CS260417B1 - Connection of electromagnet especially of electromagnetic valve for control of gaseous or liquid mediums passage - Google Patents

Abstract

The solution relates to the connection of an electromagnet, in particular the solenoid valve, which controls the flow of gaseous or liquid media. Its arrangement brings a reduction consumption of the copper wire used on the coil winding, reduce electrical consumption energy and noise levels. His nature it is that the switch that is connected to one AC power terminal electricity is connected at one end the first coil winding connected with the second control winding coils, thyristor anodes and anode first diodes. The thyristor cathode is connected to the anode a second diode whose cathode is connected to the second AC power terminal energy. Between the cathode of the thyristors and the ancd the second diode is connected the second coil winding. Control electrode thyristors are then connected to one the condenser outlet to whose second outlet the first resistor connected is connected in series on the cathode of the first diode and in parallel to capacitor is connected to the second resistor. Engagement can be used with solenoids for steering Other activities of cooperating facilities especially for the needs of control technology to control the passage of media in the control device for example gaseous or liquid.

Description

The invention relates to the connection of an electromagnet, in particular to a solenoid valve for gaseous or liquid media

The electrical circuit of the solenoid valve must, in addition to other features, provide not only the necessary adequate force to overcome the working stroke of its moving core, but also the economic operating mode. This is that electricity consumption should not exceed the value necessary to function.

In most cases, the solenoid valves are controlled by alternating current winding, and are actuated by an electrical circuit connected by a mechanical contact. In these circuits, moving cores are generally used, forming part of the magnetic circuit, which is predominantly cup-shaped. To close the magnetic circuit, a relatively large initial magnetomotor force is provided by the arrangement of the electrical circuit. The cause of this state is the large working stroke of the movable core which controls the valve, which is due to the operation of the magnetic circuit. The electrical circuits when the valve is opened, i.e. in the order of milliseconds, require a relatively greater power input to overcome the initial stroke.

However, when the valve is opened, that is, in most cases, practically minutes and sometimes hours, the solenoid valve operates in an uneconomical mode, manifested by increased power consumption. In addition, the wiring of these solenoid valves operates with alternating current, which at. its function is caused by a relatively high noise level. .

These disadvantages are substantially eliminated by the wiring of the solenoid, in particular the solenoid valve, of the present invention, characterized in that one end of the first coil control winding connected to the switch is connected to the other end with the other coil control winding, thyristor anode and first diode anode. the thyristor cathode is connected to the anode of the second diode whose cathode is connected to the second terminal of the AC power source, while between the thyristor cathode and the anode of the second diode is connected the other end of the second coil control winding; a second resistor connected in series to a first resistor connected to the cathode of the first diode and a second resistor connected in parallel to the capacitor. A third resistor is used instead of the second coil winding.

The advantage of this connection lies mainly in material savings, which is up to 50% of the current consumption of copper wire used on the coil winding of the solenoid valve. In addition, it is possible for the second control winding to be made of lower quality materials. An essential advantage is the reduction of electric power consumption and noise during operation of the solenoid valve due to the rectified current connection.

An example of a solenoid valve connection is shown in the accompanying drawing in Fig. 1, Fig. 2 'showing an alternative embodiment thereof.

A switch 3 is connected to the AC power terminal Jf, the other end of which is connected to the first coil control winding. The other end of the first coil control winding 2 is connected to the second coil control winding 3, to the anode of the thyristor 4 and further to the anode of the first diode 5. The cathode of the thyristor 4 is connected to the anode of the second diode 6. energy. A second end of the second control winding 3 is connected between the cathode of the thyristor 4 and the anode of the second diode S. The control electrode of the thyristor 4 is connected to the capacitor 7. In series with the capacitor 7 is connected a first resistor 8 connected to the cathode of the first diode.

5. A second resistor 9 is connected in parallel to the capacitor 7.

In an alternative embodiment, a third resistor 11 is used instead of the second coil winding 3.

When the switch 1 is closed, the current flows through the first coil control winding 2 and the thyristor 4, which is opened by the charging current of the capacitor 7 and the current flowing through the first resistor B, the second resistor 9 and the first diode 5. despite the second coil control winding b given by the voltage drop across the thyristor T.

As soon as the negative half-wave of the sinusoidal AC voltage passes, the thyristor 4 is closed so that no nrond flows through the entire circuit, which is prevented by a second diode

6.

The positive half-wave takes charge of the capacitor 7, for example in this case for about 50-200 milliseconds, with the valve operating at full power. When the capacitor 7 is charged, current flows to the control electrode of the thyristor 4. Thus, the circuit is closed for a positive half-wave. In this case, the current passes through the first coil control winding 2, the second coil control winding 3 and the second diode 6. The valve thus operates in the economy mode.

When the switch 1 is opened, the power supply to the wiring is interrupted, thereby discharging the capacitor 7 via the second resistor 9. The wiring is then ready for the next operating cycle.

The circuit works similarly using the third resistor 11.

The invention can be used with electromagnets for controlling the further operation of cooperating devices, in particular for the needs of control technology to control the passage of media in the control device, for example gaseous or liquid.

Claims (1)

Connection of solenoids, in particular a solenoid valve for controlling the flow of gaseous or liquid media connected via a switch to one terminal of an AC power source, characterized in that one end of the first coil control winding (2) connected to the switch by the coil winding (3), the thyristor anode (4) and the anode of the first diode (5), the thyristor cathode (4) is connected to the anode of the second diode (6j), the cathode of which is connected to the second terminal the thyristor cathode (4) and the anode of the second diode (6j) are connected to the other end of the second coil control winding (3) or a third resistor (10) is used, the thyristor control electrode (4) being connected to one capacitor terminal (7) a second resistor connected in series to a first resistor (8) connected to a cathode of the first diode (5) and parallel to a capacitor (7J) a second resistor (9).