KR20220069768A - Direct combustion calorimetry system of flare gas - Google Patents

Abstract

The present invention comprises: an extraction unit which is provided on a pipe through which flare gas flows and which samples the flare gas; a combustion unit which receives the flare gas extracted by the extraction unit and burns the same; and a calorific value calculation unit which calculates a calorific value of the flare gas burned in the combustion unit. The extraction unit extracts the flare gas while being installed on a vent provided on the pipe.

Description

DIRECT COMBUSTION CALORIMETRY SYSTEM OF FLARE GAS

The present invention relates to a direct combustion calorimetry system for flare gas, and more particularly, to a direct combustion calorimetry system for flare gas configured to measure the calorific value of flare gas moving along a pipeline with high accuracy. will be.

In general, flare gas is a waste gas generated from an oil refinery or petrochemical plant, and it means a volatile and combustible gas. It consists of a plurality of pipelines (pipes) that become A flare system comprising a flare stack for burning and discharging, a seal drum for preventing an accident from occurring due to a flame flowing back from the flare stack, and the like is provided.

Accordingly, the flare gas is discharged to the outside through an exhaust and waste gas treatment device called a flare stack. That is, the flare gas may be delivered to the flare stack through a pipe, and may be combusted in the flare stack and discharged to the atmosphere.

Since the flare stack is connected to a plurality of pipes and receives the flare gas, it is sensitively affected by fluctuations in the internal pressure of the pipe. In other words, various factors such as the combustion efficiency of the flare gas by the flare stack and the structural stability of the flare stack are affected by the internal pressure of the pipe or the flow state of the flare gas.

Therefore, the flow rate of the flare gas flowing along the pipe is measured, and the problem that may occur in the flare stack is prevented in advance by detecting the abnormality of the pipe or the leakage of the flare gas according to the measured result. can be said to be very important.

Recently, due to laws for the atmospheric environment, interest in not only the flow rate of the flare gas discharged from the flare stack but also the calorific value of the flare gas is increasing. In other words, the environmental law that continuously measures the calorific value of the gas emitted from the flare stack to reduce carbon dioxide emissions and fine dust will come into effect from 2024.

Therefore, there is a need to monitor the calorific value of the flare gas in real time and change the operating conditions of an oil refinery or a petrochemical plant based on the result.

Conventionally, a method of analyzing the components of the flare gas flowing along the pipe by taking a sample, calculating the unit calorie value for each component, or measuring the amount of heat by directly burning the collected flare gas has been used. . However, this method has problems in that the process is complicated and cumbersome, and the calorific value of the flare gas cannot be measured in real time.

In particular, the method of directly burning the flare gas is performed after collecting the flare gas from a separate branch pipe (branch pipe) provided in the pipe through which the flare gas flows. In this method, only the flare gas flowing along the inner wall of the pipe Since it is collected through a branch pipe, there is a problem in that the calorific value of the flare gas composed of various components cannot be accurately measured.

Meanwhile, in order to accurately measure the calorific value of the flare gas in real time, the flow rate of the flare gas must be accurately measured. However, since the flare gas is a mixed gas generated in various processes, it is difficult to accurately determine the composition thereof, so that the accuracy of the flow rate value is deteriorated.

Conventionally, at the site where the actual flare system is installed, it is difficult to know the composition of the flare gas flowing along the pipe, and the density value of the flare gas according to the pressure in the pipe also fluctuates frequently. There is a problem in that the flow rate value of the gas is different, and consequently, the calorific value of the gas discharged from the flare stack is inaccurate.

Accordingly, the present applicant has proposed the present invention to solve the above problems, and as a related prior art document, there is a 'calorimetric system of natural gas' of Korean Patent Registration No. 10-1423566.

In order to solve the above problems, the present invention provides a direct combustion calorimetric measurement system of a flare gas configured to accurately measure the calorific value of the flare gas by separately burning the sampled flare gas and the calibration gas. there is a purpose to

Another object of the present invention is to provide a direct continuous calorimetry system for a flare gas configured to measure the calorific value after sampling the flare gas containing various components.

The present invention is provided in a pipe through which the flare gas flows, the extraction unit for sampling the flare gas; a combustion unit receiving and burning the flare gas extracted by the extraction unit; and a calorific value calculating unit for calculating the calorific value of the flare gas burned in the combustion unit, wherein the extractor may extract the flare gas while being mounted on a vent provided in the pipe.

In addition, the calibration gas supply unit for supplying the calibration gas to the combustion unit; and a calibration unit for calculating a calibration value of the calorific value calculation unit based on the calorific value of the calibration gas burned in the combustion unit by the calibration gas supply unit.

In addition, the calibration gas supply unit may supply the calibration gas in a state connected to a flare gas flow pipe connecting the extraction unit and the combustion unit to each other or supply the calibration gas in a state directly connected to the combustion unit. .

In addition, the calibration unit, the calorific value of the calorific value calculator can be calculated by comparing and analyzing the theoretical calorific value of the calibration gas supplied from the calibration gas supply unit and the calorific value of the calibration gas actually measured by the calorific value calculating unit.

In addition, the extractor may sample the flare gas flowing along the inner central portion of the pipe in a state in which it is mounted on a vent provided in the pipe.

In addition, the extraction unit, a sampling bar into which the lower end in the longitudinal direction is inserted into the pipe; a velocity measuring unit for measuring the velocity of the flare gas while being connected to the sampling bar; a density measuring unit for measuring the density of the flare gas while being connected to the sampling bar; and a flow rate analyzer for calculating the flow rate of the flare gas based on the value measured by the speed measuring unit and the density measuring unit, and storing and analyzing the calculated flow rate.

In addition, the sampling bar may include a round surface disposed to face the flow direction of the flare gas; a chamfer provided on the back side of the round surface; and a vertical surface that partitions the chamfer but connects both ends of the round surface in the width direction to each other.

In addition, the velocity of the flare gas measured by the velocity measuring unit is calculated using a pressure difference generated due to the flow of the flare gas, and the velocity measuring unit is a length of the first pressure sphere formed on the round surface. a first pipe to which one end of the direction is communicatively connected; a second pipe having one end in the longitudinal direction connected to the second pressure port formed on the vertical surface to be in communication; and the other longitudinal end of the first pipe and the other longitudinal end of the second pipe, and is communicatively connected to the flare gas using the pressure difference between the pressure generated in the first pipe and the pressure generated in the second pipe. It may include; a first sensor unit for measuring the speed.

In addition, the density measuring unit may include: a third pipe having one end in the longitudinal direction connected to the gas inlet formed in the round surface to be communicatively connected; a fourth pipe having one longitudinal end communicatively connected to a gas outlet formed on a circumferential surface of the sampling bar; and a second sensor unit connected in communication with the other longitudinal end of the third pipe and the other longitudinal end of the fourth pipe, and measuring the density of the flare gas flowing in through the third pipe; may include .

In addition, the combustion unit may receive the flare gas passed through the density measuring unit and burn it.

The direct combustion calorific value measurement system of the flare gas according to the present invention enables to check the calorific value of the flare gas discharged from the flare stack in real time, such as an oil refinery or a petrochemical plant. Conditions can be easily changed to avoid air pollution.

In addition, since the direct combustion calorific value measurement system of the flare gas according to the present invention measures the calorific value by extracting and burning the flare gas flowing along the inner center of the pipe, the calorific value is inaccurate due to the flow rate and density of the flare gas can be prevented from being measured.

In addition, the direct combustion calorific value measurement system of the flare gas according to the present invention provides a configuration for supplying and burning a calibration gas having a known theoretical calorific value in order to calibrate the calorific value calculator for calculating the calorific value of the flare gas, so that the flare gas It can be easily identified whether the calorific value of the flare gas is being measured with high precision, and the calorific value of the flare gas can be obtained with high accuracy by performing a correction operation accordingly.

In addition, the direct combustion calorimetry system of the flare gas according to the present invention measures the speed of the flare gas in a pressure calculation method that is not affected by the turbulence/laminar flow according to the flow rate of the flare gas, and uses the speed value to measure the flare gas Since it has a configuration for calculating the flow rate of , it is possible to accurately calculate the amount of heat of the flare gas by applying the flow rate value of the flare gas measured with high accuracy.

In addition, the direct combustion calorific value measurement system of the flare gas according to the present invention is applied to various points of the pipeline provided and piped at the flare gas outlet and has a configuration capable of simultaneously measuring the flow rate and heat amount, so that at multiple points By comprehensively analyzing the measured data, it is possible to finally derive the flow rate and heat quantity of the flare gas with high accuracy.

In addition, the direct combustion calorific value measurement system of the flare gas according to the present invention is applied to various points of the pipeline provided and piped at the flare gas outlet and has a configuration capable of simultaneously measuring the flow rate and heat amount, so that at multiple points By comprehensively analyzing the measured data, it is possible to accurately identify gas leak points, pipe breakage points, and uneven pressure sections. Conditions can be provided as reference data.

1 is a view showing the configuration of a direct combustion calorimetry system for flare gas according to the present invention.
2 is a view showing the configuration of an extractor according to an embodiment of the present invention.
3 is an enlarged perspective view of a region A of the sampling bar shown in FIG. 2;
FIG. 4 is a view showing an internal view of a region A of the sampling bar shown in FIG. 3;
5 is a view showing a first sensor unit and a second sensor unit of the extraction unit according to the present invention.
6 is a plan cross-sectional view of the lower end of the sampling bar shown in FIG. 3 viewed from above;
7 is a view showing the configuration of a direct combustion calorimetry system for flare gas according to another embodiment of the present invention.

Advantages and features of the present invention and methods of achieving them will become apparent with reference to the embodiments described below in detail in conjunction with the accompanying drawings.

However, the present invention is not limited to the embodiments disclosed below, but will be embodied in various different forms, and only these embodiments allow the disclosure of the present invention to be complete, and common knowledge in the art to which the present invention pertains It is provided to fully inform those who have the scope of the invention, and the present invention is only defined by the scope of the claims.

Hereinafter, a direct combustion calorimetry system for flare gas according to an embodiment of the present invention will be described in detail with reference to FIGS. 1 to 7 . In describing the present invention, detailed descriptions of related well-known functions or configurations are omitted so as not to obscure the gist of the present invention.

The direct combustion calorific value measurement system 100 of the flare gas according to an embodiment of the present invention measures the calorific value of the flare gas at various points in a pipeline through which the flare gas flows in real time, and, in addition, the calorific value of the flare gas It is characterized in that it is configured so that it can be determined whether or not it is being measured accurately.

The calorimetry system 100, as shown in FIGS. 1 and 2,

an extraction unit 200 provided in a pipe P through which the flare gas flows and sampling the flare gas; a combustion unit 300 for receiving and burning the flare gas extracted by the extraction unit 200; Calibration gas supply unit 400 for supplying calibration gas to the combustion unit 300; a calorific value calculating unit 500 for calculating the calorific value of the gas burned in the combustion unit 300; and a calibration unit 600 for calculating a calibration value of the calorific value calculating unit 500 based on the calorific value of the calibration gas burned in the combustion unit 300 and the calorific value of the flare gas; .

The extraction unit 200 may be a component for extracting the flare gas flowing along the pipe (P) to the outside of the pipe (P). In other words, it may be provided at one point in the longitudinal direction of the pipe (P), and may be referred to as a component for extracting the flare gas flowing along the inside of the pipe (P).

The combustion unit 300 may be a component that receives and burns the flare gas extracted to the extraction unit 200 . That is, the combustion unit 300 may include a combustion chamber and a burner for burning the gas stored in the chamber. For reference, the combustion chamber is connected to the extraction unit 200 through a separate flow pipe.

The calibration gas supply unit 400 may supply a gas having a theoretical calorific value to the combustion unit 300 . For example, the calibration gas supply unit 400 may supply a butane gas or a propane gas to the combustion unit 300 .

The calibration gas supply unit 400 is directly connected to the flare gas flow pipe connecting the extraction unit 200 and the combustion unit 300 to each other, or is directly connected to the chamber of the continuous unit 300 for calibration. gas can be supplied. For reference, in one embodiment of the present invention, as shown in FIG. 2 , the calibration gas supply unit 400 is illustrated as being directly connected to the combustion unit 300 .

The calorific value calculating unit 500 may measure the calorific value of the flare gas burned in the combustion unit 300 . In addition, the calorific value calculation unit 500 may measure the calorific value of the calibration gas burned in the combustion unit 300 when the calibration gas is supplied to the combustion unit 300 .

The calorific value of the flare gas flowing along the pipe (P) line may be calculated by burning the flare gas extracted by the extraction unit 200 in the combustion unit 300 .

Therefore, based on the calorific value data calculated by the calorific value calculation unit 500, the calorific value of the flare gas flowing along the pipe (P) line constituting the flare system can be grasped in real time, and in addition, based on the calorific value data It is possible to control the operating conditions of the flare system.

On the other hand, the calibration unit 600, together with the calibration gas supply unit 400, the calorific value calculation unit 500 is a component for determining whether the calorific value of the flare gas burned in the combustion unit 300 is accurately measured. can be said

The calibration unit 600 compares and analyzes the theoretical calorific value of the calibration gas supplied to the combustion unit 300 from the calibration gas supply unit 400 and the calorific value of the calibration gas actually measured by the calorific value calculating unit 500 , A calibration value of the calorific value calculator may be calculated.

In other words, the calibration unit 600 compares and analyzes the actual measured calorific value of the calibration gas burned in the combustion unit 300 and the theoretical calorific value of the calibration gas, and based on this data, the calorific value calculation unit 500 can be corrected.

For example, the calibration unit 600, when the calorific value of the calibration gas actually measured by the calorific value calculating unit 500 is less than or exceeding the theoretical calorific value, the calorific value calculating unit 500 may be calibrated.

Accordingly, the calorific value calculation unit 500 may measure the calorific value of the flare gas burned in the combustion unit 300 by the calibration gas supply unit 400 and the calibration unit 600 with high accuracy.

For reference, in an embodiment of the present invention, it has been described that the flare gas is burned or the calibration gas is burned in one combustion unit 300 , but the present invention is not limited thereto. For example, the calorific value measurement system 100 according to the present invention includes a combustion chamber for burning the calibration gas supplied to the combustion unit 300 in order to calibrate the calorific value calculating unit 500 , and the extraction unit 200 . ) may be separately equipped with a combustion chamber for burning the extracted flare gas. That is, a separate combustion unit for burning the calibration gas may be further provided. At this time, the chamber of the combustion part for burning the flare gas and the chamber of the combustion part for burning the calibration gas naturally have the same volume and can be said to have the same combustion conditions.

On the other hand, the extraction unit 200 according to an embodiment of the present invention, it is preferable to extract the flare gas flowing along the inner central portion of the pipe (P).

Because, if any one of the various types of gases constituting the flare gas occupies an exceptionally large proportion, a phenomenon may occur in which the calorific value of the flare gas cannot be detected with high accuracy.

More specifically, the flare gas flowing along the pipe P may be a mixture of gases generated in various processes. Accordingly, each gas constituting the flare gas may flow in an irregular flow inside the pipe P due to its specific gravity or properties. If the extraction unit 200 extracts only the flare gas flowing along the inner wall of the pipe P, the extracted flare gas has a high probability that it contains only some gas components, so the calorific value of the flare gas may be inaccurate.

Therefore, in order to extract the flare gas containing various gas components and to calculate a high and accurate calorific value, it is preferable that the extraction unit 200 extracts the flare gas flowing along the inner central portion of the pipe P.

The extraction unit 200 may have the following configuration in view of the above.

The extraction unit 200 includes, as shown in FIGS. 2 to 5 , a sampling bar 210 into which a lower end portion in the longitudinal direction is inserted into the pipe (P); a velocity measuring unit 220 for measuring the velocity of the flare gas while being connected to the sampling bar 210; a density measuring unit 230 for measuring the density of the flare gas while being connected to the sampling bar 210; and a flow rate analyzer 240 for calculating the flow rate of the flare gas based on the value measured by the speed measuring unit 220 and the density measuring unit 230, and storing and analyzing the calculated flow rate. can do.

The sampling bar 210 has a vertical bar shape as a whole, and may be inserted in a vertical direction crossing the longitudinal direction of the pipe P through a vent B having a relatively small diameter.

A case (not shown) in which the first sensor unit 221 of the speed measuring unit 220 and the second sensor unit 231 of the density measuring unit 230, which will be described later, are built in an upper end of the sampling bar 210 is provided The upper end of the sampling bar 210 including this case may be a component disposed to be exposed to the outside of the pipe (P).

The lower end of the sampling bar 210, as shown in Figs. 3 and 4, a circular arc-shaped round surface 211 disposed to face the flow direction (A) of the flare gas; a chamfer 212 provided with a predetermined depth on the rear side of the round surface 211; and a vertical surface 213 partitioning the chamfer 212 and connecting both ends of the round surface 211 in the width direction to each other.

That is, the lower part of the sampling bar 210 in the form of a vertical bar having an overall circular cross section may have a 'C' shape cut out, and the lower part is used to measure the speed and density of the flare gas substantially. It can be said to be a part of

The round surface 211 may be disposed to face the flow direction A of the flare gas with a semicircular curvature. That is, when the lower end of the sampling bar 210 is inserted into the pipe P through the vent B provided in the pipe P, the round surface 211 is arranged to face the flow direction of the flare gas. have.

In addition, a first pressure sphere h1 for measuring the velocity of the flare gas may be formed on the round surface 211 , and the first pressure sphere h1 is a longitudinal stop portion of the round surface 211 . can be placed in

In addition, a gas inlet h2 for measuring the density of the flare gas may be formed in an upper portion of the round surface 211 where the chamfer 212 is not provided, and the gas inlet h2 is the first It may be disposed on a position that does not interfere with the pressure port h1.

The chamfer 212 is, as described above, a vertical surface 213 connecting both ends of the round surface 211 in the width direction to each other, and a horizontal surface extending in the horizontal direction from the top and bottom of the vertical surface 213, respectively. (131d) can be demarcated.

On the other hand, a second pressure port h3 for measuring the velocity of the flare gas may be formed on the vertical surface 213 , and the second pressure port h3 is disposed at a longitudinal stop portion of the vertical surface 213 . can be

For reference, the first pressure sphere h1 formed on the round surface 211 may be a hole for measuring the voltage at the point where the sampling bar 210 is inserted into the pipe P. Conversely, the vertical surface The second pressure port h3 formed in the 213 may be a hole for measuring the static pressure at the point where the sampling bar 210 is inserted into the pipe P.

As described above, the first pressure port h1 is provided on the round surface 211 facing the flow direction (A) of the flare gas, and the second pressure port (h1) is provided on the vertical surface 213 opposite to the round surface 211 ( The reason for forming h3) is that, as shown in FIG. 6 , a vortex generated when the flare gas comes into contact with the round surface 211 flows in the direction in which the vertical surface 213 is arranged, so that the second This is to prevent inflow into the pressure port h3. That is, this is to prevent the flare gas flowing after contacting the round surface 211 from flowing in the direction in which the second pressure port h3 is formed so that the second pressure port h3 can accurately measure the static pressure. .

Accordingly, the first pressure port h1 is preferably formed on the round surface 211 for branching the flare gas in both directions, and the second pressure port h3 is branched by the round surface 211 to flow. It is preferably formed on the vertical surface 213 that is not affected by the flare gas.

Meanwhile, a gas outlet h4 may be provided at the lower end of the sampling bar 210 where the chamfer 212 is not formed.

As shown in FIGS. 4 and 5 , the speed measuring unit 220 includes a first pipe L1 having one end in the longitudinal direction connected to the first pressure port h1 formed on the round surface 211 to be communicatively connected. ); a second pipe (L2) whose one end in the longitudinal direction is communicatively connected to the second pressure port (h3) formed on the vertical surface (213); and the other longitudinal end of the first pipe (L1) and the other longitudinal end of the second pipe (L3) are connected in communication with the pressure generated in the first pipe (L1) and the second pipe (L2) The first sensor unit 221 for measuring the speed of the flare gas by using the differential pressure of the pressure generated in the 221; may include.

The first pipe L1 and the second pipe L2 may be provided inside the sampling bar 210 in a longitudinal direction of the sampling bar 210 .

One longitudinal end, that is, the lower end of the first pipe L1, is connected to be in communication with the first pressure port h1 as described above, and the other longitudinal end, that is, the upper end, is the first sensor unit 221 . can be connected with

One longitudinal end of the second pipe L2, that is, the lower end is connected to be in communication with the second pressure port h3 as described above, and the other longitudinal end, that is, the upper end, is the first sensor unit 221 . can be connected with

The first sensor unit 221 may be referred to as a known differential pressure sensor, and calculates a differential pressure (dynamic pressure) between the pressure generated in the first pipe L1 and the pressure generated in the second pipe L2, and , it is possible to calculate the velocity of the flare gas using the calculated value.

In addition, the velocity of the flare gas calculated by the first sensor unit 221 may be transmitted to the flow rate analyzer 240 .

The density measuring unit 230 includes, as shown in FIGS. 4 and 5, a third pipe (L3) having one end in the longitudinal direction connected to the gas inlet (h1) formed in the round surface 211 to be in communication; a fourth pipe (L4) whose longitudinal end is communicatively connected to the gas outlet (h4) formed on the outer surface of the sampling bar (110) in which the chamfer (212) is not disposed; The second end of the third pipe (L3) in the longitudinal direction and the other end of the fourth pipe (L4) in the longitudinal direction are communicatively connected to each other, and the density of the flare gas introduced through the third pipe (L3) is measured. The sensor unit 231; may include.

The third pipe L3 and the fourth pipe L4 may also be provided in the sampling bar 210 in the longitudinal direction of the sampling bar 210 .

One longitudinal end of the third pipe L3, that is, the lower end, is connected in communication with the gas inlet h1 as described above, and the other longitudinal end, that is, the upper end, is the second sensor unit 231 can be connected with

One longitudinal end of the fourth pipe L4, that is, the lower end, is connected in communication with the gas outlet 111c as described above, and the other longitudinal end, that is, the upper end, is the second sensor unit 231 can be connected with

Accordingly, the flare gas introduced into the gas inlet h1 may be transferred to the second sensor unit 231 through the third pipe L3 , and the flare gas passed through the second sensor unit 231 . may be discharged to the gas outlet 111c through the fourth pipe L4.

Here, the gas outlet 111c is disposed above the vertical surface 113 so that the flare gas discharged through the gas outlet 111c does not flow into the second pressure port 113a formed on the vertical surface 113 . It is preferable to be provided on the circumferential surface of the sampling bar 210 .

The second sensor unit 231 may be a known quartz oscillator gas sensor that vibrates using a flare gas as a medium, and measures the density of the flare gas and uses the measured value as the flow rate analyzer It can be passed to (240).

Meanwhile, as shown in FIG. 2 , the combustion unit 300 may receive the flare gas passing through the density measurement unit 230 and burn the flare gas.

The pipe (P) of the flare system provided in an oil refinery or petrochemical plant is widely piped with various shapes and numbers. It is preferable to accurately measure the flow rate value of the flare gas to be measured. In addition, the flow rate and heat value of the flare gas measured as described above may be used as data to be compared and analyzed with flow values and heat values measured at other various points of the pipe P.

The flow rate analyzer 240 may receive power from a power supply not shown, and may transmit it to the speed measuring unit 220 and the density measuring unit 230 .

In addition, as described above, the flow rate analyzer 240 receives the data values measured from the speed measurer 220 and the density measurer 230 to calculate, store and analyze the flow rate of the flare gas, and also, The data may be transmitted to the calibration unit 600 .

Then, the calibration unit 600 may calculate the calibration value of the calorific value calculation unit 500 based on the flow rate data of the flare gas transmitted from the flow rate analysis unit 240 .

On the other hand, when the sampling bar 210 is in the shape of a curved pipe or is at a position affected by non-uniform flow due to the curved pipe, the flow profile of the flare gas is preferentially identified through computational fluid dynamics (CFD), and the It is desirable to measure the velocity and density of the flare gas after calibrating the flow profile.

That is, among several sections of the pipe P through which the flare gas flows, in the case of a straight pipe in which the fluid can flow uniformly without receiving resistance to the flow, the velocity distribution of the flare gas in the pipe has an almost uniform shape ( Like a normal distribution graph, where the center point is the fastest and the point where the tangent to the inside of the pipe is the slowest). Therefore, at such a position, it is possible to accurately grasp what kind of relationship the velocity of the flare gas measured in the relationship between the length of the inserted sampling bar 210 and the diameter of the pipe P has with the average velocity of the fluid in the corresponding section, It is difficult to understand what relationship the velocity measured by the sampling bar 210 has with the velocity of a curved pipe in which the flow velocity distribution within the pipe is not uniformly predicted or at a point at a position affected by the curved pipe.

In order to solve this problem, if the velocity distribution in the pipe P in which the sampling bar 210 is installed is accurately grasped, the relationship between the measured value at the corresponding point and the average velocity can be clearly identified.

In other words, even if the sampling bar 210 is inserted into the point of the pipe P having the shape of a curved pipe or the point of the pipe P having the shape of a straight pipe, the point is the curved part of the pipe P When they are disposed close to each other and are affected by non-uniform fluid flow, the flow profile of the flare gas may be identified and corrected through computational fluid dynamics (CFD). That is, the correction can be made by securing three-dimensional data of the pipe through a three-dimensional scan, actual measurement, or a value on a design drawing, and STAR-CCM+, a commercial program for performing CFD, can be used.

Therefore, when the point at which the sampling bar 210 is inserted is a curved portion of the pipe P or a straight portion disposed close to the curved portion, it is preferable to measure the velocity and density after correcting the flow profile of the flare gas. .

The extraction unit 200 configured as described above measures the velocity of the flare gas in a pressure calculation method that is not affected by turbulence/laminar flow according to the flow velocity of the flare gas, and calculates the flow rate of the flare gas using the velocity value. , it can measure the flow rate of flare gas flowing along the pipe with high accuracy.

Accordingly, the extraction unit 200 extracts the flare gas to be burned in the combustion unit 300 and simultaneously calculates a flow rate value using the extracted flare gas, so the flow rate for each section of the pipeline provided in the flare system , calorific value and pressure fluctuations can be accurately identified, and the operating conditions of the flare system can be changed accordingly.

On the other hand, the direct combustion calorimetry system 100 of the flare gas according to an embodiment of the present invention, as shown in FIG. 7 , a detection unit for detecting a component of the flare gas extracted by the extraction unit 200 . (700) and a calorimetric analysis unit 800 for calculating the total amount of heat of the flare gas based on the data measured by the flow rate analysis unit 240 of the detection unit 700 and the extraction unit 200; can

The detection unit 700 may be referred to as a component for detecting a component of the flare gas flowing along the pipe (P). In other words, the detection unit 700 may be a component that detects each component constituting the flare gas and the concentration of the component.

The concentration of each component detected by the detection unit 700 is a relative volume concentration (volumn percent) occupied by the component in the total volume of the flare gas.

The detection unit 700 may be composed of a mass spectrometer (mass spectrometer) that detects a specific component included in the flare gas and the concentration of the component, and a density measuring unit ( 230) may be delivered with the flare gas. For reference, since the mass spectrometer is a well-known device used for analyzing the composition of a material, a detailed description of its configuration is omitted in the specification of the present invention.

In addition, the detection unit 700 may be composed of a known analysis device that detects the detection concentration in response to a specific component based on the components of the flare gas identified by prior investigation or experiment, and constitutes the flare gas. It may be provided with a number corresponding to or greater than the number of various components.

In addition, as described above, the concentration of the component detected by the detection unit 700 can be referred to as a relative volume concentration (volume percent) occupied by the detected gas in the total volume of the flare gas flowing along the pipe P. and this data may be utilized to calculate the total amount of heat of the flare gas in the calorific value analyzer 800, which will be described later.

As described above, the calorific value analyzer 800 may calculate the total calorific value of the flare gas based on the data measured by the flow rate analyzer 240 of the detector 700 and the extractor 200 .

In other words, the calorific value analyzer 800 calculates the flow rate value occupied by the component from the flow rate value of the flare gas based on the component of the flare gas detected by the detection unit 700 and the concentration data of the component, and then The total amount of heat of the flare gas can be calculated by multiplying the component flow rate by the unit calorific value of the component.

For example, assuming that the components constituting the flare gas are methane, ethane, propane, butane, hydrogen, and nitrogen by the detection unit 700 , the calorific value analyzer 800 is extracted based on the concentration data for each gas. After calculating the component flow rate value occupied by each gas from the flow rate value of the flare gas measured by the flow rate analysis unit 240 of the unit 200, the component flow rate value is multiplied by the unit calorific value of the corresponding gas for a single gas calorific value can be calculated. Then, the total calorific value of the flare gas can be calculated by summing all the calorific values for the single gases.

The total calorific value of the flare gas calculated as described above may be utilized as one data for calculating the calorific value of the exhaust gas discharged from the flare stack. That is, the calorific value of the flare gas discharged from the flare stack may be calculated using data of the calorific value of the flare gas calculated at various points of the pipe P, respectively.

In addition, the total calorific value of the flare gas calculated by the calorific value analysis unit 800 may be compared and analyzed with the calorific value data of the flare gas calculated by the calorific value calculating unit 500 .

That is, in terms of reducing the energy used to burn the flare gas in the combustion unit 300 , the detection unit 700 and the calorific value analyzer 800 may be used to calculate the calorific value of the flare gas.

In addition, the calorific value of the flare gas burned in the combustion unit 300 is calculated by the calorific value calculating unit 500, and the detection unit 700 and the calorific value analyzing unit 800 are abnormally determined using the calculated data. can do.

It is also possible to determine whether there is an abnormality in the calorific value calculating unit 500 based on the data calculated by the counter-lightning unit 700 and the calorific value analyzing unit 800 .

That is, based on the data measured by the calorific value calculation unit 500 for calculating the calorific value of the flare gas burned in the combustion unit 300 , and the flow rate analysis unit 240 of the detection unit 700 and the extraction unit 200 . The calorific value analyzer 800 that calculates the calorific value of the flare gas may perform a diagnosis function by performing comparison analysis with each other.

For example, whether the calorific value calculated by the calorific value calculation unit 500 or the calorific value calculated by the calorific value analysis unit 700 is measured with high accuracy is determined by the calorific value of the calibration gas supplied to the combustion unit 300 and burned can be comparatively analyzed.

In other words, the calorific value of the flare gas measured by the calorific value calculating unit 500 , the calorific value of the calibration gas measured by the calorific value calculating unit 500 , and the calorific value of the flare gas calculated by the calorific value analyzing unit 800 are compared with each other By analyzing, it is possible to accurately determine the presence or absence of abnormalities in each component.

As described above, it is preferable that the calorific value analyzer 800 calculates the calorific value of the flare gas from the viewpoint of reducing the energy used for burning the flare gas and the work hassle. However, since there is a risk of lowering the measurement accuracy than measuring the calorific value by directly burning the flare gas, in terms of measuring the calorific value of the flare gas with high accuracy, the combustion unit 300 and the calibration gas supply unit 400 and the calorific value It is preferable to measure the calorific value of the flare gas using the calculator 500 and the calibration unit 600 . By properly utilizing the two methods, it is possible to measure the calorific value of the flare gas with high accuracy, as well as to save energy and improve work convenience.

Although specific embodiments according to the present invention have been described so far, various modifications are possible without departing from the scope of the present invention.

Therefore, the scope of the present invention should not be limited to the described embodiments, but should be defined by the claims described below as well as the claims and equivalents.

100: calorimetry system
200: extraction unit 210: sampling bar
220: speed measuring unit 230: density measuring unit
240: flow analysis unit 300: combustion unit
400: gas supply for calibration
500: calorific value calculation unit
600: correction unit
700: detection unit
800: calorific value analysis unit

Claims (10)

an extraction unit provided in a pipe through which the flare gas flows to sample the flare gas;
a combustion unit receiving and burning the flare gas extracted by the extraction unit; and
and a calorific value calculating unit for calculating the calorific value of the flare gas burned in the combustion unit;
The extraction unit is a direct combustion calorimetry system for flare gas, characterized in that for extracting the flare gas in a state of being mounted on the vent provided in the pipe.
The method of claim 1,
Calibration gas supply unit for supplying calibration gas to the combustion unit; and
Direct combustion calorific measurement system of flare gas comprising a; .
3. The method of claim 2,
The calibration gas supply unit,
Direct combustion type of flare gas, characterized in that supplying the calibration gas in a state connected to a flare gas flow pipe connecting the extraction unit and the combustion unit to each other or supplying the calibration gas in a state directly connected to the combustion unit calorimetry system.
3. The method of claim 2,
The correction unit,
Direct combustion of flare gas, characterized in that the calorific value of the calorific value calculation unit is calculated by comparing and analyzing the theoretical calorific value of the calibration gas supplied from the calibration gas supply unit and the calorific value of the calibration gas actually measured in the calorific value calculating unit News calorimetry system.
The method of claim 1,
The direct combustion calorimetry system of the flare gas, characterized in that the extraction unit samples the flare gas flowing along the inner central portion of the pipe in a state in which it is mounted on a vent provided in the pipe.
6. The method of claim 5,
The extraction unit,
a sampling bar into which the lower end in the longitudinal direction is inserted into the pipe;
a velocity measuring unit for measuring the velocity of the flare gas while being connected to the sampling bar;
a density measuring unit for measuring the density of the flare gas while being connected to the sampling bar; and
Direct combustion calorimetry system of flare gas comprising a; a flow rate analyzer for calculating the flow rate of the flare gas based on the value measured by the speed measuring unit and the density measuring unit, and storing and analyzing the calculated flow rate .
7. The method of claim 6,
The sampling bar is
a round surface disposed to face the flow direction of the flare gas;
a chamfer provided on the back side of the round surface; and
Direct combustion calorimetry system for flare gas, characterized in that it comprises a; partitioning the chamfered portion but connecting both ends of the width direction of the round surface to each other.
8. The method of claim 7,
The speed of the flare gas measured by the speed measuring unit is,
It is calculated using the pressure difference generated by the flow of the flare gas,
The speed measuring unit,
a first pipe having one end in the longitudinal direction connected to the first pressure port formed on the round surface so as to be in communication with the first pipe;
a second pipe having one end in the longitudinal direction connected to the second pressure port formed on the vertical surface to be in communication; and
The other longitudinal end of the first pipe and the other longitudinal end of the second pipe are communicatively connected to each other, and the velocity of the flare gas using the pressure difference between the pressure generated in the first pipe and the pressure generated in the second pipe. Direct combustion calorimetry system of flare gas comprising a first sensor unit for measuring
8. The method of claim 7,
The density measuring unit,
a third pipe whose one end in the longitudinal direction is communicatively connected to the gas inlet formed on the round surface;
a fourth pipe having one longitudinal end connected to the gas outlet formed on the circumferential surface of the sampling bar to be in communication with each other; and
and a second sensor unit communicatively connected to the other longitudinal end of the third pipe and the other longitudinal end of the fourth pipe, and measuring the density of the flare gas flowing in through the third pipe. Direct combustion calorimetry system for flare gases.
10. The method of claim 9,
The combustion unit,
A direct combustion calorimetry system for flare gas, characterized in that the flare gas passed through the density measuring unit is received and combusted.

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