SU805437A1 - Device for control of on-route switch operation - Google Patents

Description

54) DEVICE FOR CONTROLLING THE OPERATION OF THE TRAVEL SWITCH

to control the position of mechanisms moving in hermetic volumes under conditions of aggressive media and high temperatures due to a decrease in the reliability of its operation.

A device for controlling the operation of a trip switch comprising a radio-controlled contact, a bias winding, an excitation winding, power sources and a pulsating voltage, a driving element, a polarized control relay with two stable states, two thyristors, a transistor, a zener diode, is known. , a charging circuit, resistors, capacitors, diodes, a dynistor and a switch, the excitation winding being connected through a switch to a power source; one of the outputs of the magnetic control of the contact is connected to Yusu power source, the Zener diode cathode is connected to the connection point of the RC charging circuit resistor, one of the terminals of each winding of the polarized relay is connected to one output of one of the capacitors, the other terminals of all capacitors are combined and connected to the minus of the pltany source, another output of one winding the relay is connected through one of the resistors to the emitter of the transistor, the collector of which is connected through the other resistor and the bias winding to the positive power source and to the anode of one thyristor, whose cathode is connected to m the source of the power supply, and another electrode through the third resistor is connected to the connection point of another output of the magnetically controlled contact with the RC circuit resistor, another output of the other relay coil is connected to the anode of the other thyristor, the cathode of which is connected to the power supply minus, and the control electrode to the anode of the Zener diode, and to the cathode of one diode, the anode of which is connected to the base of the transistor and the fourth resistor is connected to the positive power source, the connection point of the specified other is the output of another relay winding to the cathode This other diode is connected to the cathode of another diode, the anode of which is connected to a source of pulsating voltage, and the cathode of the thyristor is connected to the circuit of the power source.

The drawbacks of such a device are the complication of the circuit and device design, associated with the presence in the circuit of a three-winding relay and additional elements for controlling the third winding, the complicated design and manufacturing technology of the device, due to the fact that the field windings and the different windings have different sizes. moreover, the bias winding inside of which the MK is placed is placed, in turn, on the outer surface of the excitation coil, as well as the reduced sensitivity of the device This is due to the fact that the possibility of approaching the MC to the exciting element in order to obtain maximum sensitivity is limited by the thickness of the bias winding inside which the MC is located.

The aim of the invention is to simplify the device.

The goal is achieved by the fact that in a device for controlling the operation of a trip switch containing a magnetically controlled contact, a bias winding, an excitation winding, power sources and a pulsating voltage, a moving exciter element, a control relay with two steady states, two thyristors, a transistor, a zener diode, an RC charging circuit, resistors, capacitors, diodes, a latch and a switch, the excitation winding being connected through a switch to the power supply, one of the magneto terminals the controlled contact is connected to the power supply plus, the Zener diode cathode is connected to the connection point of a resistor and an RC charging circuit capacitor, one of the terminals of each winding of a polarized relay is connected to one output of one of the capacitors, the other terminals of all capacitors are connected and connected to the source minus power supply, the other output of one relay winding is connected through one of the resistors to the emitter of the transistor, the collector of which through the other resis. the torus and the bias winding are connected to the power supply plus and to the anode of one thyristor, whose cathode is connected to the power supply minus, and the control electrode is connected via a third resistor to the connection point of the other output of the magnetically controlled contact with the RC circuit resistor, the other output is different the relay coil is connected to the anode of another thyristor, the cathode of which is connected to the minus of the power source, and the control electrode to the anode of the zener diode and to the cathode of a single diode, the anode of which is connected to the base of the transistor and black of the fourth resistor is connected to the positive power source, the other point of connection of said another output of said relay coil with the diode cathode is connected through a fifth resistor to the cathode of another diode, an anode of which is connected to a source of pulsating voltage, and a cathode retainer connected to the positive power source.

A double-winding relay was used as a polarized control relay, the anode of the dynistor is connected to the anode of the indicated other thyristor.

The drawing is a schematic diagram of the device.

The limit switch sensor is detached from the magnetically controlled contact 1, the bias winding 2, the excitation winding 3 and the moving exciter element (ferromagnetic iron or permanent magnet), not shown in the drawing, moving in a hermetic volume.

The schematic diagram of the device contains a magnetic control contact 1, windings 2 and 3 of the sensor, transistor 4, thyristor 5, double-winding field -. A relay 6 with direct 7 and a baffle 8 windings, capacitors 9, 10 and 11, resistors 12, 13, 14, 15, 1 and 17, thyristor 18, zener diode $ 1, diodes 20 and 21, dynistor 22, source 23 constant a current, a switch 24, and a pulsating voltage source 25.

The switch 24 serves to select the operation mode of the device. When the switch 24 is turned off, the device operates when a constant magnet is used as the driving element, and when the switch is turned on, the device operates when both the constant magnet and the ferromagnetic core are used as the driving element.

The device works as follows.

In the absence of an acting element at the control point (the location of the sensor windings), the magnetically controlled contact (MK) 1 is open and the windings 7 and 8 of relay 6 are de-energized. In this case, the excitation winding 3 creates a magnetic flux insufficient for closing the magnetically controlled contact. When the acting element is inserted into the trimming 3, the field increases and turns on MK 1, the positive potential of the source 23 goes through the resistor 13 to the control electrode of the thyristor 5, the latter turns on, the capacitor 10 discharges through the winding 7, and the thyristor 5 converts the relay 6 to an on state the At the same time through the open transistor 4 and the thyristor 5 begins to flow a current through the winding 2 bias, which creates a flow directed oppositely to the flow of the winding 3, and compensates for it so that MK 1 opens. Winding 7 of relay 6 is de-energized, and the relay signals the presence of a controlled body at the control point. When re-closing MK 1, when the acting element leaves the winding 3, the flow created by it decreases, the equality of the flows

violated, and under the action of the predominant flux generated by the winding 2 n & magnetization, MK 1 closes, which leads to the inclusion of the thyristor 18 and the discharge of the capacitor 9 through the winding 8, providing a power supply. transition relay b to ref. ya off state. In this case, the open thyristor 18, which shunts the base transition of the transistor 4, locks it, as a result of which the bias winding 2 is de-energized. Turning on the thyristor 18 occurs in the process of decreasing the amplitude of the pulsating voltage on the anode of the diode 20 to zero.

If at some point in time the circuit was in the on state (after a current pulse was applied through the winding 7) and the device was de-energized, the capacitor 9, charged before the voltage of the power supply 23, discharged along the circuit containing the winding 8 , dynistor 22 and winding 3, transfer of relay 6 to the initial off state.

Thus, when de-energized, the device operates as a normal neutral relay, but without long-term power consumption to keep the control relay in the on state, since the windings 7 and 8 of relay 6 are practically de-energized. At the same time, the device differs in its simplified design and structure. as compared to the known, a three-winding relay (a double-winding relay is used), a capacitor, a diode and a resistor are excluded. In addition, the design and manufacturing technology of the device's sensor is simplified because it is made in the form of a two-section Ts1u1indric multilayer coil, the sections of which perform the functions of excitation and bias windings, the MC is located on its outer surface, while in the known MC device it is located inside the coil undercarriage, which, in turn, is mounted on the outer surface of the excitation coil.

Claims (3)

1. USSR author's certificate No. 529502, class, H 01 H 36/00, 1973. i. USSR Author's Certificate 613416, cl. H 01 H 36/00, 1978 .. 3. USSR author's certificate in application 2551192 / 24-07, cl. H 01 H 36/00, 1978 (prototype). / xy r4