KR20220131730A - SF6 Decomposition and pollution control Apparatus - Google Patents

Abstract

The present invention relates to an apparatus for decomposing sulfur hexafluoride and controlling pollution, which comprises: a gas supply unit supplying sulfur hexafluoride, nitrogen gas, burnt gas, and moisture; a reaction unit where the sulfur hexafluoride, the nitrogen gas, the burnt gas, and the moisture are introduced and using the burnt gas, and the moisture to burn and decompose the sulfur hexafluoride; a processing unit using a neutralizing agent to neutralize acidic gas generated in the burning to generate a neutralization salt and discharge the exhaust gas generated in the burning and the neutralization salt; and a control unit receiving a control condition, controlling the gas supply unit according to the control condition, controlling internal environments in the reaction unit and the processing unit, and analyzing composition of the exhaust gas to determine whether the acidic gas is included or not.

Description

Sulfur hexafluoride decomposition and detoxification device {SF6 Decomposition and pollution control Apparatus}

The present invention relates to a device for decomposing and detoxifying sulfur hexafluoride.

Sulfur hexafluoride (SF ₆ ) has excellent chemical and thermal stability and insulation performance, so it is widely used as an efficient insulating gas in various electrical equipment such as switchgear, GIS and annular main circuit.

However, sulfur hexafluoride is a greenhouse gas that contributes to global warming with a high degree of contribution to global warming compared to its emission amount, and it is 23,900 times that of carbon dioxide. A way to deal with it is required.

It is an object of the present invention to provide an apparatus for decomposing and detoxifying sulfur hexafluoride, which decomposes and detoxifies sulfur hexafluoride.

A device for decomposing and detoxifying sulfur hexafluoride according to one aspect for realizing the object of the present invention includes a gas supply unit for supplying sulfur hexafluoride, nitrogen gas, combustion gas and moisture; a reaction unit to which the sulfur hexafluoride, the nitrogen gas, the combustion gas, and the moisture are introduced, and to burn and decompose the sulfur hexafluoride by using the combustion gas and the moisture; a processing unit which neutralizes the acid gas generated in the combustion by using a neutralizing agent to generate a neutral flame, and discharges the exhaust gas and the neutral flame generated in the combustion; and receiving a control condition, controlling the operation of the gas supply unit according to the control condition, controlling the internal environment of the reaction unit and the processing unit, and analyzing a component of the exhaust gas to determine whether the acid gas is included including a control unit that

The control condition is a reference value for each of pressure, temperature, water level, and concentration of a fluid moving in the reaction unit and the processing unit.

The gas supply unit may include: a first supply line supplying the nitrogen gas to the reaction unit; a first pressure regulator for adjusting the pressure of the nitrogen gas; a first flow controller for adjusting the flow rate of the nitrogen gas; a second supply line for supplying the sulfur hexafluoride to the reaction unit; a second pressure regulator for adjusting the pressure of the sulfur hexafluoride; and a second flow rate controller for adjusting the flow rate of the sulfur hexafluoride.

Here, the combustion gas includes any one or more of LNG and air,

The gas supply unit may include a third supply line for supplying the LNG to the reaction unit; a third pressure regulator for regulating the pressure of the LNG; a third flow controller for controlling the flow rate of the LNG; a fourth supply line for supplying the air to the reaction unit; a fourth pressure regulator for regulating the pressure of the air; a fourth flow regulator for adjusting the flow rate of the air; and a moisture supply unit for supplying the moisture to the reaction unit.

The reaction unit may include: a burner into which the nitrogen gas, the LNG, and the air are introduced; and a combustion chamber that provides a combustion space in which the sulfur hexafluoride is combusted, and the sulfur hexafluoride, the nitrogen gas and the moisture are introduced to burn the sulfur hexafluoride to generate the acid gas and the exhaust gas, wherein the acid gas and the exhaust gas are generated. The gas contains any one or more of sulfur trioxide and hydrogen fluoride.

The processing unit, wherein the exhaust gas and the acid gas are introduced, the acid gas is quenched, a detoxification reaction of the acid gas occurs using the neutralizer, and a reaction material is generated by the detoxification reaction. Quencher; a neutralization tank in which the neutralizing agent is stored, the neutralization tank is connected to the actuator, and the reactant is introduced therein to cause a detoxification reaction of the reactant; a storage tank connected to the neutralization tank, into which the neutralized salt generated from the detoxification reaction is introduced and stored, and for discharging the neutralized flame to the outside; and a neutralizing agent supply unit for supplying the neutralizing agent to the neutralization tank,

The neutralizing agent is a liquid composed of at least one of sodium hydroxide, potassium hydroxide, and calcium hydroxide, and moves from the neutralization tank to the quencher,

The reactant is a liquid including at least one of water, the neutralizing agent, the acid gas, and the neutralizing salt.

The processing unit may include: a first moving line through which the reactant moves from the actuator to the neutralization tank; a second moving line through which the neutralizing agent moves from the neutralization tank to the actuator; a third moving line through which the neutralizing flame and the neutralizing agent are moved from the neutralization tank to the storage tank; and a fourth moving line through which the neutralizing agent moved to the storage tank moves to the neutralization tank.

The processing unit further comprises a first discharge line for discharging the exhaust gas flowing into the actuator to the outside,

The storage tank includes a second discharge line for discharging the neutral flame to the outside.

The control unit measures the temperature of the combustion space and controls the operation of the gas supply unit according to the temperature of the combustion space.

The combustion space is divided into first to third spaces sequentially based on one side through which the sulfur hexafluoride is introduced,

The control unit measures the temperatures of the first to third spaces, respectively, and controls the operations of the first to fourth flow rate controllers by using the temperatures of the first to third spaces.

The control unit controls the operation of the first to fourth flow rate controllers using [Equation 1],

[Equation 1]

TR = (TR_1*TR_2+TR_3)/4

When the value of TR is equal to or greater than the first reference value, the first to fourth flow controllers stop operating, TR_1 is the temperature of the first space, TR_2 is the temperature of the second space, and TR_3 is the second 3 Indicates the temperature of the space.

In addition, the control unit measures the internal temperature of the actuator, and controls the operation of the gas supply unit according to the internal temperature of the actuator.

The interior is divided into a gas portion in which a gas is disposed and a liquid portion in which a liquid is disposed,

The control unit measures the temperature of the gas part and the liquid part, respectively.

The control unit controls the operations of the first to fourth flow rate controllers using the respective temperatures of the gas and liquid parts, and when the temperature of the gas part is equal to or greater than a second reference value, the first to fourth flow rate controllers and stops the operation of the first to fourth flow rate controllers when the temperature of the liquid part is equal to or greater than the third reference value.

In addition, the control unit measures the pressure of the combustion space, and controls the operation of the gas supply unit according to the pressure of the combustion space.

The control unit, when the pressure of the combustion space is equal to or greater than a fourth reference value, stops the operations of the first to fourth flow rate controllers.

In addition, the storage tank may include: a discharge valve for opening and closing the second discharge line; and a heater for heating the second discharge line.

The control unit measures the pressure of one side and the other side on the second discharge line based on the discharge valve, respectively, and controls the operation of the second discharge line according to the pressure difference between the one side and the other side.

When the pressure difference between the one side and the other side is equal to or greater than a fifth reference value, the controller operates the heater and controls the discharge valve to open the second discharge line.

In addition, the control unit measures the concentration of the exhaust gas moving through the first exhaust line, and controls the operation of the gas supply unit according to the concentration of the exhaust gas.

The control unit, when the concentration of the sulfur oxide contained in the exhaust gas is equal to or greater than a sixth reference value, stops the operation of the first to fourth flow rate controllers.

The control unit, when the concentration of nitrogen oxide contained in the exhaust gas is equal to or greater than a seventh reference value, stops the operation of the first to fourth flow rate controllers.

The control unit, when the concentration of sulfur hexafluoride contained in the exhaust gas is equal to or greater than the eighth reference value, stops the operation of the first to fourth flow rate controllers.

In addition, the control unit measures the water level of the shaker, the neutralization tank, and the storage tank, and controls the flow of the fluid moving the shaker, the neutralization tank, and the storage tank according to the respective water levels do,

The fluid includes any one or more of the reactant, the neutralizing agent, and the water.

The control unit moves the fluid stored in the actuator to the neutralization tank through the first transfer line when the water level in the actuator is equal to or higher than the first water level.

The control unit opens the third moving line when the water level in the neutralization tank is equal to or higher than the second water level.

The controller opens the second discharge line when the water level of the storage tank is higher than or equal to the third water level.

In addition, the control unit measures a first ph value of the fluid moving through the first moving line and a second ph value inside the neutralization tank, and according to the first ph value and the second ph value, the neutralizing agent Controls the operation of the supply unit.

When the difference between the first ph value and the second ph value is equal to or greater than a ninth reference value, the controller controls the neutralizing agent supply unit to supply the neutralizing agent to the neutralization tank.

According to the device for decomposing and detoxifying sulfur hexafluoride according to an embodiment of the present invention,

First, it is possible to determine the decomposition efficiency of sulfur hexafluoride by measuring the concentration of the exhaust gas.

Second, a safe operation is possible because it is possible to control an abnormal situation by using the temperature inside the reaction unit and the processing unit.

Third, safe operation is possible by regulating the fluid through the water level in the quencher, neutralization tank, and storage tank.

1 is a conceptual diagram schematically showing an apparatus for decomposing and detoxifying sulfur hexafluoride according to an embodiment of the present invention.
2 is a block diagram schematically showing an apparatus for decomposing and detoxifying sulfur hexafluoride according to an embodiment of the present invention.

Hereinafter, preferred embodiments of the present invention will be described in more detail with reference to the accompanying drawings. In this case, it should be noted that in the accompanying drawings, the same components are denoted by the same reference numerals as much as possible. In addition, detailed descriptions of well-known functions and configurations that may obscure the gist of the present invention will be omitted. For the same reason, some components are exaggerated, omitted, or schematically illustrated in the accompanying drawings.

1 is a conceptual diagram schematically showing an apparatus for decomposing and detoxifying sulfur hexafluoride according to an embodiment of the present invention, and FIG. 2 is a block diagram schematically showing an apparatus for decomposing and detoxifying sulfur hexafluoride according to an embodiment of the present invention .

A sulfur hexafluoride decomposition and detoxification apparatus 100 of the present invention will be described with reference to FIGS. 1 and 2 .

The apparatus 100 for decomposing and detoxifying sulfur hexafluoride of the present invention includes a gas supply unit 110 , a reaction unit 120 , a processing unit 130 , and a control unit 140 .

The gas supply unit 110 supplies sulfur hexafluoride, nitrogen gas, combustion gas, and moisture.

Here, the combustion gas includes at least one of LNG and air.

In addition, the gas supply unit 110 includes a first supply line 111 , a second supply line 112 , a third supply line 113 , a fourth supply line 114 , and a moisture supply unit 115 .

The first supply line 111 supplies nitrogen gas to the reaction unit 120 , and the first supply line 111 includes a first pressure regulator 111a and a first flow rate regulator 111b.

The first pressure regulator 111a adjusts the pressure of the nitrogen gas, and the first flow rate controller 111b controls the flow rate of the nitrogen gas.

The second supply line 112 supplies sulfur hexafluoride gas to the reaction unit 120 , and the second supply line 112 includes a second pressure regulator 112a and a second flow rate regulator 112b.

The second pressure regulator 112a adjusts the pressure of the sulfur hexafluoride gas, and the second flow rate controller 112b adjusts the flow rate of the sulfur hexafluoride gas.

The third supply line 113 supplies LNG to the reaction unit 120 , and the third supply line 113 includes a third pressure regulator 113a and a third flow rate regulator 113b .

The third pressure regulator 113a adjusts the pressure of LNG, and the third flow regulator 113b adjusts the flow rate of LNG.

The fourth supply line 114 supplies air to the reaction unit 120 , and the fourth supply line 114 includes a fourth pressure regulator 114a and a fourth flow rate regulator 114b .

The fourth pressure regulator 114a adjusts the pressure of the air, and the fourth flow regulator 114b adjusts the flow rate of the air.

The moisture supply 115 supplies moisture to the reaction unit 120 and includes a first pump 115a, a fifth flow rate controller 115b and a steamer 115c.

The first pump 115a moves water, the fifth flow controller 115b controls the amount of water, and the steamer 115c changes water into steam.

The reaction unit 120 receives sulfur hexafluoride, nitrogen gas, combustion gas and moisture, and uses the combustion gas and moisture to burn and decompose sulfur hexafluoride.

In addition, the reaction unit 120 includes a burner 121 and a combustion chamber 122 .

In the burner 121, nitrogen gas, LNG and air are introduced and combusted, the combustion chamber 122 provides a combustion space 133 in which sulfur hexafluoride is burned, and sulfur hexafluoride, nitrogen gas and the moisture are introduced to the meat. Sulfur fluoride is combusted to produce acid gases and exhaust gases.

The combustion space 133 is divided into three spaces, and is divided into a first space 133a, a second space 133b, and a third space 133c based on one side through which sulfur hexafluoride is introduced.

The reaction equation occurring in the combustion space 133 is SF ₆ +3H ₂ O → SO ₃ + 6HF.

Here, the acid gas includes at least one of sulfur trioxide (SO ₃ ) and hydrogen fluoride (HF),

The exhaust gas includes any one or more of nitrogen gas, sulfur hexafluoride, sulfur oxides, and nitrogen oxides, other than the gas used for combustion among a plurality of gases constituting air.

The processing unit 130 generates a neutral flame by neutralizing the acid gas generated in combustion using a neutralizing agent, and discharges the exhaust gas and the neutral flame generated in the combustion.

And, the processing unit 130 is quenched (Quencher) 131, the neutralization tank 132, the storage tank 133, the neutralizer supply unit 134, the first moving line 135, the second moving line (136) , a third moving line 137 , a fourth moving line 138 and a first discharge line 139 .

Discharge gas and acid gas are introduced into the chir 131 , and the acid gas is quenched, and a detoxification reaction of the acid gas occurs using a neutralizer, and a reactant is generated by the detoxification reaction.

The reaction equation occurring in the source 131 is SO ₃ + 6HF + 8X ^* OH → X ₂ SO ₄ (s) + XF(s) + 7H ₂ O (X: K, Na, Ca _0.5 , etc.).

Here, the chuck 131 may be divided into a gas part and a liquid part. The gas part is a space in which the gas flowing into the cleator 131 is located, and the liquid part is the liquid part flowing into the cleator 131 . is the space it is located in.

The neutralization tank 132 stores the neutralizing agent, and is connected to the quencher 131 , and the reactant generated in the quencher 131 flows in, thereby detoxifying the reactant.

Here, the inside of the neutralization tank 132 is maintained at a predetermined pH.

The storage tank 133 is connected to the neutralization tank 132, the neutralized flame generated from the detoxification reaction is introduced and stored, and the neutralized flame is discharged to the outside.

The neutralizing agent supply unit 134 supplies the neutralizing agent to the neutralization tank 132 .

Here, the neutralizing agent is a liquid composed of at least one of sodium hydroxide (NaOH), potassium hydroxide (KOH), and calcium hydroxide (Ca(OH) ₂ ), and is gentle in the quencher 131 and the neutralization tank 132 .

The reactant is a liquid composed of at least one of a neutralizing agent, an acid gas, and a neutralizing salt.

The reaction material is generated in the quencher 131 , where the acid gas and exhaust gas are introduced from the combustion chamber 122 , and the neutralizing agent is introduced and injected from the neutralization tank 132 .

Then, in the quencher 131 , the acid gas and the exhaust gas meet and react with the neutralizing agent to generate a neutral flame and water, and other unreacted components may be dissolved in the water.

Here, the reactant may be a liquid in which an unreacted neutralizing agent, water, and a neutralizing salt are mixed.

The first moving line 135 moves the reactants from the actuator 131 to the neutralization tank 132 , and the first moving line 135 includes a second pump 135a.

The second moving line 136 moves the neutralizing agent from the neutralization tank 132 to the quencher 131 , and the second moving line 136 includes a third pump 136a.

The third moving line 137 moves the neutralizing flame and the neutralizing agent from the neutralizing tank 132 to the storage tank 133 , and the third moving line 137 includes a fourth pump 137a.

The fourth moving line 138 moves the neutralizing agent moved to the storage tank 133 to the neutralizing tank 132 , and the fourth moving line 138 includes a fifth pump 138a.

The first discharge line 139 discharges the exhaust gas introduced into the actuator 131 to the outside, and the first discharge line 139 includes a sixth flow rate controller 139a.

And, the storage tank 133 further includes a second discharge line 133a, a discharge valve 133b and a heater (not shown), the second discharge line 133a is the neutral flame stored in the storage tank 133 discharged to the outside, the discharge valve 133b opens and closes the second discharge line 133a, and a heater (not shown) heats the second discharge line 133a.

The control unit 140 receives a control condition, controls the operation of the gas supply unit 110 according to the control condition, controls the internal environment of the reaction unit 120 and the processing unit 130 , and analyzes the components of the exhaust gas. to determine whether acid gas is included.

The control conditions include reference values for pressure, temperature, water level, and concentration of the fluid moving the reaction unit 120 and the processing unit 130 inside the reaction unit 120 and the processing unit 130 , respectively.

A process in which the control unit 140 controls the operation of the gas supply unit 110 according to the internal temperature of the reaction unit 120 and the processing unit 130 will be described.

The controller 140 measures the temperature of the combustion space 123 and controls the operation of the gas supply unit 110 according to the temperature of the combustion space 123 .

Specifically, the controller 140 measures the temperature of the first to third spaces 123a, 123b, and 123c of the combustion space 123, respectively, and the temperature of the first to third spaces 123a, 123b, 123c. to control the operations of the first to fourth flow rate controllers 111a, 112a, 113a, and 114a.

The control unit 140 controls the operation of the first to fourth flow rate controllers 111a, 112a, 113a, 114a using [Equation 1],

[Equation 1]

TR = (TR_1*TR_2+TR_3)/4

When the value of TR is equal to or greater than the first reference value, the operation of the first to fourth flow rate controllers 111a, 112a, 113a, and 114a is stopped.

Here, TR_1 represents the temperature of the first space 123a, TR_2 represents the temperature of the second space 123b, and TR_3 represents the temperature of the third space 123c.

The combustion space 123 may increase in temperature when LNG or air is excessively supplied.

Here, it is set to control the operation of the gas supply unit 110 according to the weighted average value by setting an average value by giving weight to the temperature of the second space 123b and setting a temperature alarm.

In addition, by setting a standard deviation value for each temperature measurement part of the first to third spaces 123a, 123b, and 123c, a local abnormal situation inside the combustion space may also be detected.

In addition, the control unit 140 measures the temperature inside the actuator 131 and controls the operation of the gas supply unit 110 according to the internal temperature of the actuator 131 .

Specifically, the control unit 140 measures the temperatures of the gas and liquid portions of the actuator 131, respectively, and uses the respective temperatures of the gas and liquid portions for the first to fourth flow rate controllers 111a, 112a, and 113a. , 114a) controls the operation.

When the temperature of the gas portion is equal to or greater than the second reference value, the controller 140 stops the operations of the first to fourth flow rate controllers 111a, 112a, 113a, 114a and

When the temperature of the liquid portion is equal to or greater than the third reference value, the first to fourth flow rate controllers 111a, 112a, 113a, and 114a are stopped.

A process in which the control unit 140 controls the operation of the gas supply unit 110 according to the internal pressure of the reaction unit 120 and the processing unit 130 will be described.

The control unit 140 measures the pressure of the combustion space 123 and controls the operation of the gas supply unit 110 according to the pressure of the combustion space 123 .

When the pressure of the combustion space 123 is equal to or greater than the fourth reference value, the controller 140 stops the operations of the first to fourth flow rate controllers 111a, 112a, 113a, and 114a.

When the pressure of the combustion space 123 is equal to or greater than the fourth reference value, an excessively large amount of gas is supplied to the combustion space 123 , or it may be caused by clogging of the discharge part through which the gas is discharged to the quencher 131 . .

In addition, a process in which the controller 140 controls the second discharge line 133 by using the pressure of one side and the other side with respect to the discharge valve 133b in the second discharge line 133a will be described.

The control unit 140 measures pressures of one side and the other side of the second discharge line 133a, respectively.

Here, one side is a portion adjacent to the storage tank 133 with respect to the discharge valve 133b, and the other side is a portion adjacent to the outside.

When the pressure difference between one side and the other side is equal to or greater than the fifth reference value, the control unit 140 operates a heater (not shown) to heat the second discharge line 133, and controls the discharge valve 133b to control the second discharge line ( 133) is opened to discharge the liquid containing the neutral flame stored in the storage tank 133 to the outside.

Such a situation does not occur at the initial stage of operation, but the neutral flame may be over-dissolved in water during continuous operation or may occur locally at a low temperature.

A process in which the control unit 140 controls the operation of the gas supply unit 110 according to the concentration of the fluid moving through the reaction unit 120 and the processing unit 130 will be described.

The controller 140 measures the concentration of the exhaust gas moving through the first exhaust line 139 and controls the operation of the gas supply unit 110 according to the concentration of the exhaust gas.

Specifically, when the concentration of sulfur oxide contained in the exhaust gas is equal to or greater than the sixth reference value, the controller 140 stops the operations of the first to fourth flow rate controllers 111a, 112a, 113a, and 114a.

Also, when the concentration of nitrogen oxide contained in the exhaust gas is equal to or greater than the seventh reference value, the controller 140 stops the operations of the first to fourth flow rate controllers 111a, 112a, 113a, and 114a.

In addition, when the concentration of sulfur hexafluoride contained in the exhaust gas is equal to or greater than the eighth reference value, the controller 140 stops the operation of the first to fourth flow rate controllers 111a, 112a, 113a, and 114a.

When the concentrations of sulfur oxides, nitrogen oxides and sulfur hexafluoride are detected above the sixth to eighth reference values, it not only means that the decomposition rate of sulfur hexafluoride decomposed in the combustion chamber 122 is low, but also that the air pollutants are released, so the error is reduced Minimized detection is required.

Therefore, in order to minimize the effect of disturbance in the process of measuring the concentration of the exhaust gas, the concentration value is measured by applying the noise-filtered average value.

A process in which the control unit 140 controls the operation of the gas supply unit 110 according to the water level of the processing unit 130 will be described.

The control unit 140 controls the shut-off 131, the neutralization tank 132, and the storage tank 133 according to the water levels of the quencher 131, the neutralization tank 132, and the storage tank 133 of the fluid moving. control the flow

Here, the fluid includes any one or more of a reactant, a neutralizing agent, and water.

Specifically, when the water level of the quencher 131 is equal to or higher than the first water level, the controller 140 moves the fluid stored in the quencher 131 to the neutralization tank 132 through the first transfer line 135 . .

Also, when the water level in the neutralization tank 132 is equal to or higher than the second water level, the controller 140 moves the fluid stored in the neutralization tank 132 to the storage tank 133 through the third transfer line 137 .

Also, when the water level of the storage tank 133 is equal to or higher than the third water level, the controller 140 discharges the fluid stored in the storage tank 133 to the outside through the second discharge line 133a.

A process in which the controller 140 controls the operation of the neutralizing agent supply unit 134 according to the first ph value of the fluid moving through the first moving line 135 and the second ph value in the neutralization tank 132 will be described.

The controller 140 measures the first ph value of the fluid moving the first moving line 135 and the second ph value inside the storage tank 133 , and the difference between the first ph value and the second ph value is the ninth When it is equal to or greater than the reference value, the neutralizing agent supply unit 134 is controlled to supply the neutralizing agent to the neutralization tank 132 .

Here, the second ph value must be maintained within a certain range. The first ph value is smaller than the second ph value, and the larger the difference between the two values, the greater the change in the second ph value due to the first ph value. need to supply

Additionally, the controller 140 may output a prior notification before performing the control operation by setting a separate notification value before performing the control operation in a plurality of control operations.

In addition, the controller 140 may measure the concentration of sulfur hexafluoride moving through the second supply line 112 and determine the decomposition rate of sulfur hexafluoride by comparing the concentration of sulfur hexafluoride detected in the exhaust gas.

In addition, the control unit 140 stores the decomposition rate of sulfur hexafluoride according to the amount of gas introduced from the gas supply unit 110 and the amount of the neutralizing agent introduced into the quencher, so that the decomposition rate of sulfur hexafluoride according to each amount can be dataized.

Although it has been described with reference to the above embodiments, it will be understood by those skilled in the art that various modifications and changes can be made to the present invention without departing from the spirit and scope of the present invention as set forth in the claims below. will be able

110...gas supply
111...first supply line 111a...first pressure regulator
111b...first flow regulator
112...Second supply line 112a...Second pressure regulator
112b...second flow regulator
113...third supply line 113a...third pressure regulator
113b...third flow regulator
114...Fourth supply line 114a...Fourth pressure regulator
114b...Fourth flow regulator
115...moisturizer 115a...first pump
115b... Fifth flow regulator 115c... Steamer
120...reaction section
121...burner 122...combustion chamber
123...combustion space 123a...first space
123b...Second space 123c...Third space
130...processing unit 131...??
132...neutralization tank 133...storage tank
133a...Second discharge line 133b...Drain valve
134...Neutralizer supply unit 135...First moving line
136...Second moving line 137...Third moving line
138...Fourth transfer line 139...First discharge line
140...control unit

Claims (28)

a gas supply unit for supplying sulfur hexafluoride, nitrogen gas, combustion gas and moisture;
a reaction unit to which the sulfur hexafluoride, the nitrogen gas, the combustion gas, and the moisture are introduced, and to burn and decompose the sulfur hexafluoride by using the combustion gas and the moisture;
a processing unit which neutralizes the acid gas generated in the combustion by using a neutralizing agent to generate a neutral flame, and discharges the exhaust gas and the neutral flame generated in the combustion; and
receiving a control condition, controlling the operation of the gas supply unit according to the control condition, controlling the internal environment of the reaction unit and the processing unit, and analyzing a component of the exhaust gas to determine whether the acid gas is included control
including,
The control condition is a reference value for each of the pressure, temperature, water level, and concentration of the fluid moving the processing unit in the reaction unit and the processing unit, sulfur hexafluoride decomposition and detoxification apparatus. According to claim 1,
The gas supply unit,
a first supply line for supplying the nitrogen gas to the reaction unit;
a first pressure regulator for adjusting the pressure of the nitrogen gas;
a first flow controller for adjusting the flow rate of the nitrogen gas;
a second supply line for supplying the sulfur hexafluoride to the reaction unit;
a second pressure regulator for adjusting the pressure of the sulfur hexafluoride; and
A second flow rate controller to control the flow rate of the sulfur hexafluoride
containing, sulfur hexafluoride Disassembly and detoxification device. 3. The method of claim 2,
The combustion gas includes any one or more of LNG and air,
The gas supply unit,
a third supply line for supplying the LNG to the reaction unit;
a third pressure regulator for regulating the pressure of the LNG;
a third flow controller for controlling the flow rate of the LNG;
a fourth supply line for supplying the air to the reaction unit;
a fourth pressure regulator for regulating the pressure of the air;
a fourth flow regulator for adjusting the flow rate of the air; and
a moisture supply device for supplying the moisture to the reaction unit
containing, sulfur hexafluoride Disassembly and detoxification device. 4. The method of claim 3,
The reaction unit,
a burner into which the nitrogen gas, the LNG and the air are introduced; and
A combustion chamber that provides a combustion space in which the sulfur hexafluoride is combusted, and the sulfur hexafluoride, the nitrogen gas and the moisture are introduced to burn the sulfur hexafluoride to generate the acid gas and the exhaust gas
including,
The acid gas, including any one or more of sulfur trioxide and hydrogen fluoride, sulfur hexafluoride Disassembly and detoxification device. 5. The method of claim 4,
The processing unit,
Quencher in which the exhaust gas and the acid gas are introduced, the acid gas is quenched, a detoxification reaction of the acid gas occurs using the neutralizer, and a reaction material is generated by the detoxification reaction ;
a neutralization tank in which the neutralizing agent is stored, the neutralization tank is connected to the actuator, and the reactant is introduced therein to cause a detoxification reaction of the reactant;
a storage tank connected to the neutralization tank, into which the neutralized salt generated from the detoxification reaction is introduced and stored, and for discharging the neutralized flame to the outside; and
A neutralizing agent supply unit for supplying the neutralizing agent to the neutralization tank
including,
The neutralizing agent,
a liquid composed of at least one of sodium hydroxide, potassium hydroxide, and calcium hydroxide, and moves from the neutralization tank to the
The reactant is a liquid containing at least one of water, the neutralizing agent, the acid gas, and the neutralizing salt, sulfur hexafluoride Disassembly and detoxification device. 6. The method of claim 5,
The processing unit,
a first transfer line through which the reactant material moves from the actuator to the neutralization tank;
a second moving line through which the neutralizing agent moves from the neutralization tank to the actuator;
a third moving line through which the neutralizing flame and the neutralizing agent are moved from the neutralization tank to the storage tank; and
A fourth moving line through which the neutralizing agent moved to the storage tank moves to the neutralization tank
Further comprising, sulfur hexafluoride Disassembly and detoxification device. 7. The method of claim 6,
The processing unit,
A first discharge line for discharging the exhaust gas flowing into the locker to the outside
further comprising,
The storage tank,
A second discharge line for discharging the neutral flame to the outside
Containing, sulfur hexafluoride decomposition and detoxification device. 8. The method of claim 7,
The control unit is
A device for decomposing and detoxifying sulfur hexafluoride, which measures the temperature of the combustion space and controls the operation of the gas supply unit according to the temperature of the combustion space. 9. The method of claim 8,
The combustion space is
It is divided into first to third spaces sequentially based on one side through which the sulfur hexafluoride is introduced,
The control unit is
A device for decomposing and detoxifying sulfur hexafluoride, which measures the temperature of the first to third spaces, respectively, and controls the operation of the first to fourth flow rate controllers using the temperature of the first to third spaces. 10. The method of claim 9,
The control unit is
Using [Equation 1] to control the operation of the first to fourth flow rate regulators,
[Equation 1]
TR = (TR_1*TR_2+TR_3)/4
When the value of TR is greater than or equal to the first reference value, the first to fourth flow regulators stop the operation,
wherein TR_1 represents the temperature of the first space, TR_2 represents the temperature of the second space, and TR_3 represents the temperature of the third space. 8. The method of claim 7,
The control unit is
A device for decomposing and detoxifying sulfur hexafluoride, which measures the internal temperature of the quencher and controls the operation of the gas supply unit according to the internal temperature of the quencher. 12. The method of claim 11,
The inside is said to
It is divided into a gas portion in which the gas is disposed and a liquid portion in which the liquid is disposed,
The control unit is
Sulfur hexafluoride decomposition and detoxification apparatus for measuring the temperature of the gas part and the liquid part, respectively. 8. The method of claim 7,
The control unit is
Controlling the operation of the first to fourth flow rate regulators using the respective temperatures of the gas and liquid parts,
When the temperature of the gas portion is greater than or equal to the second reference value, the first to fourth flow controllers stop the operation,
When the temperature of the liquid portion is equal to or greater than the third reference value, the first to fourth flow rate controllers stop the operation, sulfur hexafluoride decomposition and detoxification device. 8. The method of claim 7,
The control unit is
A device for decomposing and detoxifying sulfur hexafluoride, which measures the pressure of the combustion space and controls the operation of the gas supply unit according to the pressure of the combustion space. 15. The method of claim 14,
The control unit is
When the pressure in the combustion space is equal to or greater than the fourth reference value, the first to fourth flow rate controllers stop the operation, sulfur hexafluoride decomposition and detoxification device. 8. The method of claim 7,
The storage tank,
a discharge valve for opening and closing the second discharge line; and
a heater for heating the second discharge line
Further comprising, sulfur hexafluoride decomposition and detoxification device. 17. The method of claim 16,
The control unit is
Measuring the pressure of one side and the other side, respectively, based on the discharge valve on the second discharge line,
Sulfur hexafluoride decomposition and detoxification device for controlling the operation of the second discharge line according to the pressure difference between the one side and the other side. 18. The method of claim 17,
The control unit is
When the pressure difference between the one side and the other side is equal to or greater than a fifth reference value, the apparatus for decomposing and detoxifying sulfur hexafluoride, which operates the heater and controls the discharge valve to open the second discharge line. 8. The method of claim 7,
The control unit is
A device for decomposing and detoxifying sulfur hexafluoride, which measures the concentration of the exhaust gas moving through the first exhaust line and controls the operation of the gas supply unit according to the concentration of the exhaust gas. 20. The method of claim 19,
The control unit is
When the concentration of the sulfur oxide contained in the exhaust gas is equal to or greater than the sixth reference value, the first to fourth flow rate controllers stop the operation, sulfur hexafluoride decomposition and detoxification device. 20. The method of claim 19,
The control unit is
When the concentration of nitrogen oxides contained in the exhaust gas is equal to or greater than a seventh reference value, the first to fourth flow rate controllers stop the operation, sulfur hexafluoride decomposition and detoxification device. 20. The method of claim 19,
The control unit is
When the concentration of sulfur hexafluoride contained in the exhaust gas is equal to or greater than the eighth reference value, the first to fourth flow rate controllers stop the operation, sulfur hexafluoride decomposition and detoxification device. 8. The method of claim 7,
The control unit is
Measuring the water level of the shaker, the neutralization tank and the storage tank, and controlling the flow of the fluid moving the shaker, the neutralization tank and the storage tank according to the respective water levels,
The fluid, the reaction material, the neutralizing agent, and the water containing any one or more, sulfur hexafluoride decomposition and detoxification device. 24. The method of claim 23,
The control unit is
Sulfur hexafluoride decomposition and detoxification apparatus for moving the fluid stored in the locker to the neutralization tank through the first transfer line when the water level of the locker is higher than or equal to the first water level. 24. The method of claim 23,
The control unit is
When the water level in the neutralization tank is higher than or equal to the second water level, the third moving line is opened, sulfur hexafluoride decomposition and detoxification device. 24. The method of claim 23,
The control unit is
When the water level in the storage tank is above the third water level, the second discharge line is opened, sulfur hexafluoride decomposition and detoxification device. 8. The method of claim 7,
The control unit is
Measuring a first ph value of the fluid moving through the first moving line and a second ph value inside the neutralization tank, and controlling the operation of the neutralizing agent supply unit according to the first ph value and the second ph value , sulfur hexafluoride decomposition and detoxification device. 28. The method of claim 27,
The control unit is
When the difference between the first ph value and the second ph value is greater than or equal to a ninth reference value, the device for decomposing and detoxifying sulfur hexafluoride is to control the neutralizing agent supply unit to supply the neutralizing agent to the neutralization tank.

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