SU1100645A1 - Device for forging d.c. electromagnet - Google Patents

Abstract

DEVICE FOR FORCING THE DC ELECTROMAGNET, co-holding thyristor, dynistor, optocoupler thyristor, capacitor, zener diode, closing control contact, four diodes, three resistors, leads for connecting the electromagnet winding, leads for connecting a constant current source, and a terminal for connecting a source of an electromagnet, leads for connecting a DC source and a terminal for connecting a source of an electromagnet, leads for connecting a source of a constant current and a terminal for connecting a source of an electromagnet, terminals for connecting a DC source and a terminal for connecting a source of an electromagnet, leads for connecting a source of a constant current and a terminal for opening a source of an electromagnet, terminals for connecting a DC source and a terminal for opening a source of an electromagnet; with a grounded neutral, with the thyristor anode connected to a terminal for connecting the phase of a grounded neutral network and a series of series-connected first resistor, first diode, capacitor and output The optocoupler thyristor leads with a thyristor control electrode whose cathode is connected to one of the leads for connection. electromagnet windings and a serially connected second diode and a closing control contact with an output for connecting the positive pole of a DC source, an output for connecting the negative pole of which is connected to another output for connecting an electromagnet winding and grounded, and the third diode, the input terminals of the optronic thyristor and the second resistor is connected in series and the specified series circuit through the closing control contact is connected between the outputs for connecting the source DC current, characterized in that., in order to improve the device’s technological performance and reliability, the second and third optocoupler thyristors, the fourth and fifth resistors, are inserted into it (L anode of the dynistor is connected to the junction of the first resistor and anode of the first the diode, and the cathode of the dynistor through the output pins of the second OPTRONNO- (2 th thyristor is connected to the cathode of the thyristor; the third resistor and the output pins of the third optocoupler thyristor are connected in series and connected in parallel to the capacitor; the input pins to orogo photocouple SCR 05 included in the series circuit, w4: conductive hundred p1 of a third diode, thyristor optocoupler input terminals and a second resistor, a zener diode, a fourth. the resistor and the diode are connected in series and connected to the leads for connecting the electromagnet winding, the input pins of the third optocoupler thyristor and the fifth resistor are connected in series and connected in parallel to the fourth resistor.

Description

The invention relates to industrial automation and can be used in machine tool construction for driving hydraulic spools using DC electromagnets. A device for forcing a hydraulic distributor with a direct current electromagnet is known, containing a forcing thyristor with a capacitor and a resistor in its control electrode circuit. and the capacitor discharge circuit is connected to a disconnect by a relay contact, and the closing contact of the same relay is connected in series with the electromagnet, disconnecting only PICs direct current, but including also boosts a voltage and DC current T 3. This device has the following disadvantages: the resistor and the capacitor in the circuit of the control electrode of the thyristor are selected in accordance with the parameters of the thyristor, which makes it difficult to serially produce the device; the device requires a closing and opening relay contacts, and the relay contact used to control the device is under AC voltage, which eliminates the possibility of installing this relay in a cabinet in a common unit of low-voltage low-voltage control relays (as required by security); in addition, the possibility of replacing control contacts with transistors due to high voltage is excluded. It is also known a device for forming a direct current electromagnet comprising a boosting thyristor with a capacitor, a resistor, and an optocoupler thyristor in the control electrode circuit of the forcing thyristor pa. The capacitor discharge circuit is provided with series-connected dystrom and low-current thyristor, so the control electrode of the latter is included in cutting the circuit of the protective device elements from overvoltages at the moment of disconnecting the electromagnet from the direct current source C2J. This device has the following disadvantages: the resistor and the capacitor in the control electrode circuit of the forcing thyristor are selected in accordance with the parameters of this thyristor, which makes it difficult to mass-produce the device; capacitor discharge node elements are selected depending on the parameters of low-current thyristors with a very large scatter field. These two drawbacks increase the amount of work during the assembly of the device, which reduces one of the main indicators of the technological design. In addition, the criticality of the selected elements, depending on the parameters of the thyristors, reduces the reliability of the device when extreme operating conditions occur. For example, at the same time the maximum allowable heating and forcing voltage may not automatically turn off the forcing voltage, the forced electromagnet will overheat and be damaged. Or, if the DC voltage drops to the limit and a low-current thyristor is required to turn on a relatively large current pulse, the capacitor may not discharge, and as a result, no electromagnet force will occur in the next cycle of operation. The aim of the invention is to improve the manufacturability of the device and its reliability. The goal is achieved by the fact that a device for forming a direct current electromagnet containing a thyristor, a dynistor, an optocoupler thyristor, a capacitor, a zener diode, a control closing contact, four diodes, three resistors, leads for connecting an electromagnet winding, leads for connecting a direct current source and a terminal for connecting a phase of a network with a grounded neutral, the anode of the thyristor being connected to a terminal for connecting the phase of a network with a grounded neutral and through serially connected first resis a torus, a first diode, a capacitor, and output terminals of an optocoupler thyristor — with a control electrode of a thyristor, the cathode of which is connected to one of the leads for connecting the electromagnet winding and through a successively connected second diode and a closing control contact with a terminal for connecting the positive pole of the DC source, the output for connecting the negative pole of which is connected to another output for connecting the winding of the electromagnet and is grounded, the third diode, the input pins of the optocoupler thyristor and the second A resistor is connected in series, the indicated series circuit is connected between the terminals for connecting a DC source through the closing control contact, the fourth and fifth resistors are connected to the second and third optocoupler thyristors, and the diode anode is connected to the first diode anode and the cathode through the output pins of the second optocoupler HOFO thyristor is connected to the thyristor cathode, the third resistor and the output pins of the third optocoupler thyristor are connected in series and Keys parallel capacitor torus input terminals of the second optocoupler included v.posledovatelnuyu thyristor circuit consisting of the third diode, thyristor optocoupler input terminals and a second resistor, a zener diode and a fourth resistor connected in series and are connected to vyvodami.dl. the electromagnet winding connections, the third pins of the third optocoupler thyristor, and the fifth resistor are connected in series and connected in parallel to the fourth resistor. Shunting the control circuit of a forcing thyristor with a dynistor and inserting it with an optocoupler thyristor ensures the independence of the supply time of the increased voltage for switching on the thyristor from the variation of the parameters of the latter and the possibility of discarding the corresponding individual selection of the control circuit elements, which reduces the laboriousness of the assembly and increases the manufacturability of the design for mass production. . The connection of the circuit to protect the circuit from stresses through an optocoupler with a capacitor discharge circuit increases the reliability of the device and makes it possible to serialize it without adjusting and selecting the elements of the capacitor discharge unit, which also improves the manufacturability of the design. The drawing shows the electrical circuit of the proposed device. One output of the electro; agnita 1 is grounded, and the second is connected to the phase of the ac network with a grounded neutral through a force thyristor 2. The latter provides a short-term supply of a forcing voltage. The anode of the thyristor 2 is connected to the AC mains phase and through a resistor 3 is connected to the anode of diode 4, the cathode of which is connected to the anode of diode 4 and the cathode of distor 7 through the code generator 5 and the output of the thyristor optocoupler 6 through the output of the optocoupler thyristor 8 - with the cathode of thyristor 2. The input of the optocoupler thyristor 6 through the input of the optocoupler thyristor 8 and the current limiting resistor 9 is grounded, and through the diode 10 and through the control device, the closure contact 11 is connected to the positive pole of the source DC nick, the negative pole of which is grounded. In addition, the positive pole of the DC source through the closing contact 11, the diode 12 is connected directly to the ungrounded output of the electromagnet 1. And the grounded output of the electromagnet 1 through the protection circuit element circuit against overvoltages, consisting of a diode 13, a resistor 14, an optocoupler thyristor input 15 and the Zener diode 16 is connected to the non-grounded output of the electromagnet 1, and the cathodes of the diode 13 and the Zener diode 16 are connected to each other through a resistor 17, which together with the resistor 14 forms a current divider. The output of the optocoupler thyristor 15 through the current limiting resistor 18 forms, the discharge circuit of the capacitor 5. The device operates as follows. When the command to turn on the electromagnet 1, contact 11 is closed. Through diode 10, the input circuit of the optocoupler thyristor 6, the input circuit of the optocoupler thyristor 8 and the resistor 9 starts to flow DC current. The optocoupler thyristors 6 and 8 are turned on, and a charge circuit of condensate 5 is generated by the current rectified by a half-wave circuit through a resistor 3, a diode 4, an output circuit of the optocoupler thyristor 6, a control electrode of the thyristor 2 and an electromagnet 1. The thyristor 2 opens at each positive

half wave of phase voltage. A forcing, rectified half-wave voltage, is applied to the coil of electromagnet 1, and the electromagnet is triggered. The operation occurs without vibration, since in the intervals between the half-waves of the forcing voltage passing through the thyristor 2, the force of the return spring cannot push the electromagnet 1 back as a result of the electromagnet 1 entering the coil through the contact 11 and the direct current diode 12 from the constant source tension After the capacitor voltage reaches a value sufficient for the breakdown of the distor 7, the latter breaks through and shunts the thyristor 2 through the output of the optocoupler thyristor 8 during each subsequent half-wave voltage.

The force of electromagnet 1 is stopped and the electromagnet’s bark is held by the attracted direct current. The capacitor 5, due to the diode 4 and the optocoupler thyristor 15, remains charged. As a result of the subsequent positive half-voltage, the thyristor 2 remains closed.

After disconnecting the contact 11, the optocoupler thyristor 8 breaks the circuit of the current entering the electromagnet 1 through the diistor 7.

During the opening of the contact 11, which disconnects the electromagnet 1 from the DC source, the electromotive force of the electromagnet induces a current in the diode 13, the resistor 17 and the zener diode 16, part of which branches through the resistor 14 to the input circuit of the optocoupler thyristor 15 The optocoupler thyristor 15 turns on and the capacitor 5 is discharged, preparing to re-operate after a new closure of the contact 11.

The advantage of the known device is the use of overvoltage protection elements of the device for simultaneous discharge

the capacitance that controls the operation of the operation of the electromagnetJ and the inclusion of an optocoupler thyristor in the control elerod circuit, which makes it possible to eliminate the contacts of the relay from the circuit of the increased forcing voltage.

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as a result, the installation and maintenance of electrical equipment of aggregate machines and automatic lines, as well as. these relays can be placed in low-current relays, where the presence of voltages above 110 V is not allowed.

In the proposed device, the connection of the dynistor 7 and the optocoupler thyristor 8, shunting the diode 4, the capacitor 5, the output of the optocoupler thyristor and the control electrode of the thyristor 2 ensure independence of the time delay (determining the time for forcing the electromagnet 1) from the variation of the thyristor 2 parameters. individual selection of the nominal values of the resistor 3 and the capacitor 5 in accordance with the parameters of the thyristor 2 during mass production of the proposed device. In the device, a resistor 3 can be selected for a margin with a known lower resistance, and a capacitor 5 with a larger capacity so that their values are suitable for switching on any thyristor of the selected type. The moment of disconnection of the thyristor 2 does not depend on its input data. As a result, the manufacturability and reliability of the device is significantly improved. Such an increase is also provided by transmitting a pulse from the protection circuit of the circuit against overvoltages to the capacitor discharge circuit with the help of an optocoupler thyristor 15. Thus, the spread field of the parameters of three semiconductor devices (low current thyristor and two dynistors) in the discharge circuit of a known device is replaced by a spread field one optocoupler thyristor 15 in the proposed device.

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Claims (1)

DEVICE FOR FORCING A DC ELECTROMAGNET, containing a thyristor, a dynistor, an optocoupler thyristor, a capacitor, a zener diode, a closing control contact, four diodes, three resistors, terminals for connecting an electromagnet winding, terminals for connecting a DC source and a terminal for connecting a network phase with grounded neutral, and the thyristor anode is connected to the terminal for connecting the network phase to a grounded neutral and through a series-connected first resistor, first diode, capacitor and output ode photocouple SCR - with a control electrode of the thyristor, the cathode of which is connected to one of the terminals for the connection. electromagnet windings and through a second diode and a control terminal connected in series with a terminal for connecting the positive pole of a direct current source, the terminal for connecting a negative pole of which is connected to another terminal for connecting an electromagnet winding and is grounded, the third diode, the input terminals of the optocoupler thyristor and the second the resistor is connected in series and the specified serial circuit through the make control contact is connected between the terminals to connect the source current, characterized in that., in order to improve the manufacturability of the device and its reliability, the second and third optocoupler thyristors, the fourth and fifth resistors are introduced into it, the anode of the dinistor connected to the connection point of the first resistor and the anode of the first diode, and the cathode of the dinistor through the output terminals of the second optocoupler thyristor are connected, with the cathode of the thyristor, the third resistor and the output terminals of the third optocoupler thyristor are connected in series and connected in parallel to the capacitor, the input terminals of the second optocoupler the aristors are included in a serial circuit consisting of a third diode, the input terminals of the optocoupler thyristor and a second resistor, a zener diode, a fourth, a resistor and a diode are connected in series and connected to the terminals for connecting an electromagnet winding, the input terminals of the third optocoupler thyristor and a fifth resistor are connected in series and connected parallel to the fourth resistor.