay winding in each of the links, connected to a constant voltage source, a generator of forward pulses and two closure contacts in each of the links G 1 "

The disadvantages of the known device are reduced reliability, due to the sensitivity of the circuit to interference spreading over the power supply circuits, and considerable power consumption in the absence of a control signal. These factors in a number of cases limit the functionality of the device.

The closest technical solution to the invention is a stepper distributor containing switching cells, the power buses of which are connected via a control key to the power supply buses, and the input of the control key to the clock pulse bus, with the switching cells made on the remote switch of the including winding, in the circuit of which the thyristor is turned on, the breaker winding and the group of switching contacts, the opening contact of which in each cell, starting from the second, is connected by a movable contact th previous cell, make contact all cells except the last is connected to the control electrode of the thyristor subsequent cell, a control electrode of the thyristor of the first cell is connected to its own cell NC contact and the movable contact of the last cell is connected via a capacitor to the bus clock T2.

A disadvantage of the known step distributor is low functionality, since it is necessary to have N cells for the distribution of t signals.

The aim of the invention is to extend the functionality by increasing the number of signal distribution steps.

The goal is achieved by the fact that, in a stepper distributor containing switching cells, power rails 18247

connected via a control key with power supply tires, g

the control key input is with a clock pulse bus; in this case, the switching cells are made on a remote switch consisting of the switching winding, in the circuit of which the thyristor, the breakaway winding and the group of switching contacts, which disconnect the contact in each cell, starting from the second, is connected to the moving contact of the previous cell, the closing contact of all cells, except the last one, is connected to the control electrode of the next cell thyristor, the control electrode of the first cell thyristor is connected to the disconnect terminal own cell clock, and the moving contact of the last cell is connected via a capacitor to the clock bus, an additional thyristor is inserted into each cell, which is connected to the breaking winding circuit, and an additional group of switching contacts whose disconnect contact is connected to the control electrode of the additional thyristor of the next cell, and the closing contact in the first cell is connected to the control electrode of the additional thyristor of its own cell.

The drawing shows a diagram of the proposed device. ,

The stepper distributor contains a source of 1 clock pulses, a capacitor 2 and cells 3 connected to a source k of a constant voltage

0 through the control key 5. Each of the cells 3 contains a remote switch with a switching winding 6 and a breakaway winding 7. In the switching winding circuit 6, a thyristor 8 is turned on.

A thyristor 9 is included in the breakaway circuit 7. The beginning of the windings of the remote switches and the cathodes of all the thyristors, respectively, are combined and connected to the positive and negative power supply busbars of the cells. All cells 3 contain a switching group of contacts TO, the disconnecting contact of which, in each cell, starting with the second, is connected to the moving contact of the previous cell, the disconnecting contact in the first cell is connected to the control electrode of the thyristor 8 of its own cell, the closing contacts of all cells except the last ,

| connected to the control electrodes of the thyristors 8 subsequent cells. All cells except the last also contain the second switching group of con, cycles 11, the disconnecting contact of which is connected to the control electrode of the thyristor 9 of the next cell, the closing contact in the first cell is connected to the control electrode of the thyristor 9 of its own cell, and the moving contacts of the second the switching group of contacts 11 is connected to the closing contact of the next cell, and the movable contact of the second switching group of contacts 11 in the penultimate cell is connected to the closing contact of the switching contact groups of the last cell.

Stepping switch works as follows.

The first clock pulse from the clock pulse source is fed to the input of the control switch 5 and through the capacitor 2 and the circuit of the opening contacts in the switching group of contacts 10 to the control electrode of the thyristor in the cell. The key k is closed for the duration of the clock pulse and the voltage of the power source k is applied to the cells. The thyristor 8 of cell 3 opens as the current from the first clock pulse flows through its control electrode and energizes the turn-on winding 6, the remote switch of the first cell 3 operates by transferring its moving contacts to the switching groups of contacts 10 and I and thus connects the control electrode thyristor 8 of the next cell 3 to the source of t clock pulses. However, at this point in time, the capacitor 2 is already charged, the current in the thyristor control circuit drops to almost zero and the thyristor 8 pogs. The cell does not turn on, the control switch 5 remains closed for the time required for the remote switch to operate whereby the key 5 is opened, by disconnecting the cells 3 from and, at the constant voltage source, the remote switch of the cell retains its new state. G the arrival of the second clock pulse again closes the control switch S, but the thyristor 8 of the second cell 3 is already opened, since the control electrode of this thyristor is connected to the source 1 of clock pulses. When the thyristor 8 cell 3 is turned on, the switching winding 6 of the remote decoder of this cell is energized, which triggers the remote switch and returns the moving contacts in the switching groups of contacts 10 and 11 of cell 3. Thus, each clock pulse from the clock source 1 causes the thyristors 8 to turn on 8 and the operation of the remote switches in the cells 3. With the arrival of the {Lth pulse, the thyristor 8 of the last cell also turns on, the current passing through the VC / Winding winding 6 This switch triggers its operation and reassigns the moving contact in the switching contact group 10. However, by this time all the switching groups of contacts 10 and 11 have already moved their moving contacts and with the transfer of the moving contact in the switching group of contacts 10 cells 3 a circuit is created to connect to the source 1 of the tatovy pulses of the control electrode of the thyristor 8 cell 3. With the arrival of the 1 and 1) pulse, the thyristor 9 of the first cell 3 is turned on, the current passing through the breakaway winding 7 triggers station switch and transfer of moving contacts in switching groups of contacts 10 and 11 to the initial state. This creates iienb to turn on the thyristor 8 in cell 3. Next, the operation of the distributor proceeds as described above and, with the arrival of the () pulse from the clock source 1, the thyristor 8 of the last cell 3 switches on the current passing through the breaker winding 7 of the remote switch, causes its actuation and return of the moving contact-in the switching group of contacts of the cell 3 to the initial state. The whole circuit assumes the initial state and with the arrival of the C 7. and +1) th clock pulse, the distribution cycle is repeated.

As the outputs of the distributor, you can use thyristor anodes 8 and 9 in the cells; inputs control thyristor electrodes; if necessary, complete galvanic isolation of circuits, additional contacts of remote switches connected in the same way as switching groups of contacts 10 and G.

Thus, this technical solution makes it possible to obtain a stepper distributor with the number of Q cells and the number of distribution steps. This broadens the functionality of the distributor and, if necessary, distributes a large number of pulses, allows to simplify the design and reduce the number of elements.

Claims (1)

A STEP-BY-STOP DISTRIBUTOR containing switching cells, the power bus of which is connected via a control key to the power supply buses, and the input of the control key to the clock bus, while the switching cells are made on a remote switch consisting of a winding, in the circuit of which a thyristor is connected, of a breakaway winding and a group of switching contacts, the opening contact of which in each cell, starting from the second, is connected to the movable contact of the previous cell, the closing contact of all cells, except the last connected to the thyristor electrode of the next cell, the control electrode of the thyristor of the first cell is connected to the opening contact of the own cell, and the movable contact of the last cell is connected through the capacitor to the clock bus, characterized in that, in order to expand the functionality, each cell introduced an additional tiris— ·. a torus, which is connected to the 8th circuit of the baffle winding, and in all cells except the last g, an additional group of switching contacts is introduced, the opening contact of which is connected to the control electrode of the additional thyristor of the subsequent cell, and the closing contact in the first cell is connected to the control electrode of the additional thyristor own cell.