SU608552A1 - Apparatus for electric static deposition of high-resistance dust - Google Patents

Description

one

The invention relates to the field of electrical engineering, in particular, to high-voltage power supplies for electrical equipment of electron-ion technology and can be used, for example, for electrogas cleaning and dust removal of high-resistance dusts.

A device for electrostatic deposition of high-resistive dusts is known, which contains a transformer, the secondary winding of which is shunted by a chain of two oppositely connected diodes, damping elements, a system of precipitation and corona electrodes, the first of which are connected to a common point of connection of these diodes, and the second are connected through damping elements transformer secondary windings and controlled valve switches.

A disadvantage of the known device is the low efficiency of dust cleaning with a relatively large amount of electricity consumed.

The aim of the invention is to increase the cleaning efficiency and efficiency of the device. This goal is achieved by introducing circuit interconnections in which the collecting electrodes are connected through a controlled valve in the opposite direction to the common connection point of the shunt diode diodes and between the terminals of the secondary winding

The transformer and the corresponding damping elements of each electrostatic precipitator include anti-thyristor switches connected in parallel to each other.

FIG. 1 shows the electrical circuit of the device for electrostatic deposition of high-resistive dusts; in fig. 2 - equivalent device replacement circuit (the number of connected electrostatic precipitators is two), where 1 is the secondary winding of the transformer; 2, 3 - shunt circuit diodes; 4 - controlled valve; 5, 6 - the first and second electrostatic precipitators; 7, 8 — corona electrodes of electrostatic precipitators 5 and 6, respectively; 9, 10 - collecting electrodes of filters 5, 6, respectively; And, 12 - diode-thyristor switches of electrostatic precipitators 5 and 6, respectively; 13, 14 - damping elements; 15 — control unit; 16 - current limiting element; 17 - regulatory element; 18, 19 - equivalent capacity of filters 5, 6, respectively; 20, 21 are replacement resistors of electrostatic precipitators 5 and 6, respectively.

The number of electrostatic precipitators connected to the device can generally be arbitrary, as reflected in FIG. 1 dotted lines, but not less than two. The number of electrostatic precipitators affects only the efficiency of the device as a whole and does not affect the principle of its operation.

Consider the operation of the device when the number of connected electrostatic precipitators is two.

In the initial state, the And and 12 keys are open, and the control valve 4 is opened with a signal from the control unit 15. During the corresponding half-period of the supply voltage, the thyristor of the key 11 opens with a signal from the control unit and the capacitance 18 of the electrostatic filter 5 is charged (Fig. 2) over the circuit: secondary winding 1 of the transformer, diode 2, controlled valve 4, electrodes 9 and 7 of the electrostatic precipitator 5, damping element 13, key thyristor I.

The charge of the capacitance occurs up to the maximum voltage, after which the diode 2 and the key I lock up and the capacitance 18 begins to slowly discharge to the resistor 20.

In the next half-period, the voltage of the secondary winding 1 of the transformer is turned on according to the voltage of the capacitor 18 of the electrostatic precipitator 5 and applied to the key 12.

After the key 12 is opened by applying a pulse from the control unit 15 and the thyristor of this key, the voltage on the electrostatic precipitator 6 rapidly increases due to the discharge of the capacitance 18 of the electrostatic precipitator 6 along the circuit: the damping element 14, the thyristor of the key 12, the key diode I, and the damping element 13.

By the time the tank 18 is discharged to the capacitor 19, the voltage on the secondary winding 1 retains its direction, and the capacitor 18 is recharged to a voltage at which the diode 3 and the controlled valve 4 are opened, while the reverse field is applied to the electrostatic filter 5 of the capacitance 19 of the electrostatic precipitator 6 through the diode 3, controlled valve 4, electrodes 10, 8, key thyristor 12, secondary winding 1 to the maximum value, and then follows a slow discharge on the resistor 21.

In the next half-period, the voltage of the secondary winding 1 of the transformer is already switched on in accordance with the voltage on the capacitance 19 of the electrostatic precipitator 6 and applied to the key P.

After the opening of the thyristor key 11, a rapid increase in the voltage on the capacitance 18 of the electrostatic precipitator 5 occurs due to the discharge of capacitance 19 along the circuit: capacitance 19, capacitance 18, damping element 13, thyristor of key 11, secondary winding 1, diode of key 12, damping element 14.

By the time the discharge of the capacitance 19 is completed on the capacitance 18 of the electrostatic precipitator 5, the voltage on the secondary winding 1 retains its direction, the capacitance 19 is recharged to the voltage at which the diode 2 is opened and the control valve 4 is applied, while the electrostatic precipitator 6 is applied the reverse polarity voltage and at the same time the charge of the capacitor 18 of the electrostatic filter 5 continues through diode 2, control valve 4, electrode 7, 9, key thyristor I, secondary winding 1 to the maximum value, and then slow discharge to resistor 20 follows.

Then, the described process is periodically repeated. A pulsed rectified voltage with a covered front of the wave is applied to the electrostatic precipitator.

The magnitude of the reverse polarity impulse may vary depending on the nature of the collected dust by changing the time of unlocking the controlled valve 4.

In the event of failure of one of the electrostatic precipitators to ensure the power supply mode described above, the remaining electrostatic precipitator can be replaced by an equivalent capacitor connected between the ground and the high-frequency throttle output.

According to the proposed principle, both single-phase and multi-phase systems can be built.

The advantage of the device is that due to the high rate of increase of voltage on the electrostatic precipitator, the process of charging and deposition of particles in the corona field is intensified, and several pairs of electrostatic filters from one transformer are powered. At the same time, there is a periodic discharge of the capacity of some electrostatic precipitators on the capacity of other electrostatic precipitators, which ensures a significant pulsation of the rectified voltage on each electrostatic precipitator, contributes to the discharge of the deposited high-resistive dust and prevents the formation of reverse corona, reduces power consumption and installed electrical equipment capacity, t This means that the cleaning efficiency and efficiency of the device is higher.

Claims (1)

Invention Formula A device for electrostatic deposition of high-resistance dusts, containing a transformer, the secondary I winding of which is shunted by a chain of two oppositely connected diodes, and at least two pairs of collecting and corona electrodes, the first of which are connected to the common connection point of these diodes, and the second through damping elements associated with the corresponding point of connection of the same diodes and conclusions of the secondary winding, characterized in that, in order to increase its efficiency, the collecting electrodes of the connection They are connected to the common point of connection of the diodes through a controlled valve connected in the opposite direction, and between the terminals of the secondary winding and the points of connection of the damping elements with the diodes are connected counter-parallel-connected diode-thyristor switches. fuz.l