RU2699373C1 - Method for regeneration of electric precipitator electrodes and device for its implementation - Google Patents

Abstract

FIELD: technological processes.

SUBSTANCE: invention relates to electric precipitator electrodes regeneration method consisting in periodic regeneration of electrodes. Method is characterized by the fact that period of time is measured from completion of regeneration of corona-forming electrodes prior to start of reduction of current of corona or increase of voltage at switched off regeneration of corona-forming electrodes of investigated field of electric precipitator, electric precipitator, calculating specific electrical resistance of dust in analyzed field of electric precipitator, calculating interval of regeneration of precipitating electrodes and setting interval of regeneration of precipitating electrodes of investigated field of electric precipitator as follows: VR for first ESP field is calculated by the following formula: ρ_v1f=10^5.9+kQτce1f/Lc1f, (1) further calculating and setting for the first field the period of regeneration of the precipitating electrodes of the ESP with allowance for dust resistivity by the following formula: τ_pe1f=30τ_ce1f(3.14-0.25lgρ_v1f)/(13lgρ_v1f-77), (2) designations in formulas (1) and (2) are as follows: τ_ce1f is the measured period of time between the end of regeneration of the corona-forming electrodes and the moment of decreasing corona current or increasing the voltage at the corona-forming electrodes of the first field; ρ_v1f is the dust volume resistivity at the first field; k is coefficient depending on ESP type; Q is gas flow rate at first field; η_1f is degree of gas cleaning by first field of ESP; τ_ce1f – regeneration interval of corona-forming electrodes of the first field; τ_pe1f is a regeneration interval of precipitation electrodes of the first field; L_c1f is the length of the corona-forming electrodes of the first field, and then the above operations are repeated for all fields of the ESP using a software device. Invention also relates to the device.

EFFECT: use of disclosed invention increases degree of purification of gases.

2 cl, 1 dwg

Description

The invention relates to the electrical cleaning of gases from dust of non-aggressive gases in the power system, non-ferrous and ferrous metallurgy, chemical and other industries.

Known methods for the regeneration of electrodes of an electrostatic precipitator, consisting in the calculation of the regeneration modes of precipitation and corona electrodes of an electrostatic precipitator based on the design and technological parameters of the electrostatic precipitator. The implementation of these modes of modes is carried out using a time relay, software devices, for example, E1ex-24 controllers having a rigid cyclic control program. Also used are ACS devices of the type KEP, PURF, MIURF, SAIL, AUR, ARV, control systems SU-12, SU-24 and their modifications, which also have a rigid cyclic program.

The disadvantages of the known methods of regenerating electrostatic electrodes include the fact that the regeneration modes of electrostatic electrodes are set by analogy with other electrostatic precipitators - analogues, or are calculated when setting up electrostatic precipitators manually. In this case, there is no possibility of constant automatic accounting of the changing technological parameters of the operation of the electrostatic precipitator and dust and gas flow. As a result, the degree of gas purification is reduced.

A known method for automatically controlling the process of regeneration of precipitation electrodes of an n-section electrostatic precipitator of an open-hearth furnace (see AC 1510930 SU Pikulik N.V. et al. 1987), according to which the regeneration of electrodes is carried out automatically in accordance with the technological mode of operation of the furnace. The disadvantage is the use of a differential pressure gauge, a device that is additionally installed in the technological equipment circuit and the creation of a special communication circuit between the open-hearth furnace and the electrostatic precipitator. In addition, the time-varying parameters of the dust and gas flow and the properties of the captured dust are not taken into account.

The technical task of the invention and the technical result achieved by solving it is to increase the degree of gas purification by an electrostatic precipitator due to the time-constant monitoring of the operation mode of each field of the electrostatic precipitator and the subsequent automatic setting of regeneration modes of corona and precipitation electrodes corresponding to the actual technological regime of operation of each electrostatic precipitator field.

The specified technical result is achieved in that the electrostatic precipitator first measures the period of time from the moment the regeneration of the corona electrodes ends, until the beginning of the decrease in the corona current, or until the voltage on the corona electrode begins to increase when the mechanism of shaking the corona electrodes in the studied field of the electrostatic precipitator is switched off. Based on the magnitude of this period, the period τ _{ke1p of} shaking of the corona electrodes of the studied field of the electrostatic precipitator is calculated. Next, the specific electrical resistance of dust in the investigated field of the electrostatic precipitator and the time interval of shaking the precipitation electrodes of the studied field of the electrostatic precipitator are calculated. Then, using the program unit, the regeneration interval of the precipitation electrodes of each studied field of the electrostatic precipitator is automatically set. This sequence of operations is carried out continuously for each field of the electrostatic precipitator.

The implementation of the proposed method for the regeneration of electrodes of an electrostatic precipitator is carried out in an ACS device by the mechanisms of regeneration of corona and precipitation electrodes of an electrostatic precipitator as follows. In FIG. 1 shows a block diagram of a device for implementing the method.

The list of positions in the drawing:

1 - Electrofilter;

2 - Power supply unit of the corona electrodes with high voltage;

3 - The mechanism of regeneration of precipitation electrodes;

4 - The mechanism of regeneration of the corona electrodes;

5 - Unit for measuring the period of time between the end of regeneration and a decrease in the corona current or an increase in voltage at the corona electrodes;

6 - Block calculating the regeneration period of the corona electrodes;

7 - Unit for calculating the electrical resistivity of dust;

8 - Block calculating the regeneration period of the precipitation electrodes.

The electrostatic precipitator “1” is connected to the power supply unit “2”, which supplies high voltage to the corona electrodes and has the function of instantaneous recording of current and voltage at the corona electrodes. The regeneration of the precipitation electrodes is carried out using the mechanism "3", the regeneration of the corona electrodes - mechanism "4". The unit for measuring the time period τ _{ke1p is} connected and receives a signal from the mechanism “4” for the regeneration of the corona electrodes. The measurement unit "5" is fed from the power supply unit "2" the values of the current and voltage on the corona electrodes. The unit for calculating the “6” period of the regeneration time of the corona electrodes supplies a control signal to the block “4” of the regeneration of the corona electrodes and simultaneously

to block "7" calculation of dust resistivity. Block “8” for calculating the regeneration period is connected to block “7” and provides a control signal to the mechanism “3” for regeneration of the precipitation electrodes.

Device ACS regeneration of electrodes of the electrostatic precipitator operates as follows.

Based on the signal from the “4” mechanism about the end of the regeneration of the corona electrodes and the signal from the current or voltage block “2”, the “5” block measures the time period of the first and subsequent fields: τ _ke1p , τ _ke2p , τ _ke3p , etc. The intervals for the regeneration of the corona electrodes in block “6” are set by the program in accordance with a certain period of time from the end of the regeneration of the corona electrodes to the beginning of a decrease in the corona current or an increase in voltage when the shaking of the corona electrodes is switched off on each field of the electrostatic precipitator.

In block "7" calculate the resistivity for the first field of the electrostatic precipitator according to the following formula:

In block "8" calculate and set for the first field the regeneration period of the precipitation electrodes of the electrostatic precipitator taking into account the dust resistivity according to the following formula:

The designations in formulas (1) and (2) are as follows:

τ _ke1p - the measured period of time between the moment the regeneration of the corona electrodes ends and the moment the corona current decreases or the voltage across the corona electrodes of the first field increases;

ρ _v1п - resistivity of dust in the first field;

k is a coefficient depending on the type of electrostatic precipitator;

Q is the gas flow in the first field;

η _1p - the degree of gas purification by the first field of the electrostatic precipitator;

τ _ke1p is the regeneration interval of the corona electrodes of the first field;

τ _oe1p is the regeneration interval of the precipitation electrodes of the first field;

L _k1n - the length of the corona electrodes of the first field.

From block "8" a control signal is supplied to the mechanism "3" of regeneration of the precipitating electrode of the electrostatic precipitator.

Then, in the same way, the necessary parameters for the second field and subsequent fields of the electrostatic precipitator are calculated and set by the program.

The periods of regeneration of the corona electrodes of the EF fields (τ _ke1p , τ _ke2p , τ _ke3p , etc.) are _measured periodically depending on the operating mode of the process

installation. They are set manually by the program and can be, for example, on the TPP electrostatic precipitators a period of 1 ... 2 hours, on electrostatic precipitators with a frequently changing operating mode - 5 ... 10 minutes.

In addition, in special cases of the implementation of this invention, the obtained data on the value of the electrical resistivity of the dust of the fields of the electrostatic precipitator is used to adjust the operating mode of the power supply units of the electrostatic precipitator fields with a high voltage.

Also, based on the data obtained, it is possible to calculate the coefficient K _inter - the ratio of the intervals of regeneration of the corona or precipitation electrodes of a particular electrostatic precipitator. Since they are equal to each other, by the ratio of these intervals it is possible to obtain information about the degree of gas purification in each field of the electrostatic precipitator.

The advantages of the invention lie in the achievement of continuous automatic tracking and changing of the regeneration regimes and of the corona and, together, precipitation electrodes. This allows you to ensure the work of EF gas purification with increased efficiency.

These features are significant and interconnected with the formation of a stable set of essential features sufficient to obtain the desired technical result.

The specified technical result is achieved by the fact that an automatic control system for regeneration modes of the electrostatic precipitator is proposed, combined with the automatic process control system of the electrostatic precipitator.

The present invention is industrially applicable, since its implementation does not require special accessories, sensors and new

Claims (14)

1. The method of regeneration of electrodes of the electrostatic precipitator, consisting in periodic regeneration of electrodes, characterized in that they measure the period of time from the end of the regeneration of the corona electrodes to the beginning of the reduction of the corona current or increase the voltage when the regeneration of the corona electrodes of the studied field of the electrostatic precipitator is switched off, the specific electrical resistance of dust in the studied field is calculated electrostatic precipitator, calculate the regeneration interval of the precipitation electrodes and set the regeneration interval to precipitate of natural electrodes of the studied field of the electrostatic precipitator as follows: the resistivity is calculated for the first field of the EF according to the following formula:

then, the regeneration period of the electrophoresis electrodes EF is calculated and set for the first field, taking into account dust resistivity according to the following formula:

the notation in formulas (1) and (2) is as follows: τ _ke1p is the measured time period between the moment of completion of the regeneration of the corona electrodes and the moment of decrease in the corona current or increase in voltage on the corona electrodes of the first field; ρ _v1п - electrical resistivity of dust in the first field; k is a coefficient depending on the type of EF; Q is the gas flow in the first field; η _1p - the degree of gas purification by the first field EF; τ _ke1p is the regeneration interval of the corona electrodes of the first field; τ _oe1p is the regeneration interval of the precipitation electrodes of the first field; L _k1n - the length of the corona electrodes of the first field, and then repeat the above operations for all fields of the EF using a software device. 2. A device for implementing the method according to claim 1, comprising a measurement unit, a period calculation unit, a specific electrical dust resistance calculation unit, a precipitation electrode regeneration period calculation unit, a precipitation electrode regeneration mechanism, a corona electrode regeneration mechanism, and a high voltage corona electrode power supply unit characterized in that the output from the regeneration mechanism of the corona electrodes is connected to the first input of the measurement unit, and is connected to the second input of the measurement unit current output from the power supply unit, the voltage output from the power supply unit is connected to the third input of the measurement unit, the output from the measurement unit is connected to the input of the period calculation unit, the first output of which is connected to the input of the corona electrode regeneration mechanism, and the second output is connected to the input of the unit calculation of the electrical resistivity, the output of which is connected to the input of the unit for calculating the period of regeneration of the precipitation electrodes, the output of which is connected to the input of the regeneration mechanism of the precipitation electrodes filter filter.

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