RU2658186C1 - Unburned fuel products ignition in the electrostatic precipitator prevention method - Google Patents

Abstract

FIELD: electrical engineering.

SUBSTANCE: invention relates to methods for preventing fires in electrostatic precipitators from a spark during the interelectrode gap electrical breakdown and can be used in power engineering and other industries. At the time of increased unburned fuel products ingress into the electrostatic precipitator, disconnected the high voltage supply to the electrodes is and disconnecting the electrodes cleaning mechanisms. After termination of such increased ingress, the high voltage is first applied to the electrostatic precipitator last field, simultaneously switching on the corona electrodes in this field cleaning mechanisms, raising it to the initial corona discharge voltage in this field and further to the anti-ignition voltage for this field, after the establishment of which switching on the precipitating electrodes in this field cleaning mechanisms. Then, with the predetermined time interval high voltage is sequentially applied to the electrostatic precipitator each previous field with the same sequence. Anti-ignition voltage, duration of its supply and the interval between the precipitation electrodes cleaning with its supply, are set individually for each field. After the anti-ignition voltage supply completion, setting the high voltage and the time interval between the precipitating electrodes cleaning individually in each of the fields.

EFFECT: preventing the unburned fuel products ignition in the electrostatic precipitator.

3 cl

Description

The invention relates to methods for preventing fires in electrostatic precipitators when cleaning gases containing products of unburned fuel in them, which are removed from process equipment during which they can be removed more and which are prone to ignition from a spark during electrical breakdown of the electrode gap in electrostatic precipitators, and can be used in energy and other industries.

The closest in technical essence to the invention is a method of controlling the operation of an electrostatic precipitator installed behind technological equipment, during the operation of which fuel is burned in it with periods of increased removal of unburned fuel products that are prone to ignition from a spark during electrical breakdown of the electrode gap in an electrostatic precipitator (Russian patent No. 2478435, IPC V03C3 / 68, B01D 46/46, publ. 10.04.13, bull. No. 10). Such a method includes controlling the supply of high voltage to the systems of the corona electrodes (supply of the standard high voltage that is supplied to the systems of the corona electrodes during normal operation) and controlling the cleaning mechanisms of the systems of corona electrodes and precipitation electrode systems (regular time intervals between cleaning the electrode systems) of the electrostatic precipitator. The method is used for gases that are removed from the energy boiler, into which coal and combustion air are supplied.

The invention and the method closest to it in technical essence coincide with the following essential features. Both methods include controlling the supply of high voltage to the systems of corona electrodes (supply of the standard high voltage that is supplied to the systems of corona electrodes during normal operation) and control of the cleaning mechanisms of the systems of corona electrodes and systems of precipitation electrodes (regular time intervals between cleaning the electrode systems) of the electrostatic precipitator, installed behind technological equipment, during the operation of which fuel is burned in it with periods of increased removal of products of unburned fuel, predisposed to ignition from a spark during electrical breakdown of the interelectrode gap in the electrostatic precipitator.

The analysis of the technical properties of the method closest to the invention, due to its features, shows that the following reasons hinder the obtaining of the expected technical result when using this method. In this method, there is no control mode of the electrostatic precipitator for gases that are discharged from the process equipment when increased removal of unburned fuel products that are prone to ignition from a spark during electric breakdown of the interelectrode gap in the electrostatic precipitator occurs from it. As you know, during the operation of such technological equipment, there are periods when auxiliary fuel is additionally supplied to it at the initial stage for ignition or to intensify the combustion process, for example, when the power boiler is in normal operation on fossil fuels, fuel oil can be supplied as auxiliary fuel. As a result of fuel underburning, gases with a high content of combustible products of combustion (underburning) of fuel (soot, oil and / or tar-like combustible substances) that are prone to ignition enter the electrostatic precipitator. If these products of unburned fuel get into the electrostatic precipitator and in the state of the electrostatic precipitator control mode, they can ignite, which, in turn, will lead to a fire inside the electrostatic precipitator, damage to the internal equipment and failure of the electrostatic precipitator as a whole.

The basis of the invention is the task of creating such a method of preventing ignition of unburned fuel products in an electrostatic precipitator, in which improvements by introducing new actions and modes of their implementation will allow using the invention to achieve a technical result consisting in preventing ignition of unburned fuel products in an electrostatic precipitator.

The method includes controlling the supply of high voltage to the systems of the corona electrodes and controlling the cleaning mechanisms of the systems of the corona electrodes and the systems of the precipitation electrodes of the electrostatic precipitator installed behind the process equipment, during which it burns fuel with periods of increased removal of unburned fuel products that are prone to spark ignition with electrical breakdown of the interelectrode gap in the electrostatic precipitator.

A feature of the invention is the following. During the operation of the technological equipment, when there is an increased removal of unburned fuel products that are prone to ignition from a spark during electrical breakdown of the interelectrode gap in the electrostatic precipitator installed behind the technological equipment, the high voltage supply (standard high voltage that is supplied to the corona electrode systems at normal operation of technological equipment) simultaneously on the system of corona electrodes of all electric fields electrostatic precipitator and shut off the cleaning mechanisms of the systems of precipitation electrodes and systems of corona electrodes from trapped dust at the same time in all electric fields of the electrostatic precipitator (regular time intervals between cleaning the electrode systems). After the termination of the increased removal of unburned fuel products, a high voltage is applied first to the last field of the electrostatic precipitator, while simultaneously turning on the cleaning mechanisms of the corona electrode system in this field, raise it to the initial corona discharge voltage in this field and then to the anti-ignition voltage for this field, after which cleaning mechanisms of the precipitation electrode system in this field. Then, a high voltage with a time interval that corresponds to the regular time interval between the cleaning of the first field precipitation electrode system with the standard high voltage in this field is applied sequentially to each previous field of the electrostatic precipitator, simultaneously including the cleaning mechanisms of the corona electrode system in this field, raise it to the initial the voltage of the corona discharge in this field and further to the anti-ignition voltage for this field, after the establishment of which the cleaning mechanisms are activated Istemi collecting electrodes in this field. In this case, the anti-ignition voltage for each field is set individually, based on the conditions:

l, 5U _0k ≤U _avk ≤0.8U _pk ,

where U _0k is the initial voltage of the corona discharge in the k-th field, kV,

U _avk ^_ anti- _ignition voltage in the k-th field, kV,

U _pk ^{_ the} voltage of the spark breakdown of the interelectrode gap in the k-th field, kV, k = 1, ..., n,

n is the number of fields in the electrostatic precipitator.

The total time interval for supplying an anti-ignition voltage to each field and the time interval between cleaning the precipitation electrode system in each field with an anti-ignition voltage in this field is set individually, based on the conditions:

2.0t _ABK ≤T _ABK ≤ _{3.0T ABK}

1.5 _pcs ≤t _avk ≤3.0t _pcs

where T _avk is the total time interval for the supply of anti- _ignition voltage to the k-th field, min,

t_abk - the time interval between cleaning the precipitation electrode system in the k-th field with anti-ignition voltage in this field, min,

t _pc - regular time interval between cleaning the precipitation electrode system in the k-th field at a standard high voltage in this field, min.

After the expiration of the total time interval for the supply of anti-igniter voltage to each field in each field, individually set the nominal high voltage and regular interval of time between cleaning the precipitation electrode system in this field.

In certain cases, the invention may be characterized in that:

- in the electrostatic precipitator installed behind the process equipment operating in start-up conditions with increased removal of unburned fuel products, predisposed to ignition from a spark during electric breakdown of the interelectrode gap in the electrostatic precipitator, before the planned shutdown of the technological equipment and subsequent decommissioning of the electrostatic precipitator as a whole, sequential shutdown of mechanisms of cleaning the systems of precipitation electrodes from trapped dust in all electric fields of the electrostatic precipitator, start from the last field, while the interval between the shutdown time of the cleaning mechanisms of the precipitation electrode system for each field and the shutdown time of the process equipment is individually set from 0.95 to 0.99 of the regular time interval between cleaning the precipitation electrode system at a nominal high voltage in this field;

- in cases of emergency shutdown of technological equipment with subsequent decommissioning of the electrostatic precipitator as a whole, the cleaning mechanisms of the precipitation electrode systems are simultaneously turned off simultaneously in all fields of the electrostatic precipitator, and then after a time interval that corresponds to the standard time interval between cleaning the precipitation electrode system of the first field at regular high voltage in this field, in series, starting from the first field, disconnect the high voltage on all fields of the electrostatic precipitator, except for the last field, p In this case, the high voltage in the last field is turned off immediately after the final shutdown of the technological equipment.

When using the invention, a technical result is achieved, consisting in the maximum possible prevention of the deposition of combustible products of unburned fuel on the cleaned surface of the precipitation electrode electrostatic precipitator systems. And in the case when such deposition does occur, when an anti-ignition voltage is applied to the corona electrode systems, a layer of combustible products of unburned fuel, prone to ignition, is coated with a layer of non-combustible dust, which prevents ignition of the layer of combustible products. The subsequent removal of the combustible layer with a layer of non-combustible dust is ensured when cleaning the precipitation electrode systems. It also provides coverage of the remnants of a layer of combustible products of unburned fuel, prone to ignition, with a new layer of non-combustible dust, and the subsequent removal of residual combustible layer with a layer of non-combustible dust when cleaning the precipitation electrode systems. According to the invention, the repeatability and duration of the deposition and cleaning cycles, contributing both to an intensive decrease in the density of the layer of combustible products and to a decrease in the size of the surface of the precipitation electrode systems “affected” by this layer, prevents the ignition and intense burning (fire) of unburned fuel products in the electrostatic precipitator, which, due to the prevention of temperature deformation, it prevents the failure of the systems of corona and precipitation electrodes of the electrostatic precipitator, supporting insulator Suspension of the systems of corona electrodes and other equipment of the electrostatic precipitator, as well as elements of the electrostatic precipitator housing. This minimizes the operating time of the electrostatic precipitator with reduced efficiency.

In addition, the implementation of the invention ensures the achievement of an additional technical result, namely, that the prevention of ignition of unburned fuel products in the electrostatic precipitator is ensured solely by setting new high voltage supply modes and new cleaning modes of the corona and precipitation electrode systems when adjusting the size and time interval of the feed high voltage, as well as when adjusting the time interval for cleaning the precipitation electrode systems b alteration of the electrostatic precipitator and the use of additional equipment, which, in turn, simplifies and reduces the cost of implementation of the invention.

Between the totality of the essential features of the invention and the achieved technical result, there is the following causal relationship.

Turning off the supply of high voltage (standard high voltage, which is supplied to the corona electrode systems during normal operation of the process equipment) simultaneously to the corona electrode systems of all electric fields of the electrostatic precipitator for the duration of the operation of the process equipment, when increased removal of unburned fuel products prone to ignition occurs from it from a spark during electrical breakdown of the interelectrode gap in the electrostatic precipitator, allows to simultaneously bring h the operation of the electrode system (corona and precipitation) of all fields of the electrostatic precipitator and to prevent as much as possible the intensive settling of these combustible products (soot, oil and / or tar-like combustible substances, etc.) on them, as well as to prevent their ignition during spark breakdown, due to the absence of high voltage.

Disabling at the same time the cleaning mechanisms of the precipitation electrode systems and the systems of corona electrodes from dust collected simultaneously in all electric fields of the electrostatic precipitator (regular time intervals between cleaning the electrode systems) allows you to simultaneously remove the cleaning mechanisms of all electrode systems and keep the previously collected non-combustible layer on the latter dust, preventing the settling of combustible products on the cleaned surfaces of the electrode systems. In this case, combustible products are deposited on a layer of non-combustible dust with the subsequent removal of both layers in the mode of activated electrode cleaning mechanisms, which, accordingly, excludes further ignition in the electrostatic precipitator due to the absence of a burning object. In addition, due to such a shutdown, the possibility of ignition from a spark, which may occur during the operation of cleaning mechanisms of electrode systems (when hammers strike with anvils), is excluded.

The supply, after the termination of the increased removal of products of unburned fuel, of high voltage, first to the last field of the electrostatic precipitator with the simultaneous inclusion of cleaning mechanisms of the system of corona electrodes in this field, and then sequentially to each previous one, with the same simultaneous inclusion of cleaning mechanisms of the system of corona electrodes for each field, allows you to gradually enter the fields of the electrostatic precipitator into operation, starting from the last field with the lowest content of combustible products on the electrode systems, to first field with the highest content of combustible products on electrode systems.

The time delay between the beginning of the supply of high voltage from each subsequent field to each previous field, which corresponds to the regular time interval between cleaning the precipitation electrode system of the first field at regular high voltage in this field, allows you to organize the work of the disconnected fields of the electrostatic precipitator, starting from the first field, which are characterized the greatest contamination of the electrode systems by a layer of combustible particles, under conditions of the highest concentration of non-combustible particles in the gas stream for a given time nor, which is calculated (provided the last field is turned on) by the expression: the number of fields minus the number of the field turned off multiplied by the standard time interval between cleaning the deposit electrode system of the first field at a standard high voltage in this field. All this allows you to intensify the preliminary (without high voltage) sedimentation of non-combustible dust on the layer of combustible products of fuel combustion, which further reduces the likelihood of ignition of these products with the subsequent inclusion of anti-ignition voltage.

Each of the fields of the electrostatic precipitator electrically switched on at anti-ignition voltage, according to the invention, starting with the latter, begins work on collecting non-combustible dust at its highest concentration in the gas to be cleaned at its inlet, which helps to accelerate the process of coating the combustible layer of fuel combustion products with an non-combustible dust layer and, thereby significantly reduces the operating time of the electrostatic precipitator with reduced efficiency, which is necessary to prevent ignition. All this helps to prevent a fire in the electrostatic precipitator, and also prevents the failure of both the internal mechanical equipment of the electrostatic precipitator (electrode systems, suspension insulators of the corona electrode systems, etc.) and the deformation of the elements of the electrostatic precipitator housing.

The high voltage supply circuit for each field of the electrostatic precipitator, at which it is first raised to the initial corona discharge voltage in this field, and then to the anti-ignition voltage for this field, after the establishment of which the cleaning mechanisms of the precipitation electrode system in this field are turned on, allows electric fields to be phased out maximum efficiency (normal operation at standard voltages and regular intervals for cleaning electrode systems), preventing spark breakdowns and, accordingly but, the ignition of combustible products deposited on the electrode system of each field.

The individual installation of anti-ignition voltage for each field, based on the condition l, 5U _0k ≤U _avk ≤0.8U _prk , allows, on the one hand, to prevent spark breakdowns in the interelectrode gaps of the fields of the electrostatic precipitator, and on the other hand, to ensure efficient deposition of non-combustible dust on combustible layer of fuel combustion products. Moreover, with U _avk ≤0.8U _pk , i.e. with a decrease of 20% or more from the voltage of the spark breakdown of the interelectrode gap, the spark breakdown of the interelectrode gaps is excluded even under adverse external conditions affecting the operation of the electrostatic precipitator and the problematic physical state of the internal mechanical equipment of the electrostatic precipitator, and at U _avk ≥1.5U _0k in the interelectrode the gap provides the minimum sufficient ion current of the corona discharge for electric charging of the trapped particles, as well as the minimum required high voltage for their deposition on precipitation electrode electrostatic precipitator systems. At observance of such parameters, non-combustible dust particles are deposited on the layer of combustible fuel combustion products on the precipitation electrode field systems of the electrostatic precipitator, the minimum required layer height of non-combustible dust particles on the combustible layer is provided to prevent its ignition if, for environmental safety reasons, the operation of the electrostatic precipitator is reduced efficiency.

At U _avk > 0.8 U _pk, in some cases, for example, during cleaning of electrode systems from trapped dust (due to wear of equipment, increased mobility or swaying of electrode systems, in case of problems with power supply of electrostatic precipitator fields with high voltage, etc.), they can be provoked spark breakdowns in interelectrode gaps, leading to ignition of a layer of combustible products of fuel combustion on electrostatic precipitator electrode systems.

At U _avk <1.5U _{0k, the} ion current of the corona discharge in the interelectrode gap and the high voltage are so low that the minimum required efficiency of the electrostatic precipitator for deposition and accumulation of the required layer of non-combustible dust on the combustible layer is not ensured, which reduces the efficiency of removal of the combustible layer during electrode cleaning . All this, with the subsequent transfer of the field to the normal mode of operation at standard high voltage, can lead to ignition of the remnants of the layer of combustible products of fuel combustion that were not removed from the precipitation electrodes during spark breakdowns that are characteristic of the normal mode of operation of the fields of the electrostatic precipitator at standard high voltage. In addition, due to too low voltage and low corona discharge current, the electrostatic precipitator will operate with reduced efficiency, which is unacceptable under environmental safety conditions.

The individual setting of the total time interval for the supply of anti-ignition voltage to each field, based on the conditions 2.0t _avk ≤T _avk ≤3.0t _avk and 1.5 _pcs ≤t _avk ≤3.0 _pcs , provides, taking into account the reduced efficiency of the fields of the electrostatic precipitator at anti-ignition voltage, the maximum achievable deposition of non-combustible dust on the combustible layer of fuel combustion products, which is necessary for the subsequent effective removal of the combustible layer from the surface of the precipitation electrodes when they are cleaned, while minimizing the operating time of the electric ofiltra with reduced efficiency. The intervals are selected from the conditions, on the one hand, to minimize the operating time of the fields of the electrostatic precipitator with reduced efficiency at anti-ignition voltage, and, on the other hand, from the conditions to ensure sufficient accumulation of non-combustible dust on the combustible layer on the precipitation electrodes for effective subsequent removal of the combustible layer during electrode cleaning.

The time interval between cleaning the precipitation electrodes in each field t _avk > 3.0t _pcs leads to an unjustified increase in the operating time of the electrostatic precipitator with reduced efficiency and, accordingly, with an increased concentration of dust in the gases emitted into the atmosphere at anti-ignition voltage in this field, which is unacceptable under the conditions environmental safety.

With a time interval between cleaning precipitation electrodes in each field t _avk <1.5t _pc , the formation of a sufficient height and density of a layer of non-combustible dust on a combustible layer is not ensured, which reduces the efficiency of removal of a combustible layer during electrode cleaning, and therefore, with the subsequent transfer of the field to a regular one operating mode at normal voltage, can lead to ignition of the remnants of the layer of combustible products of fuel combustion not removed from the precipitation electrodes during spark breakdowns characteristic of the operation of the fields of the electrostatic precipitator in normal mode with standard high voltage.

With the total time interval of the supply of anti-igniter voltage for each k-th field T _avk > 3.0t _avk (as well as with a prohibitively high value of the time interval between cleaning sedimentation electrodes t _avk ), the operating time of the electrostatic precipitator increases with reduced efficiency and, accordingly, , with an increased concentration of dust in the gases emitted into the atmosphere, which is unacceptable under environmental safety conditions.

With the total time interval for the supply of anti-ignition voltage for each k-th field T _avk <2.0t _avk (as well as with the extremely low value of the time interval between cleaning precipitation electrodes t _avk ), a sufficient height and density of a layer of non-combustible dust is formed on combustible layer, which reduces the efficiency of removal of the combustible layer when cleaning the electrodes, and therefore, with the subsequent transfer of the field to the normal mode of operation at normal voltage, it can lead to ignition of non-removed sediment x electrodes of the remnants of the layer of combustible products of fuel combustion during spark breakdowns, characteristic of the operation of the fields of the electrostatic precipitator at standard high voltage.

An individual setting in each of the fields of the standard high voltage and the regular time interval between cleaning the precipitation electrodes in this field only after the total time interval for the supply of anti-igniter voltage for this field has elapsed, allows you to set the highest voltage value (usually pre-test) for each field and to achieve the maximum value of the working current of the corona discharge (in accordance with the current-voltage characteristic for each field), which with a standard time interval between kami systems collecting electrodes in each of the electrostatic fields and the normal mode of operation electrode systems purification mechanisms provides the highest efficiency of the electrostatic precipitator for cleaning dust from the gas.

Implementation in an electrostatic precipitator installed behind technological equipment operating in start-up conditions with increased removal of unburned fuel products that are predisposed to ignition from a spark during an electrical breakdown of the electrode gap in an electrostatic precipitator before a planned shutdown of technological equipment, followed by a serial shutdown of the electrostatic precipitator mechanisms for cleaning the systems of precipitation electrodes from trapped dust in all electric fields of the electrostatic precipitator, on Starting from the last field, the individual setting of the interval between the shutdown time of the cleaning mechanisms of the precipitation electrode system for each field and the shutdown time of technological equipment from 0.95 to 0.99 of the regular time interval between the cleaning of the precipitation electrode system at a standard high voltage in this field allows you to set a predetermined time interval during which each field works with disabled cleaning mechanisms of the precipitation electrode system, which allows preventively, with the maximum possible efficiency, to prevent the deposition of combustible products on the surfaces of the precipitation electrode system cleaned from a layer of non-combustible dust during the subsequent, after shutdown, start-up of technological equipment using fuels with increased removal of combustion products prone to ignition from a spark during electrical breakdown of the interelectrode gap in the electrostatic precipitator. As a result of such actions, the probability of ignition of these combustible products, deposited on a previously stored layer of non-combustible dust and then removed together with this layer of dust from the surface of the precipitation electrode systems, is greatly reduced.

The time for preliminary shutdown of the cleaning mechanisms of the precipitation electrode systems is determined by the necessary time for the formation of a layer of non-combustible dust particles of the optimal height and density on the precipitation electrodes of each of the fields of the electrostatic precipitator, and the electrostatic precipitator continues to operate with the given dust cleaning efficiency. At the next start-up of technological equipment, a layer of combustible products settles on a previously saved layer of non-combustible dust (formed on the electrodes before the technological equipment is stopped), then it is repeatedly covered with a new layer of non-combustible dust entering the electrostatic precipitator with cleaned gases from the technological equipment when the anti-ignition voltage is applied and removed with it from the surface of precipitation electrode systems.

If a preliminary shutdown is performed for more than 0.99 of the regular time interval between cleanings, then, depending on the moment of issuing a command to shut down the technological equipment in relation to the current situation in the operation of cleaning mechanisms individually in each field, a double excess of the operating time interval may occur fields of the electrostatic precipitator with the precipitation electrodes cleaning mechanisms disabled, compared to the standard interval at standard high voltage and, accordingly, to excessive accumulation dust on the electrodes, which, in some cases, with the specific properties of the captured dust, can lead to its self-collapse, i.e. to uncontrolled cleaning of electrodes from dust, which is unacceptable, because may lead to ignition of combustible dust during the subsequent start-up of technological equipment.

If preliminary shutdown is performed earlier than after 0.95 of the standard time interval between cleanings, then this time will not be enough to accumulate a layer of non-combustible dust on the precipitation electrode systems of optimal height, which would be sufficient to reliably protect the surface of the precipitation electrodes of the electrostatic precipitator from the deposition of combustible fuel combustion products during the subsequent launch of technological equipment.

Shutdown, in cases of emergency shutdown of technological equipment, first, the cleaning mechanisms of the precipitation electrode systems simultaneously in all fields of the electrostatic precipitator, and then, after a time interval that corresponds to the regular time interval between cleaning the precipitation electrode system of the first field at a nominal high voltage in this field, sequential shutdown starting from the first field, high voltage on all fields of the electrostatic precipitator, except the last field, switching off high voltage on the last field Immediately after the final shutdown of the process equipment, provides electrostatic work as efficiently as possible in the circumstances, a limited time interval to perform the preparatory procedure to withdraw from the work as a whole precipitator. The accumulation of a layer of non-combustible dust particles on the precipitation electrodes of each of the fields of the electrostatic precipitator is provided, and the electrostatic precipitator continues to work, but with reduced efficiency of gas purification from dust. At the next start-up of technological equipment, a layer of combustible products settles on a previously saved layer of non-combustible dust (formed on the electrodes before the emergency shutdown of the technological equipment), then it is repeatedly covered with a new layer of non-combustible dust entering the electrostatic precipitator with cleaned gases from the technological equipment when an anti-ignition voltage is applied and removed from him from the surface of the precipitation electrode systems.

The method according to the invention can be used to prevent ignition of unburned fuel products in electrostatic precipitators, which are discharged together with gases from technological equipment, during the operation of which their increased removal is possible, and which are prone to ignition from a spark during electrical breakdown of the interelectrode gap in electrostatic precipitators.

In a specific example, the inventive method was used to prevent ignition of unburned fuel oil products in a three-floor electrostatic precipitator (n = 3, k = 1, 2, 3), which is installed behind the power boiler of the thermal power plant. The gases generated in the furnace of the energy boiler were cleaned of the ash contained in them in an electrostatic precipitator and then released into the atmosphere through a chimney.

In the normal mode, the energy boiler worked on fossil fuels, and during the start-up of the boiler and before it was put into normal operation, fuel oil was supplied to its furnace as auxiliary fuel. Due to the burning of fuel oil in the boiler furnace, gases with a high content of combustible products of combustion (burning) of fuel oil (soot, oil- and / or tar-like combustible substances), which are prone to ignition from a spark during an electrical breakdown of the interelectrode gap, entered the electrostatic precipitator.

In a specific example, a three-field electrostatic precipitator (n = 3, k = 1, 2, 3) worked with the following parameters:

- nominal high voltage for each of the three fields (U _pcs ): U _pcs1 = 51.5 kV, U _pcs2 = 50.3 kV, U _pcs3 = 50.2 kV;

- the initial voltage of the corona discharge in each of the three fields (U _0k ): U ₀₁ = 21.0 kV, U ₀₂ = 18.1 kV, U ₀₃ = 17.5 kV;

- voltage intense spark breakdown of the interelectrode gap in each of the three fields (U _pk ): U _p1 = 54.6 kV, U _p2 = 53.5 kV, U _p3 = 53.1 kV;

- the regular time interval between cleaning the precipitation electrode system in each of the three fields at a nominal high voltage in each of the three fields (t _pc ): t _pc1 = 10 min, t _pc2 = 30 min, t _pc3 = 90 min.

To prevent ignition of unburned fuel oil products deposited on the electrostatic precipitator electrode systems, the following measures were taken.

When increased removal of unburned fuel oil products occurred from the boiler (for example, it was determined using an automation system or based on data on the start of fuel oil supply to the furnace of the energy boiler), the supply of high (standard) voltage to the corona electrode systems of all three electric fields of the electrostatic precipitator was switched off simultaneously. Then, the cleaning mechanisms of the systems of precipitation electrodes and systems of the corona electrodes from trapped dust were simultaneously turned off simultaneously in all three electric fields of the electrostatic precipitator.

After the termination of the increased removal of unburned fuel oil products (determined, for example, using an automation system or based on data on the completion of the supply of fuel oil to the furnace of an energy boiler), high voltage was applied first to the last 3rd field of the electrostatic precipitator, simultaneously including cleaning mechanisms of the corona electrode system in him, raised it to the initial corona discharge voltage U ₀₃ = 17.5 kV in the 3rd field and then to the anti- _ignition voltage U _av3 = 37.2 kV for the 3rd field, which was established based on the conditions:

l, 5U ₀₃ ≤U _a3 ≤0.8U _pr3 ,

1.5⋅17.5≤37.2≤0.8⋅53.1,

26.25≤37.2≤42.48,

assuming U _av3 = 0.7⋅U _pr3 = 0.7⋅53.1 kV = 37.17 kV ≈ 37.2 kV.

After the anti-ignition voltage was established in the 3rd field, it included mechanisms for cleaning the precipitation electrode system.

Then, a high voltage at a time interval of 10 min, which corresponded to the regular time interval between cleaning the deposit field electrodes of the 1st field with a standard high voltage in the 1st field, was applied to the 2nd field of the electrostatic precipitator, while simultaneously including the cleaning mechanisms of the corona electrode system in it , raised it to the initial corona discharge voltage U ₀₂ = 18, l kV in the 2nd field and then to the anti- _ignition voltage U _ав2 = 37.5 kV for the 2nd field, which was established based on the conditions:

l, 5U ₀₂ ≤U _a2 ≤0.8U _p2 ,

1.5⋅18.1≤37.5≤0.8⋅53.5,

27.15≤37.5≤42.8,

assuming U _av2 = 0.7⋅U _p2 = 0.7⋅53.5 kV = 37.45 kV ≈ 37.5 kV.

After the anti-ignition voltage was established in the 2nd field, it included mechanisms for cleaning the precipitation electrode system.

Then, after the anti- _igniter voltage U _av2 = 37.5 kV was _applied to the 2nd field, after a time interval of 10 minutes, which corresponded to the standard time interval between cleaning the precipitation electrode system of the 1st field at a nominal high voltage in the 1st field, high voltage on the 1st field of the electrostatic precipitator, simultaneously including the cleaning mechanisms of the corona electrode system in it, raised it to the initial corona discharge voltage U ₀₁ = 21.0 kV in the 1st field and then to the anti- _ignition voltage U _ав1 = 38.2 kV for the 1st field, which e installed based on the conditions:

l, 5U ₀₁ ≤U _ab1 ≤0.8U _pp1 ,

1.5⋅21.0≤38.2≤0.8⋅54.6,

31.5≤38.2≤43.68,

assuming U _av1 = 0.7⋅U _p1 = 0.7⋅54.6 kV = 38.22 kV ≈ 38.2 kV.

After the anti-ignition voltage was established in the 1st field, it included mechanisms for cleaning the precipitation electrode system.

The time interval between cleaning the precipitation electrode system in the 3rd field with anti-ignition voltage in this field was set to 180 min (t _av3 , value only for the 3rd field), determining it from the condition:

1.5t pcs ₃ ≤t _av3 ≤3t _pcs3 ,

1.5⋅90 min≤t _av3 ≤3⋅90 min,

assuming t _av3 = 2t _pcs3 = 2⋅90 min = 180 min.

At the same time, the total time interval for the supply of anti-igniter voltage to the 3rd field was set to 360 min (T _av3 , value only for the 3rd field), determining it from the condition:

2.0t _av3 ≤T _av3 ≤3.0t _av3 ,

2.0⋅180 min≤T _av 3≤3.0⋅180 min,

assuming T _av3 = 2.0t _av3 = 2.0-180 min = 360 min.

After the expiration of the total time interval for the supply of anti- _ignition voltage U _ab3 = 37.2 kV to the 3rd field, the standard high voltage U _pc3 = 50.2 kV and the regular time interval between cleaning the precipitation electrode system in the 3rd field t _pc3 = 90 min

The time interval between cleaning the precipitation electrode system in the 2nd field with anti-ignition voltage in this field was set to 60 min (t _av2 , value only for the 2nd field), determining it from the condition:

1.5t _pcs2 ≤t _av2 ≤3t _pcs2 ,

1.5⋅30 min≤t _av2 ≤3⋅30 min,

assuming t _av2 = 2t _pcs2 = 2⋅30 min = 60 min.

In this case, the total time interval for the supply of anti-ignition voltage to the 2nd field was set to 150 min (T _AB2 , the value is only for the 2nd field), determining it from the condition

2.0t _AB2 ≤T _AB2 ≤3.0t _AB2

and taking T _AB2 = 2.5t _AB2 = 2.5-60 min = 150 min.

After the expiration of the total time interval for the supply of anti- _ignition voltage _Uab2 = 37.5 kV to the 2nd field, the standard high voltage U _pc2 = 50.3 kV and the regular time interval between cleaning the precipitation electrode system in the 2nd field t _pc2 = were set in it 30 minutes.

The time interval between cleaning the precipitation electrode system in the 1st field with anti-ignition voltage in this field was set to 30 min (t _av1 , value only for the 1st field), determining it from the condition

l, 5t _sht1 ≤t _av1 ≤3t _sht1

and taking t ⁼ 3t _{AB1 sht1} = 3⋅10 min = 30 min.

In this case, the total time interval for the supply of anti-igniter voltage to the 1st field was set to 90 min (T _av1 , the value is only for the 1st field), determining it from the condition

2.0t _AB1 ≤T _AB1 ≤3.0t _AB1

and taking T _ab1 = 3.0t _ab1 = 3-30 min = 90 min.

After the expiration of the total time interval for the supply of anti- _ignition voltage U _av1 = 38.2 kV to the 1st field, the standard high voltage t _pc1 = 51.5 kV and the regular time interval between cleaning the precipitation electrode system in the 1st field t _pc1 = 10 min.

All this made it possible to prevent the deposition of combustible products of unburned fuel oil on a clean surface of the electrode systems. And if this happened, then when the anti-ignition voltage was applied to the corona electrode systems, the layer of unburned fuel oil, which was prone to ignition, was covered with a layer of ash preventing its ignition, and at the same time, its subsequent removal together with the ash layer during cleaning of the precipitation electrode systems was ensured. Then again a layer of products of unburned fuel oil, prone to ignition, was covered with a layer of ash and again the layer of ash with the remnants of the combustible layer was removed.

In addition, to prevent ignition of unburned fuel oil products that are intensively deposited on the electrostatic precipitator electrode systems during the start-up of the energy boiler after it is shut down when the boiler shutdown is planned, the following measures were taken before the boiler shutdown.

Before the planned shutdown of the energy boiler, in which a special set of planned measures for the decommissioning of the energy boiler is provided, the following operations were performed in the electrostatic precipitator: sequentially shut down the cleaning mechanisms of the precipitation electrode systems from trapped dust in all electric fields of the electrostatic precipitator, starting from the last, 3rd fields, while the supply of a standard high voltage to the corona electrodes and the operation of the cleaning mechanisms of the corona electrodes remained unchanged eny.

First, 88 minutes before the planned shutdown of the boiler (which corresponded to a time interval from 0.95t _pcs3 to 0.99t _pcs3 , namely 0.98t _pcs3 , = 0.98⋅90 min ≈ 88 min), the cleaning mechanisms of the precipitation electrode system were turned off 3rd field. Then, 29 minutes before the planned shutdown of the boiler (which corresponded to a time interval from 0.95t _pcs2 to 0.99t _pcs2 , namely 0.97t _pcs2 = 0.97⋅30 min ≈ ≈29 min), the cleaning mechanisms of the precipitation system were turned off electrodes 2nd field and further, for 9.9 minutes before a planned shutdown of the boiler (which corresponds to a time interval of up to 0,95t _sht1 0,99t _sht1 namely 0,99t _sht1, = 0,99⋅10 = 9 min, 9 min), the cleaning mechanisms of the precipitation electrode system of the 1st field were turned off. Then, according to the established program, a planned shutdown of the energy boiler was carried out with the subsequent withdrawal from operation of the electrostatic precipitator as a whole.

Such a procedure for switching off the cleaning mechanisms of the precipitation electrode systems of the entire electrostatic precipitator before the scheduled shutdown of the power boiler made it possible to preserve the specified ash layer on the precipitation electrodes and preventively, with the highest possible efficiency, prevent the deposition of combustible products (products of unburned fuel oil) on the surfaces of the precipitation systems cleaned of non-combustible ash electrodes during the subsequent start-up of a fuel oil boiler, which greatly reduced the likelihood of ignition of these ucts deposited on the previously stored ash layer and subsequently removed when antivosplamenitelnom voltage together with the ash layer when cleaning the collecting electrodes systems by providing a delay which corresponds to the time interval for the 1st field t _av1 = 30 m, for the 2nd field t _av2 = 60 min, for the 3rd field t _av3 = 180 min and during which the layer of combustible fuel oil burn products deposited on the previously saved ash layer (formed before the previous shutdown of the boiler) was covered with a new layer of ash entering the electrostatic precipitator with smoke gas from a power boiler operating in the normal mode on solid fuel (coal).

In cases of emergency shutdown of the energy boiler (fuel cut-off, burnout of the boiler, etc.), in which a special set of emergency measures is provided to take the energy boiler out of operation, the following operations were performed in the electrostatic precipitator: first, the cleaning mechanisms of the precipitation electrode systems were turned off simultaneously in all fields of the electrostatic precipitator , then, after a time interval of 10 min, which corresponded to the standard time interval between cleaning the deposit field electrodes of the 1st field with a standard high pressure voltage in this field (t _pc1 = 10 min), consistently turned off, starting from the 1st field, high voltage on all fields of the electrostatic precipitator, except for the last 3rd field. The high voltage on the last 3rd field was turned off immediately after the final shutdown of the energy boiler (its complete shutdown), which ensured the operation of the electrostatic precipitator with the highest possible efficiency under the conditions of a limited time interval for the preparatory procedure for the decommissioning of the electrostatic precipitator as a whole, ensuring accumulation of a layer of non-combustible dust particles on the precipitation electrodes of each of the fields of the electrostatic precipitator. Moreover, the electrostatic precipitator continued to work on cleaning the gases discharged from the emergency stop boiler. At the next start-up of the energy boiler (after restoration of its operability), a layer of combustible products deposited on a previously saved layer of non-combustible dust (formed on the electrodes before the emergency shutdown of technological equipment), then was repeatedly covered with a new layer of non-combustible dust entering the electrostatic precipitator from the process equipment when the supply of anti-ignition voltage and was repeatedly removed with it from the surface of the precipitation electrode systems.

Claims (16)

1. A method of preventing ignition of unburned fuel products in the electrostatic precipitator by shutting off the supply during the operation of the process equipment, when increased removal of unburned fuel products predisposed to ignition from a spark during electric breakdown of the interelectrode gap in the electrostatic precipitator installed behind the process equipment occurs high voltage simultaneously on the system of corona electrodes of all electric fields of the electrostatic precipitator and turn off the mechanisms cleaning the precipitation electrode systems and the corona electrode systems from dust collected simultaneously in all electric fields of the electrostatic precipitator, after the termination of the increased removal of products of unburned fuel, high voltage is first applied to the last field of the electrostatic precipitator, simultaneously including the cleaning mechanisms of the corona electrode system in this field, raise it to the initial voltage corona discharge in this field and further to the anti-ignition voltage for this field, after the establishment of which include cleaning mechanisms of the precipitation electrode system in this field, then a high voltage with an interval of time that corresponds to the regular time interval between cleaning the precipitation electrode system of the first field with a nominal high voltage in this field, is applied to each previous field of the electrostatic precipitator, simultaneously including the cleaning mechanisms of the corona system electrodes in this field, raise it to the initial corona discharge voltage in this field and then to the anti-ignition voltage for this o field, after the establishment of which include cleaning mechanisms of the precipitation electrode system in this field, while the anti-ignition voltage for each field is set individually, based on the condition 1.5U _0k ≤U _avk ≤0.8U _prk , where U _0k is the initial voltage of the corona discharge in the k-th field, kV, U _avk - anti- _ignition voltage in the k-th field, kV, U _CR - the voltage of the spark breakdown of the interelectrode gap in the k-th field, kV, k = 1, ..., n, n is the number of fields in the electrostatic precipitator, and the total time interval for supplying an anti-ignition voltage to each field and the time interval between cleaning the precipitation electrode system in each field at an anti-ignition voltage in this field is set individually, based on the conditions 2.0t _avk ≤T _avk ≤3.0t _avk , 15t _pcs ≤t _avk ≤3,0t _pcs , where T _avk is the total time interval for the supply of anti- _ignition voltage to the k-th field, min, t _avk is the time interval between cleaning the precipitation electrode system in the k-th field with anti-ignition voltage in this field, min, t _pc - regular time interval between cleaning the precipitation electrode system in the k-th field at a standard high voltage in this field, min, after the expiration of the total time interval for the supply of anti-ignition voltage to each field in each of the fields individually set the nominal high voltage and regular interval of time between cleaning the precipitation electrode system in this field. 2. The method according to p. 1, characterized in that in the electrostatic precipitator installed behind the process equipment operating in start-up conditions with increased removal of unburned fuel products, predisposed to ignition from a spark during electrical breakdown of the interelectrode gap in the electrostatic precipitator, before the planned shutdown of technological equipment with with the subsequent withdrawal from the operation of the electrostatic precipitator as a whole, a sequential shutdown of the cleaning mechanisms of the precipitation electrode systems from trapped dust in all electrons is carried out starting from the last field, the interval between the shutdown time of the cleaning mechanisms of the precipitation electrode system for each field and the scheduled shutdown of the process equipment individually set from 0.95 to 0.99 regular time interval between cleaning the precipitation electrode system at a regular high voltage in this field. 3. The method according to p. 1, characterized in that in cases of emergency shutdown of technological equipment with subsequent decommissioning of the electrostatic precipitator as a whole, the cleaning mechanisms of the precipitation electrode systems are simultaneously turned off simultaneously in all fields of the electrostatic precipitator, and then after a time interval that corresponds to the standard time interval between cleanings of the system of precipitation electrodes of the first field at a nominal high voltage in this field, in series, starting from the first field, the high voltage in all electric fields is turned off trofilter, except for the last field, while the high voltage on the last field is turned off immediately after the final shutdown of the technological equipment.