JP2023014441A - Flare gas combustion treatment system - Google Patents

Abstract

To provide a flare gas combustion treatment system capable of combusting a wide variety of flare gas including flare gas of a low calorific value incapable of burning by itself and flare gas capable of burning by itself, and capable of handling an instantly changing flow rate of flare gas while minimizing the cost of auxiliary fuel.SOLUTION: The flare gas combustion processing system comprises a VDU 1, EGF 3 and an information processing device that controls the entire system. One end of a flare gas line 40 is connected to the VDU 1 and EGF 3, respectively. A supply shut-off device that opens or shuts flare gas stream and controls the flow rate thereof is provided on the middle of the flare gas line 40 leading to the VDU 1 and on the middle of the flare gas line 40 leading to the EGF 3 respectively. The information processing device operates the supply shut-off device relating to the EGF 3 to shut the flare gas line 40 leading to the EGF 3, when flare gas combustion treatment is performed by the VDU 1. The information processing device operates the supply shut-off device relating to the VDU 1 to shut the flare gas line 40 leading to the VDU 1 or to control the flow rate of flare gas, when flare gas combustion treatment is performed by the EGF 3.SELECTED DRAWING: Figure 1

Description

The present invention relates to a flare gas combustion treatment system for burning flare gas (also referred to as "hydrocarbon gas" or "hydrocarbon") generated from oil refineries, steel plants, chemical plants, and gas storage facilities.

Flare gas such as methane is generated in oil refineries, steel plants, chemical plants, and gas storage facilities. Flare gas is combustible, toxic, and has an odor. Therefore, it is necessary to incinerate the gas and discharge it in a state in which it is rendered harmless to some extent, rather than discharging it into the atmosphere as it is.

In recent years, in the United States and other countries, laws and regulations have been revised to prohibit the emission of combustible flare gas in units of PPM (=parts per million).

By the way, there is VDU (Vapor Destruction Unit) as one of combustion processing methods for flare gas containing a large amount of inert gas such as nitrogen.

A conventional VDU oxidizes and burns the combustibles contained in the flare gas in a high-temperature atmosphere with sufficient combustion air, converts the flare gas into carbon dioxide and water, and releases them into the atmosphere. The VDU has the advantage of being able to burn flare gas that has a low calorific value and cannot be self-combusted.

On the other hand, conventional VDUs also have disadvantages. A detailed description will be given below. In the conventional VDU, a high-temperature burner is used to burn auxiliary fuel before the flare gas is introduced into the furnace in order to create a high-temperature atmosphere. As the concentration of combustibles in the flare gas increases, the amount of auxiliary fuel in the heating burner is reduced in order to keep the inside of the furnace below the maximum allowable temperature. to cool. In the conventional VDU, the cooling air is forcibly sent by a blower or the like, so the flow rate of the cooling air that can be used (controlled) is limited. Therefore, the maximum combustible concentration in the flare gas that can be processed and the maximum flow rate of the flare gas depend on the flow rate of the cooling air that can be forcibly supplied from a blower or the like.

Another method for burning self-flammable flare gas is EGF (Enclosed Ground Flare).

The EGF burns the flare gas by stepwise adjusting the number of flare burners for burning the flare gas according to the flow rate of the flare gas whose flow rate varies from 0 to 100%. Specifically, a flare gas path leading to each flare burner is provided, and a cutoff valve is provided in each path. Depending on the amount of flare gas to be supplied, the number of passages to be conducted is adjusted by the cutoff valve, thereby gradually adjusting the number of flare burners to be operated. This technique is known as "staging control for EGF".

Japanese Unexamined Utility Model Publication No. 58-128352

For example, Patent Literature 1 discloses the following configuration as a prior art. In the flare gas combustion system (grand flare), several combustion zones (≒stages) are provided in the flare gas combustion processing system in order to correspond to the flare gas flow rate from the plant. A staging switching device (supply/cutoff device) is provided in one or more sub-paths other than the path. The staging switching device (supply/cutoff device) performs an opening operation by means of an electrical signal with an instrumented air pressure when the flare gas pressure in the main path rises, allowing the flare gas to flow through the sub path.

If the calorific value of the flare gas is low and stable combustion cannot be expected, auxiliary fuel is injected into the flare gas in advance to increase the calorific value and burn. As compared with the VDU, a large amount of supplementary fuel is required for self-combustion.

In addition, since the flow rate of the flare gas fluctuates instantaneously, when adjusting the injection amount of auxiliary fuel according to the concentration of combustibles contained in the flare gas, it is necessary to measure the flow rate of the flare gas and the concentration of combustibles, and It is necessary to instantaneously perform the two steps of "calculating the optimum auxiliary fuel injection amount based on Therefore, the injection amount of auxiliary fuel is calculated and injected based on the minimum standard of combustible concentration, and the cost of auxiliary fuel increases beyond the required amount.

As described above, the conventional VDU has a limit of application based on the air volume of cooling air by a blower or the like, and the EGF has a cost demerit based on the injection amount of auxiliary fuel. Therefore, there has been no technology capable of burning a flare gas with a low calorific value, which cannot be self-combusted, and capable of coping with instantaneously fluctuating flow rates of the flare gas while minimizing the cost.

Therefore, in order to deal with the above problems, the present invention can burn a wide range of flare gases, including non-self-burning flare gases with a low calorific value and self-burning flare gases, and can instantly fluctuate while minimizing auxiliary fuel costs. It is an object of the present invention to provide a flare gas combustion processing system capable of coping with a flare gas flow rate.

In order to achieve the above object, the invention according to claim 1 is
A flare gas combustion processing system for burning flare gas,
The system includes a VDU and EGF, and an information processing device that controls the entire system,
One end of a flare gas line for supplying flare gas is connected to each of the VDU and the EGF,
A supply cutoff device for opening, blocking, and controlling the flow rate of the flare gas is provided in the middle of the flare gas line toward the VDU and in the middle of the flare gas line toward the EGF, respectively,
When performing flare gas combustion processing in the VDU, the information processing device operates the supply cutoff device related to the EGF to close the flare gas line leading to the EGF,
When performing flare gas combustion processing in the EGF, the information processing device operates the supply cutoff device related to the VDU to close or control the flow rate of the flare gas line leading to the VDU. Flare gas combustion processing system.

Further, the invention according to claim 2 is
2. The flare gas combustion treatment system according to claim 1, wherein the flare gas, which has a low combustible component concentration and cannot self-combust, is combusted by the VDU.

Further, the invention according to claim 3 is
The VDU is provided with an air intake damper that takes in air from the outside,
The information processing device controls the amount of auxiliary fuel when the temperature in the VDU rises to a preset temperature or higher,
2. Even if the amount of auxiliary fuel is controlled, when the temperature inside the VDU is equal to or higher than a preset temperature, the air intake damper is opened and air is taken into the VDU from the outside by natural suction. 2 as the flare gas combustion treatment system.

Further, the invention according to claim 4 is
When the temperature in the VDU is equal to or higher than a preset temperature, the information processing device operates the supply cutoff device related to the VDU to close or control the flow rate of the flare gas line toward the VDU. 4. The flare gas combustion processing system according to any one of claims 1 to 3, wherein the supply cutoff device associated with the EGF is operated to open the flare gas line leading to the EGF.

Further, the invention according to claim 5 is
When the flow rate of the flare gas drops below a preset value of the flare gas pressure, the information processing device operates the supply cutoff device related to the EGF to cut off the flare gas line toward the EGF. The flare gas combustion processing system according to any one of claims 1 to 4, wherein the flare gas line directed to the VDU is opened or flow rate is controlled by operating the supply cutoff device related to the VDU while closing the flare gas line.

Further, the invention according to claim 6 is
The other end of the flare gas line is connected to a combustible gas storage device in which flare gas is stored and provided with a safety valve that operates when overpressure occurs,
The flare gas line has a length from one end to the other end that takes at least several seconds for the flare gas flowing out from the other end to reach the one end,
A safety valve detection device for detecting the operation of the safety valve is provided in the middle of the flare gas line near the combustible gas storage device,
When the internal pressure of the combustible gas storage device reaches an overpressure state and the safety valve operates, the safety valve detection device detects the operation and outputs a signal to that effect to the information processing device,
When the information processing device receives the signal, the information processing device operates the supply cutoff device related to the VDU, closes or controls the flow rate of the flare gas line heading to the VDU, and cuts the supply cutoff device related to the EGF. The flare gas combustion treatment system according to any one of claims 1 to 5, which is operated to open the flare gas line to the EGF.

By combining VDU and EGF, the present invention burns the flare gas with VDU when the concentration of combustible components in the flare gas is low, and burns the flare gas with EGF when the concentration of combustible components in the flare gas is high. Since it is combusted, the flare gas can be economically and efficiently combusted regardless of the combustible content concentration. In addition, since the switching between VDU and EGF is instantaneous based on the command of the information processing device, even if flare gas containing a large amount of combustible components is suddenly supplied due to an abnormality, etc., switching to EGF can be performed. Combustion treatment can be performed safely. On the other hand, when the concentration of combustibles in the flare gas is low and it is not possible to self-combust, it is possible to switch to VDU and perform combustion processing, so that combustion processing can always be performed with the minimum necessary amount of auxiliary fuel, which is convenient. is.

1 is a schematic configuration diagram of a flare gas combustion processing system according to Embodiment 1 of the present invention; FIG. FIG. 4 is an explanatory diagram showing the flow of fuel and the flow of flare gas when VDU is used in the flare gas combustion processing system of Embodiment 1 of the present invention; FIG. 4 is an explanatory diagram showing the flow of flare gas and the flow of fuel in the second stage when EGF is used in the flare gas combustion processing system of Embodiment 1 of the present invention; FIG. 4 is an explanatory diagram showing the flow of flare gas and the flow of fuel in the third stage when EGF is used in the flare gas combustion processing system of Embodiment 1 of the present invention; FIG. 4 is a flowchart showing the flow of processing when flare gas is increased in the flare gas combustion processing system according to Embodiment 1 of the present invention; FIG. FIG. 4 is a flowchart showing the flow of processing when flare gas is reduced in the flare gas combustion processing system according to Embodiment 1 of the present invention; FIG.

(Embodiment example 1)
BEST MODE FOR CARRYING OUT THE INVENTION A first embodiment according to the present invention will be described in detail below with reference to the accompanying drawings. However, the components described in this embodiment are merely examples, and the scope of the present invention is not limited to them.

<Configuration of flare gas combustion processing system>
FIG. 1 is a schematic configuration diagram of a flare gas combustion processing system according to Embodiment 1 of the present invention. The flare gas combustion processing system has VDU1 and EGF3. The VDU 1 has a cylindrical body 20 and has a cylindrical shape. Also, the EGF 3 has a cylindrical body 30 and has a columnar shape. In the first embodiment, the VDU 1 and the EGF 3 have a cylindrical configuration, but this is merely an example. For example, the VDU 1 and the EGF 3 may have a prismatic shape, and the shape is not limited. VDU1 and EGF3 play a role of a furnace (≈combustion chamber) for burning the supplied flare gas. Therefore, hereinafter, "VDU1" refers to a furnace that performs VDU as a combustion treatment method, and "EGF3" refers to a furnace that performs EGF as a combustion treatment method. VDU1 and EGF3 are also called a flare stack.

<Configuration of VDU1>
A plurality of air intake holes (not shown) are provided in the lower part of the VDU 1 , and each hole is covered with an air intake damper 21 . In addition, in Embodiment 1, a configuration in which a plurality of air intake holes are provided and a plurality of air intake dampers 21 are provided to cover the holes is shown, but the present invention is not limited to this configuration. A configuration may be adopted in which a single outside air intake hole is provided and the hole is covered with the air intake damper 21 .

Further, the VDU 1 is provided with an auxiliary burner 23 for maintaining a high-temperature atmosphere in the furnace, a flare burner A-1 for burning flare gas supplied into the furnace, and a pilot burner 14 . Furthermore, a temperature detection device 50 such as a thermocouple for detecting the temperature inside the VDU 1 is provided above the VDU 1 .

<Structure of EGF3>
The EGF 3 has a structure in which a cylindrical body 30 is supported by a plurality of pedestals 32 . Therefore, outside air (air) flows into the EGF 3 from the air intake zone 31 below the cylindrical body 30 through the space between the pedestals 32 . In addition, although the structure which supports the cylinder 30 by the column base 32 was shown in this Embodiment 1, the structure which supports the cylinder 30 is not limited to this structure. An air intake zone 31 is provided in the cylindrical body 30 , and any configuration may be employed as long as the outside air (air) can flow into the EGF 3 from the air intake zone 31 . For this reason, for example, the housing 30 may be integrally molded including the legs for supporting itself, and may be configured such that the cylindrical body 30 is provided with a plurality of holes as the air intake zones 31 .

Further, the EGF 3 is provided with flare burners B-1, C-1, D-1, . The pilot burner 14 associated with the VDU 1 and the pilot burner 15 associated with the EGF 3 are always supplied with fuel and burned in order to instantly ignite the supplied flare gas.

One end of a fuel line 10 is connected to the VDU 1 to supply fuel. More specifically, a fuel line 12 for supplying fuel to the pilot burner 14 of the VDU 1 and a VDU auxiliary burner fuel for supplying auxiliary fuel to the auxiliary burner 23 branched from the fuel line 11 for supplying fuel to the pilot burner 15 of the EGF 3. Two fuel lines, line 13, are connected to VDU1. In the middle of the fuel line 13 for the VDU auxiliary burner, an auxiliary fuel flow rate adjusting device 22 capable of adjusting the amount of the auxiliary fuel flowing through the fuel line 13 is provided.

One end of a fuel line 10 is also connected to the EGF 3 to supply fuel. Specifically, in order to supply fuel to each EGF pilot burner 15 installed corresponding to each flare gas burner such as flare gas burner B-1, C-1, D-1, ..., N-1, A branched fuel line 11 is connected to the EGF 3 .

One end of a flare gas line 40 is connected to each of VDU1 and EGF3 to receive supply of flare gas. More specifically, the flare gas line 40 branches midway into a VDU-oriented flare gas line 42 directed to VDU1 and a plurality of EGF-oriented flare gas lines 43, 44, 45, . . . Alternatively, it is connected to EGF3. A VDU/EGF flare gas switching device A capable of opening/blocking the flow of flare gas toward VDU1 and adjusting (controlling) the flow rate is provided in the middle of flare gas line 42 toward VDU1. Note that the VDU/EGF flare gas switching device A is, for example, a supply/shutoff valve.

The other end of flare gas line 40 is connected to combustible gas storage device 80 . Flare gas to be burned is stored in the combustible gas storage device 80, and the stored flare gas is discharged when the combustion process is performed. Also, the combustible gas storage device 80 is provided at a position sufficiently separated from the flare gas processing equipment such as the VDU 1 and the EGF 3 for ensuring safety. Therefore, one end and the other end of the flare gas line 40 are, for example, 100 m or longer. Therefore, it takes several seconds (≈2 or 3 seconds) or more for the flare gas flowing out of the combustible gas storage device 80 to reach the VDU1 or the EGF3.

As described above, the EGF 3 is provided with a plurality of flare burners B-1 to N-1. Therefore, in order to supply flare gas to each flare burner, the flare gas line 40 consists of flare gas lines 43, 44, 45, . branched together. EGF flare gas supply/shutoff devices B, C, D, . there is The EGF flare gas supply/shutoff devices B to N may be configured to open/shut off the flow of the flare gas toward the EGF 3 and adjust (control) the flow rate, and are, for example, supply/shutoff valves.

Further, the flare gas line 40 before branching is provided with a flare gas pressure detection device 60 for detecting the pressure of the flowing flare gas. When the B to N flare gas supply/switch operation arithmetic unit 61 recognizes that the flare gas pressure value detected by the flare gas pressure detection device 60 exceeds the set value, the EGF flare gas supply/cutoff device B, etc. is operated. Then, the flare gas line 43 and the like are opened to supply the EGF 3 with the flare gas. At the same time, when the integrated information processing device (not shown, described later) recognizes the operation of the EGF flare gas supply/cutoff device B, etc., by the B to N flare gas supply/switching operation arithmetic unit 61, the VDU/EGF flare gas switching operation arithmetic unit 71 , the VDU/EGF flare gas switching device A is operated to shut off the flare gas line 42 directed to the VDU1.

A safety valve detection device 70 is provided in the middle of the flare gas line 40 before branching. When the pressure inside the combustible gas storage device 80 becomes overpressure and the safety valve operates (opens), the safety valve detection device 70 detects the operation and outputs a signal to that effect to the VDU/EGF flare gas switching operation calculation device 71. do. Upon receiving the signal, the VDU/EGF flare gas switching operation arithmetic device 71 operates the VDU/EGF flare gas switching device A to close the flare gas line 42 directed to the VDU 1 and cut off the flow of flare gas. At the same time, when the integrated information processing device recognizes the operation of the VDU/EGF flare gas switching operation arithmetic device 71 for the VDU/EGF flare gas switching device A, the EGF flare gas supply/cutoff is performed through the B to N flare gas supply/switching operation arithmetic device 61. By operating the device B and the like, the flare gas line 43 and the like are opened to supply the EGF 3 with the flare gas.

The position on the flare gas line 40 where the safety valve detection device 70 is provided is before the branch and near the combustible gas storage device 80 (usually sufficiently far from the flare processing equipment for ensuring safety). , when the safety valve is actuated, the flare gas flowing out from the combustible gas storage device 80 reaches the flare gas line header 41 (or before it reaches the flare gas line header 41), VDU via the VDU/EGF flare gas switching operation arithmetic device 71 /EGF flare gas switching device A can be operated to close the flare gas line 42 toward VDU1. At the same time, the EGF flare gas supply/shutoff device B or the like can be operated via the integrated information processing device and the B to N flare gas supply/switching arithmetic device 61 to open the flare gas line 43 or the like and supply flare gas to the EGF 3 . As described above, in an emergency such as when the safety valve detection device 70 detects that the safety valve has opened, the supply destination of the flare gas can be switched to flow to the EGF 3 before the flare gas reaches the VDU 1, which is convenient.

This flare gas combustion processing system is entirely controlled using an information processing device such as a server. A detailed description will be given below.

The VDU 1 is provided with an auxiliary fuel adjustment arithmetic device 51 and an air intake damper opening adjustment device 52 as information processing devices. The auxiliary fuel adjustment arithmetic device 51, the air intake damper opening adjustment device 52, and the temperature detection device 50 are connected so as to be able to communicate with each other. Further, the auxiliary fuel adjustment arithmetic device 51 is connected to the auxiliary fuel flow rate adjustment device 22 so as to be able to communicate with each other. Furthermore, the air intake damper opening adjustment device 52 is connected to each air intake damper 21 so as to be able to communicate with each other.

The auxiliary fuel adjustment arithmetic device 51 detects the temperature in the VDU 1 through the temperature detection device 50, and based on the detected temperature, operates the auxiliary fuel flow rate adjustment device 22 to adjust the amount of auxiliary fuel to be supplied to the auxiliary combustion burner 23. Adjust. Also, the air intake damper opening adjustment device 52 detects the temperature inside the VDU 1 through the temperature detection device 50, and adjusts the opening of each air intake damper 21 based on the temperature.

The EGF 3 is provided with a B to N flare gas supply/switching operation computing device 61 and a VDU/EGF flare gas switching operation computing device 71 as information processing devices. Also, the B to N flare gas supply/switching operation arithmetic device 61 is connected to the EGF flare gas supply/shutoff devices B, C, D and N so as to be able to communicate with each other. Furthermore, the VDU/EGF flare gas switching operation arithmetic device 71 is connected to the VDU/EGF flare gas switching device A so as to be able to communicate with each other.

The B to N flare gas supply/switching operation computing device 61 detects the pressure of the flare gas flowing through the flare gas line 40 before flowing into the flare gas header 41 (=before branching) through the flare gas pressure detecting device 60, and detects the pressure , the EGF flare gas supply/shutoff devices B, C, D and N are operated to open or shut off the flare gas line 43 and adjust (control) the flow rate of the flare gas flowing through the flare gas line 43 and the like. In addition, the VDU/EGF flare gas switching operation arithmetic device 71 operates the VDU/EGF flare gas switching device A according to a command from the general information processing device to open, shut off, and flow through the flare gas line 42 . Controls the flare gas flow rate.

The auxiliary fuel adjustment arithmetic device 51, the air intake damper opening adjustment device 52, the B to N flare gas supply/switching operation arithmetic device 61, and the VDU/EGF flare gas switching operation arithmetic device 71 are each an integrated information processing device (not shown), They are connected so that they can communicate with each other. The integrated information processing device is higher than the auxiliary fuel adjustment arithmetic device 51, the air intake damper opening degree adjustment device 52, the B to N flare gas supply/switching operation arithmetic device 61, and the VDU/EGF flare gas switching operation arithmetic device 71, and It plays a role of centrally controlling the flare gas combustion processing system according to the first embodiment. Therefore, the integrated information processing device receives information and commands from the auxiliary fuel adjustment arithmetic device 51, the air intake damper opening adjustment device 52, the B to N flare gas supply/switching operation arithmetic device 61, and the VDU/EGF flare gas switching operation arithmetic device 71. Receive and output information and instructions to the auxiliary fuel adjustment arithmetic device 51, the air intake damper opening adjustment device 52, the B to N flare gas supply/switching operation arithmetic device 61, and the VDU/EGF flare gas switching operation arithmetic device 71. do.

<Processing flow of the flare gas combustion processing system>
Next, the processing flow of the flare gas combustion processing system according to the first embodiment will be described with reference to FIGS. 2 to 6. FIG. First, the flow of processing when the amount of flare gas increases is shown. As shown in FIGS. 2 and 5, the auxiliary fuel adjustment arithmetic device 51 operates the auxiliary fuel flow rate adjustment device 22 to supply the auxiliary fuel to the auxiliary combustion burner 23 provided in the VDU 1 through the fuel lines 10 and 13. to ignite and burn. Further, the auxiliary fuel adjustment arithmetic device 51 continuously detects the temperature inside the VDU 1 through the temperature detection device 50, and supplies the auxiliary fuel so as to raise the temperature of the VDU 1 from normal temperature to the set temperature 1 (step S501). ). Here, "set temperature 1" refers to a temperature (for example, approximately 400 to 600°C) at which combustible components in the flare gas ignite. When the general information processing device recognizes that the VDU 1 has reached the set temperature 1 from the information received from the auxiliary fuel adjustment arithmetic device 51, the general information processing device performs the VDU/EGF flare gas switching operation arithmetic device 71 as shown in FIG. , flare gas lines 40, 41 and 42 to supply flare gas into the VDU 1, and the flare gas flowing into the flare gas burner A-1 is ignited and burned by the pilot burner 14 for VDU. This is the first stage (≈1st stage).

The auxiliary fuel adjustment calculation device 51 operates the auxiliary fuel flow rate adjustment device 22 while continuing the supply and combustion of flare gas, adjusts the amount of fuel supplied to the flare gas burner A- 1, and adjusts the amount of fuel supplied to the flare gas burner A- 1, , the temperature inside the VDU1 is continuously detected to maintain the temperature of the VDU1 at or above the set temperature 1 (step S502). For example, it is maintained at 600-800°C. This is referred to as "set temperature 2". This "set temperature 2" is the temperature at which the flare gas decomposes and burns (=the temperature at which the generation of unburned matter can be minimized and the cylinder body 20, which is the combustion cylinder, does not deteriorate).

When the concentration of combustibles in the supplied flare gas (=the amount of combustible gas in the flare gas) increases and the temperature detection device 50 recognizes that the temperature of the VDU 1 has risen from the set temperature 2, the auxiliary fuel adjustment arithmetic unit 51 operates the auxiliary fuel flow rate adjusting device 22 to reduce the amount of auxiliary fuel supplied to the auxiliary burner 23 and lower the temperature inside the VDU 1 to the set temperature 2 (step S503).

When it recognizes that the temperature of the VDU 1 has risen from the set temperature 2 while the auxiliary fuel is reduced to the minimum amount that the auxiliary burner 23 can combust (=minimum flow rate), the air intake damper opening adjustment device 52 is activated. adjusts the opening degree of each air intake damper 21, takes in air from the outside into the VDU 1, and lowers the temperature inside the VDU 1 to the set temperature 2 (step S504). As a characteristic of the burner, it is usually determined by each burner, such as what percentage of the maximum flow rate (maximum combustion amount) is the minimum flow rate.

The concentration of combustibles in the supplied flare gas (=the amount of combustible gas in the flare gas) increases, and the general information processing device, according to the information received from the auxiliary fuel adjustment arithmetic unit 51, raises the temperature of VDU 1 to set temperature 3. When it is recognized that the temperature rises (for example, 1000° C.), the VDU/EGF flare gas switching operation arithmetic device 71 operates the VDU/EGF flare gas switching device A to completely close the flare gas line 42, and the flow of the flare gas is switched to EGF3. (step S505). Further, when the auxiliary fuel adjustment calculation device 51 recognizes that the temperature of the VDU 1 has risen to the set temperature 3 through the temperature detection device 50, the fuel is supplied to the auxiliary burner 23 through the VDU auxiliary burner fuel line 13. The amount of supplemental fuel is adjusted in response to the temperature rise of VDU1. When the set temperature is 3, the auxiliary fuel is adjusted to the minimum flow rate, and the temperature is lowered to the set temperature 1. The "set temperature 3" is the maximum temperature at which deterioration of the cylinder body 20, which is the combustion cylinder, does not occur during long-term operation.

As described above, in the flare gas fuel processing system according to the first embodiment, the concentration of combustible substances in the flare gas is low, and the flare gas that cannot self-combust is burned in the VDU1, and the auxiliary fuel is used to store the fuel in the VDU1. It is a configuration for forming a high-temperature atmosphere. Thereby, fluctuations in the concentration of combustible components in the flare gas can be grasped as temperature changes in the VDU1. Therefore, the temperature rise in the VDU 1 can be regarded as an increase in the concentration of combustible components in the flare gas, and can be dealt with by reducing the amount of auxiliary fuel to be supplied. As a result, it is possible to prevent the temperature inside the VDU 1 from becoming excessively high, and at the same time, to keep the amount of auxiliary fuel to be supplied to the minimum required.

Then, the concentration of combustibles in the supplied flare gas (=the amount of combustible gas in the flare gas) increases, and the auxiliary fuel is reduced to the minimum amount that the auxiliary burner 23 can combust (=minimum flow rate). When the temperature inside the VDU 1 rises to a preset temperature 2, the air intake damper 21 is opened to take air into the VDU 1 from the outside. In this way, the fact that the VDU 1 is configured to utilize natural draft (=take in air from the outside, also known as "natural suction") for cooling inside the furnace makes it possible to keep the amount of auxiliary fuel to the minimum necessary. It is a factor that can

In addition, the main role of the VDU 1 in the flare gas (combustion) processing system according to Embodiment 1 is to burn flare gas with a combustible content concentration that cannot self-combust, including flare gas with 100% non-combustible content. The VDU1 uses auxiliary fuel to create a high-temperature atmosphere in the furnace, and has a configuration in which fluctuations in the concentration of combustible components in the flare gas can be grasped as temperature changes in the furnace, and natural ventilation is used to cool the furnace. It is a system performed by Therefore, the size of VDU1 is sufficient as long as it has a capacity capable of playing the main role described above, and does not need to correspond to the maximum flare gas flow rate. In the case of a flare gas combustion processing system consisting only of VDUs with no EGF, VDU1 needs to be VDU+EGF in order to correspond to "maximum flow rate of flare gas x maximum calorific value".

Now, let us return to the processing flow of the flare gas combustion processing system. When the general information processing device recognizes that the temperature of the VDU 1 has risen to the set temperature 3 (for example, 1000° C.) from the information received from the auxiliary fuel adjustment arithmetic device 51, the VDU/EGF flare gas switching operation arithmetic device 71 performs The VDU/EGF flare gas switching device A is operated to completely close the flare gas line 42 (step S505). At the same time, as shown in FIG. 3, the general information processing device controls the EGF flare gas supply/cutoff device B provided in the middle of the flare gas line 43 toward the EGF 3 through the B to N flare gas supply/switching operation arithmetic unit 61. The flare gas line 43 is opened by operation (step S506), and the flare gas is flowed through the flare gas line 43 to the EGF flare burner B-1 for combustion treatment. This is the second stage (≈2nd stage). In this way, by simultaneously performing steps S505 and S506, the switching time from VDU1 to EGF3 is shortened.

Next, the B to N flare gas supply/switch operation arithmetic device 61 detects an increase in the combustible content in the flare gas and an increase in the flare gas pressure due to an increase in the flow rate of the flare gas (=preset flare gas pressure value or more) is recognized, as shown in FIG. Flare gas is passed through the gas line 44 to the EGF flare burner C-1 for combustion treatment. This is the third stage (≈3rd stage).

Similarly, the B to N flare gas supply/switching operation computing device 61 recognizes, through the flare gas pressure detector 60, a further increase in the combustible content in the flare gas and a further increase in the flare gas pressure accompanying a further increase in the flow rate of the flare gas. Then, not only the flare gas lines 43 and 44, but also the EGF flare gas supply/shutdown device D is operated in sequence to operate the flare gas line 45 (fourth stage, 4th stage, step S508) and the EGF flare gas supply/shutoff device N. Then, the flare gas line 4x is also opened (Nth stage, step S509).

Next, the flow of processing when the amount of flare gas is reduced is shown. When the B to N flare gas supply/switching operation arithmetic device 61 recognizes a decrease in flare gas pressure (becomes equal to or less than a preset flare gas pressure value) due to a decrease in flare gas flow rate through the flare gas pressure detection device 60, As shown in 6, the processing stage (the number of stages) is lowered sequentially from the EGF flare gas supply/cutoff device N (Nth stage, Nth stage). In other words, the EGF flare gas supply/shutdown device N is operated to close the flare gas line 4x to shut off the flare gas flow (Nth stage, step S601), and the EGF flare gas supply/shutdown device D is operated to close the flare gas line 45 to block the flow of flare gas (fourth stage, 4thstage, step S602), the EGF flare gas supply/cutoff device C is operated to close the flare gas line 44, The flow of flare gas is cut off (3rd stage, step S603).

Through the flare gas pressure detection device 60, the B to N flare gas supply/switching operation computing device 61 detects that the flare gas pressure has further decreased due to the further decrease in the flow rate of the flare gas (=becomes equal to or less than the preset value of the flare gas pressure). is recognized, the EGF flare gas supply/shutoff device B is operated to close the flare gas line 43 to shut off the flow of flare gas (second stage, 2nd stage, step S604), and stop the supply of flare gas to the EGF 3. .

At the same time, when the general information processing device recognizes that the supply of flare gas to the EGF 3 has been stopped from the information received from the B to N flare gas supply/switching operation arithmetic device 61, the VDU/EGF flare gas switching operation arithmetic device 71 , the VDU/EGF flare gas switching device A is operated to open the flare gas line 42 (step S605), and the flare gas is supplied to the VDU1. By simultaneously performing steps S604 and S605 in this manner, the switching time from EGF3 to VDU1 is shortened.

In the VDU1, a predetermined amount of auxiliary fuel is always supplied to the auxiliary burner 23, and the temperature inside the VDU1 is maintained at the set temperature 1. Therefore, when the flare gas is supplied to the flare burner A-1, combustion processing is performed. (step S606).

As described above, in the flare gas combustion processing system according to the first embodiment, by combining the VDU 1 and the EGF 3, when the concentration of combustible components in the flare gas is low, the flare gas is combusted by the VDU 1 and When the concentration of combustible components is high, the flare gas is burned by EGF 3, so the flare gas can be burned economically and efficiently regardless of the concentration of combustible components. Further, switching between VDU1 and EGF3 is instantaneously performed based on a command from an information processing device such as the VDU/EGF flare gas switching operation arithmetic device 71 or the like. Specifically, it takes several seconds to open/shut off the flare gas lines of the VDU/EGF flare gas switching device A and the EGF flare gas supply/shutoff device B, etc. Start the operation of the devices at the same time. Therefore, even if flare gas containing a large amount of combustible components is suddenly supplied due to an abnormality or the like, it is possible to instantaneously switch to EGF 3 and perform combustion processing safely. On the other hand, if the concentration of combustibles in the flare gas is low and it is not possible to self-combust, it is possible to switch to VDU1 and perform combustion processing, so that combustion processing can always be performed with the minimum necessary amount of auxiliary fuel, which is convenient. is. In general, when flare gas is burned only with EGF3, the cost of auxiliary fuel may cost several hundred million yen per year, but by combining VDU1 and EGF3, the cost can be reduced to several million yen per year, which is less than 10%. Can be compressed.

In the flare gas combustion system according to Embodiment 1, a configuration in which a plurality of flare gas lines 43, 44, 45, . It is sufficient that the number of flare gas lines directed to . Similarly, the number of flare burners and the number of EGF flare gas supply shutoff/shutoff devices provided in the EGF 3 may be matched with the processing stages (the number of stages) of the EGF 3 .

In addition, in the flare gas combustion system according to Embodiment 1, the general information processing device, the auxiliary fuel adjustment arithmetic device 51, the air intake damper opening adjustment device 52, the B to N flare gas supply/switching operation arithmetic device 61, and the VDU/ Although the configuration in which the five information processing devices such as the EGF flare gas switching operation arithmetic device 71 are provided independently has been shown, the configuration is not limited to this. For example, a configuration using a single information processing device having the functions of the auxiliary fuel adjustment calculation device 51 and the air intake damper opening degree adjustment device 52 may be used, or the B to N flare gas supply/switching operation calculation device 61 and VDU/EGF may be used. A single information processing device having the function of the flare gas switching operation arithmetic device 71 may be used. Alternatively, a single unit having the functions of a general information processing device, an auxiliary fuel adjustment arithmetic device 51, an air intake damper opening adjustment device 52, a B to N flare gas supply/switching operation arithmetic device 61, and a VDU/EGF flare gas switching operation arithmetic device 71 information processing apparatus.

A: VDU/EGF flare gas switching device, A-1: VDU flare gas burner, B: EGF flare gas supply cutoff device, C: EGF flare gas supply cutoff device, D: EGF flare gas supply cutoff device, N: EGF flare gas supply cutoff device,
1: VDU, 10: Fuel line, 11: EGF pilot burner fuel line, 12: VDU pilot burner fuel line, 13: VDU auxiliary burner fuel line, 14: Pilot burner, 15: Pilot burner, 20: VDU cylinder, 21: air intake damper, 22: auxiliary fuel flow control device, 23: auxiliary burner,
3: EGF, 30: EGF cylinder, 31: EGF air intake zone, 32: column base,
40: flare gas line, 41: flare gas header, 42: flare gas line for VDU, 43: flare gas line for EGF, 44: flare gas line for EGF, 45: flare gas line for EGF, 4x: flare for EGF gas line,
50: Temperature detection device 51: Auxiliary fuel adjustment arithmetic device 52: Air intake damper opening adjustment device 60: Flare gas pressure detection device 61: B to N flare gas supply/switching operation arithmetic device 70: Safety valve operation detection device , 71: VDU/EGF flare gas switching operation arithmetic device, 80: combustible gas storage device

In order to achieve the above object, the invention according to claim 1 is
A flare gas combustion processing system for burning flare gas,
The system includes a VDU and EGF, and an information processing device that controls the entire system,
One end of a flare gas line for supplying flare gas is connected to each of the VDU and the EGF,
A supply cutoff device for opening, blocking, and controlling the flow rate of the flare gas is provided in the middle of the flare gas line toward the VDU and in the middle of the flare gas line toward the EGF, respectively,
For flare gas that has a low combustible content concentration and cannot self-combust, it is combusted with the VDU,
When performing flare gas combustion processing in the VDU, the information processing device operates the supply cutoff device related to the EGF to close the flare gas line leading to the EGF,
When performing flare gas combustion processing in the EGF, the information processing device operates the supply cutoff device related to the VDU to close or control the flow rate of the flare gas line leading to the VDU. Flare gas combustion processing system.

Further, the invention according to claim 2 is
A flare gas combustion processing system for burning flare gas,
The system includes a VDU and EGF, and an information processing device that controls the entire system,
One end of a flare gas line for supplying flare gas is connected to each of the VDU and the EGF,
A supply cutoff device for opening, blocking, and controlling the flow rate of the flare gas is provided in the middle of the flare gas line toward the VDU and in the middle of the flare gas line toward the EGF, respectively,
When performing flare gas combustion processing in the VDU, the information processing device operates the supply cutoff device related to the EGF to close the flare gas line leading to the EGF,
When performing flare gas combustion processing in the EGF, the information processing device operates the supply cutoff device related to the VDU to close or control the flow rate of the flare gas line toward the VDU,
When the temperature in the VDU is equal to or higher than a preset temperature, the information processing device operates the supply cutoff device related to the VDU to close or control the flow rate of the flare gas line toward the VDU. and a flare gas combustion processing system for opening a flare gas line directed to the EGF by operating the supply cutoff device associated with the EGF .

Further, the invention of claim 3 is
A flare gas combustion processing system for burning flare gas,
The system includes a VDU and EGF, and an information processing device that controls the entire system,
One end of a flare gas line for supplying flare gas is connected to each of the VDU and the EGF,
A supply cutoff device for opening, blocking, and controlling the flow rate of the flare gas is provided in the middle of the flare gas line toward the VDU and in the middle of the flare gas line toward the EGF, respectively,
When performing flare gas combustion processing in the VDU, the information processing device operates the supply cutoff device related to the EGF to close the flare gas line leading to the EGF,
When performing flare gas combustion processing in the EGF, the information processing device operates the supply cutoff device related to the VDU to close or control the flow rate of the flare gas line toward the VDU,
When the flow rate of the flare gas drops below a preset value of the flare gas pressure, the information processing device operates the supply cutoff device related to the EGF to cut off the flare gas line toward the EGF. A flare gas combustion processing system is provided in which the flare gas line leading to the VDU is opened or the flow rate is controlled by operating the supply cutoff device associated with the VDU while closing the flare gas line .

Further, the invention of claim 4 is
A flare gas combustion processing system for burning flare gas,
The system includes a VDU and EGF, and an information processing device that controls the entire system,
One end of a flare gas line for supplying flare gas is connected to each of the VDU and the EGF,
A supply cutoff device for opening, blocking, and controlling the flow rate of the flare gas is provided in the middle of the flare gas line toward the VDU and in the middle of the flare gas line toward the EGF, respectively,
When performing flare gas combustion processing in the VDU, the information processing device operates the supply cutoff device related to the EGF to close the flare gas line leading to the EGF,
When performing flare gas combustion processing in the EGF, the information processing device operates the supply cutoff device related to the VDU to close or control the flow rate of the flare gas line toward the VDU,
The other end of the flare gas line is connected to a combustible gas storage device in which flare gas is stored and provided with a safety valve that operates when overpressure occurs,
The flare gas line has a length from one end to the other end that takes at least several seconds for the flare gas flowing out from the other end to reach the one end,
A safety valve detection device for detecting the operation of the safety valve is provided in the middle of the flare gas line near the combustible gas storage device,
When the internal pressure of the combustible gas storage device reaches an overpressure state and the safety valve operates, the safety valve detection device detects the operation and outputs a signal to that effect to the information processing device,
When the information processing device receives the signal, the information processing device operates the supply cutoff device related to the VDU, closes or controls the flow rate of the flare gas line heading to the VDU, and cuts the supply cutoff device related to the EGF. A flare gas combustion treatment system is operated to open the flare gas line to the EGF .

Further, the invention of claim 5 is
The VDU is provided with an air intake damper that takes in air from the outside,
The information processing device controls the amount of auxiliary fuel when the temperature in the VDU rises to a preset temperature or higher,
Even if the amount of auxiliary fuel is controlled, when the temperature inside the VDU is equal to or higher than a preset temperature, the air intake damper is opened to take air from the outside into the VDU by natural suction . 5. The flare gas combustion treatment system according to any one of 4 above.

<Structure of EGF3>
The EGF 3 has a structure in which a cylindrical body 30 is supported by a plurality of pedestals 32 . Therefore, outside air (air) flows into the EGF 3 from the air intake zone 31 below the cylindrical body 30 through the space between the pedestals 32 . In addition, although the structure which supports the cylinder 30 by the column base 32 was shown in this Embodiment 1, the structure which supports the cylinder 30 is not limited to this structure. An air intake zone 31 is provided in the cylindrical body 30 , and any configuration may be employed as long as the outside air (air) can flow into the EGF 3 from the air intake zone 31 . Therefore, for example, the tubular body 30 may be integrally molded including the legs that support itself, and may be configured to have a plurality of holes as the air intake zones 31 in the tubular body 30 .

One end of a fuel line 10 is also connected to the EGF 3 to supply fuel. Specifically, in order to supply fuel to each EGF pilot burner 15 installed corresponding to each flare burner such as flare burners B-1, C-1, D-1 . A fuel line 11 is connected to the EGF 3 .

The position on the flare gas line 40 where the safety valve detection device 70 is provided is before the branch and near the combustible gas storage device 80 (usually sufficiently far from the flare gas processing equipment for ensuring safety). Therefore, when the safety valve is activated, when the flare gas flowing out from the combustible gas storage device 80 reaches the flare gas line header 41 (or before reaching), the VDU /EGF flare gas switching operation arithmetic device 71 is operated to VDU /EGF flare gas switching device A can be operated to close the flare gas line 42 toward VDU1. At the same time, the EGF flare gas supply/shutoff device B or the like can be operated via the general information processing device and the B to N flare gas supply/switching operation arithmetic device 61 to open the flare gas line 43 and the like and supply flare gas to the EGF 3 . As described above, in an emergency such as when the safety valve detection device 70 detects that the safety valve has opened, the supply destination of the flare gas can be switched to flow to the EGF 3 before the flare gas reaches the VDU 1, which is convenient.

The B to N flare gas supply/switching operation computing device 61 detects the pressure of the flare gas flowing through the flare gas line 40 before flowing into the flare gas line header 41 (=before branching) through the flare gas pressure detecting device 60, and detects the pressure , the EGF flare gas supply/shutoff devices B, C, D and N are operated to open or shut off the flare gas line 43 and adjust (control) the flow rate of the flare gas flowing through the flare gas line 43 and the like. In addition, the VDU/EGF flare gas switching operation arithmetic device 71 operates the VDU/EGF flare gas switching device A according to a command from the general information processing device to open, shut off, and flow through the flare gas line 42 . Controls the flare gas flow rate.

<Processing flow of the flare gas combustion processing system>
Next, the processing flow of the flare gas combustion processing system according to the first embodiment will be described with reference to FIGS. 2 to 6. FIG. First, the flow of processing when the amount of flare gas increases is shown. As shown in FIGS. 2 and 5, the auxiliary fuel adjustment arithmetic device 51 operates the auxiliary fuel flow rate adjustment device 22 to supply the auxiliary fuel to the auxiliary combustion burner 23 provided in the VDU 1 through the fuel lines 10 and 13. to ignite and burn. Further, the auxiliary fuel adjustment arithmetic device 51 continuously detects the temperature inside the VDU 1 through the temperature detection device 50, and supplies the auxiliary fuel so as to raise the temperature of the VDU 1 from normal temperature to the set temperature 1 (step S501). ). Here, "set temperature 1" refers to a temperature (for example, approximately 400 to 600°C) at which combustible components in the flare gas ignite. When the general information processing device recognizes that the VDU 1 has reached the set temperature 1 from the information received from the auxiliary fuel adjustment arithmetic device 51, the general information processing device performs the VDU/EGF flare gas switching operation arithmetic device 71 as shown in FIG. , flare gas lines 40, 41 and 42 to supply flare gas into VDU1, and the flare gas flowing into flare burner A-1 is ignited and burned by pilot burner 14 for VDU. This is the first stage (≈1st stage).

The auxiliary fuel adjustment arithmetic device 51 operates the auxiliary fuel flow rate adjustment device 22 while continuing the supply and combustion of the flare gas to adjust the amount of fuel supplied to the flare burner A-1, and through the temperature detection device 50, The temperature inside the VDU1 is continuously detected to maintain the temperature of the VDU1 at or above the set temperature 1 (step S502). For example, it is maintained at 600-800°C. This is referred to as "set temperature 2". This "set temperature 2" is the temperature at which the flare gas decomposes and burns (=the temperature at which the generation of unburned matter can be minimized and the cylinder body 20, which is the combustion cylinder, does not deteriorate).

In the flare gas combustion processing system according to Embodiment 1, a configuration in which a plurality of flare gas lines 43, 44, 45, . The number of flare gas lines leading to the EGF3 should match the processing stages (the number of stages) of the EGF3. Similarly, the number of flare burners and the number of EGF flare gas supply /shutoff devices provided in the EGF 3 may be matched with the processing stages (the number of stages) of the EGF 3 .

A: VDU/EGF flare gas switching device, A-1: VDU flare burner, B: EGF flare gas supply cutoff device, C: EGF flare gas supply cutoff device, D: EGF flare gas supply cutoff device, N: EGF flare gas supply cutoff device,
1: VDU, 10: Fuel line, 11: EGF pilot burner fuel line, 12: VDU pilot burner fuel line, 13: VDU auxiliary burner fuel line, 14: Pilot burner, 15: Pilot burner, 20: VDU cylinder, 21: air intake damper, 22: auxiliary fuel flow control device, 23: auxiliary burner,
3: EGF, 30: EGF cylinder, 31: EGF air intake zone, 32: column base,
40: flare gas line, 41: flare gas line header, 42: flare gas line for VDU, 43: flare gas line for EGF, 44: flare gas line for EGF, 45: flare gas line for EGF, 4x: flare for EGF gas line,
50: Temperature detection device 51: Auxiliary fuel adjustment arithmetic device 52: Air intake damper opening adjustment device 60: Flare gas pressure detection device 61: B to N flare gas supply/switching operation arithmetic device 70: Safety valve operation detection device , 71: VDU/EGF flare gas switching operation arithmetic device, 80: combustible gas storage device

Claims (6)

A flare gas combustion processing system for burning flare gas,
The system includes a VDU and EGF, and an information processing device that controls the entire system,
One end of a flare gas line for supplying flare gas is connected to each of the VDU and the EGF,
A supply cutoff device for opening, blocking, and controlling the flow rate of the flare gas is provided in the middle of the flare gas line toward the VDU and in the middle of the flare gas line toward the EGF, respectively,
When performing flare gas combustion processing in the VDU, the information processing device operates the supply cutoff device related to the EGF to close the flare gas line leading to the EGF,
When performing flare gas combustion processing in the EGF, the information processing device operates the supply cutoff device related to the VDU to close or control the flow rate of the flare gas line leading to the VDU. and flare gas combustion treatment system. 2. The flare gas combustion treatment system according to claim 1, wherein the flare gas, which has a low combustible component concentration and cannot self-combust, is combusted by the VDU. The VDU is provided with an air intake damper that takes in air from the outside,
The information processing device controls the amount of auxiliary fuel when the temperature in the VDU rises to a preset temperature or higher,
Even if the amount of auxiliary fuel is controlled, when the temperature inside the VDU is higher than a preset temperature, the air intake damper is opened to take air from the outside into the VDU by natural suction. The flare gas combustion treatment system according to claim 1 or 2. When the temperature in the VDU is equal to or higher than a preset temperature, the information processing device operates the supply cutoff device related to the VDU to close or control the flow rate of the flare gas line toward the VDU. 4. The flare gas combustion processing system according to any one of claims 1 to 3, wherein said supply cutoff device associated with said EGF is operated to open a flare gas line directed to said EGF. When the flow rate of the flare gas drops below a preset value of the flare gas pressure, the information processing device operates the supply cutoff device related to the EGF to cut off the flare gas line toward the EGF. The flare gas combustion according to any one of claims 1 to 4, characterized in that the flare gas line directed to the VDU is opened or flow rate is controlled by operating the supply cutoff device associated with the VDU while closing the flare gas line. processing system. The other end of the flare gas line is connected to a combustible gas storage device in which flare gas is stored and provided with a safety valve that operates when overpressure occurs,
The flare gas line has a length from one end to the other end that takes at least several seconds for the flare gas flowing out from the other end to reach the one end,
A safety valve detection device for detecting the operation of the safety valve is provided in the middle of the flare gas line near the combustible gas storage device,
When the internal pressure of the combustible gas storage device reaches an overpressure state and the safety valve operates, the safety valve detection device detects the operation and outputs a signal to that effect to the information processing device,
When the information processing device receives the signal, the information processing device operates the supply cutoff device related to the VDU, closes or controls the flow rate of the flare gas line heading to the VDU, and cuts the supply cutoff device related to the EGF. The flare gas combustion treatment system according to any one of claims 1 to 5, which is operable to open a flare gas line to said EGF.

Images