KR100849399B1 - Multi-area gas leakage detection system using single gas detector - Google Patents

Abstract

A multi-area gas leakage detection system using a single gas detector is provided to reduce a cost by simplifying communication equipment for signal transmission from the gas detector to a central control device and equipment for processing and analyzing a signal in the central control device. A multi-area gas leakage detection system using a single gas detector includes a sample dividing unit(200), a gas detection unit(300), and a central control device(400). The sample dividing unit divides air samples collected from a sample collection unit(100) into detected samples to be detected for leakage of a gas and exhausted samples to be exhausted outside. The gas detection unit detects a combustible gas in the detected samples by sampling the detected samples. The central control device receives a gas detection signal from the gas detection unit, calculates concentration of the gas based on the signal, determines whether the gas is leaked or not, displays the determination result, raises an alarm in leakage of the gas, and controls operation of the units based on a work order inputted from the outside.

Description

Multi-zone gas leak detection system using single gas detector {MULTI-AREA GAS LEAKAGE DETECTION SYSTEM USING SINGLE GAS DETECTOR}

The present invention relates to a gas leak detection system, and more particularly, by using a single gas detector, it detects in real time flammable gas leaking from a plurality of zones in a large installation space, such as a thermal power plant, and notifies the central controller And a gas leak detection system for issuing an emergency alert.

In general, fossil energy such as natural gas (LNG) or liquefied petroleum gas (LPG) is mainly used as industrial fuel in factories and thermal power plants. These gases are flammable gases that can lead to fire and explosion, which can lead to enormous losses such as damage to property and lives.Therefore, gas leaks can be prevented and leaks can be detected quickly to prevent the spread of damage. You need to deal with it. To this end, in recent years, gas leak detection systems have been introduced one after another in places where there is a risk of gas leakage, such as factories or thermal power plants.

Conventional gas leak detection systems include a gas detector and a central controller. The gas detector is provided at a plurality of positions where gas leakage is foreseen, and detects whether the gas leaks in real time. The signals detected by each gas detector are transmitted to the central controller, and the central controller collects and analyzes these signals to monitor for gas leaks in real time. When an abnormal signal is found, a gas leak emergency alarm is issued to detect a gas leak. You will be able to respond quickly.

FIG. 1 is an example of such a conventional gas leak detection system, schematically illustrating a system for detecting gas leaking from multiple zones, in particular from multiple zones inside two different annular combustors, in a thermal power plant. Hereinafter, these annular combustors will be referred to as a first sensing zone I and a second sensing zone II, respectively. On the other hand, the plurality of partial sensing zones inside each annular combustor are divided into alphabets in the drawing, and each of the partial sensing zones is provided with one gas detector 3, 3 '. Each of the gas detectors 3 and 3 'detects the leakage of flammable gas in real time, and the detected signal is transmitted to the central controller 4, and the central controller 4 analyzes the transmitted signal. It will determine if there is a leak.

However, according to the conventional gas leak detection system, separate gas detectors must be installed in a plurality of zones where gas leakage is concerned, and a plurality of relatively expensive gas detectors must be installed. The equipment for remote communication between each gas detector and the central controller and the equipment necessary for signal processing transmitted from each gas detector to the central controller are complicated, and the central controller is overloaded because the multiple signals must be collected and processed simultaneously. There has been a problem that efficient real-time gas leak detection is not performed.

Therefore, the present invention was devised to solve the problems of the conventional gas leak detection system as described above, by using only a single gas detector, without having to install a separate gas detector in each of a plurality of zones to detect the gas leak. By detecting the gas leak in real time, it is possible to reduce the equipment cost due to the installation of a plurality of gas detectors, and the communication equipment and signal processing and analysis equipment necessary for the signal transmission from each gas detector to the central controller. The aim is to provide a system that can efficiently and stably detect gas leaks at low cost.

Gas detection system according to the present invention for achieving the above object, the sampling unit 100 for collecting air samples from each of a plurality of detection zones that there is a risk of leakage of flammable gas; A sample classification unit 200 for classifying each air sample collected from the sampling unit 100 into a detection target sample to be a gas leak detection target and an exhaust target sample to be discharged to the outside; A gas detection unit 300 for sampling a flammable gas present in the sample to be sampled by sampling the air sample classified as the sample to be detected by the sample classification unit 200; The gas detection signal is received from the gas detecting unit 300, the concentration of the gas is calculated based on the determination of the gas leakage, and the result is displayed, the gas leak alarm is issued, and the operation input from the outside. Based on the command includes a central controller 400 for controlling the operation of each unit.

Here, the sampling unit 100, the sampling pipes (110, 110 ') are installed separately connected to each detection zone to collect the air samples present in the plurality of detection zones; Solenoid valves (120, 130) for controlling the flow of air samples through the sampling pipe (110, 110 ') installed for each detection zone; A first transfer line 140 classifying the detection zone into a first detection zone and a second detection zone, and transferring the air sample collected from the sampling pipe connected to the first detection zone to the sample classification unit 200; ; And a second transfer line 150 for transferring the air sample collected from the sampling pipe connected to the second detection zone to the sample classification unit 200.

In addition, the sample classification unit 200 includes a sampling tube 260 for collecting and transporting the sample to be detected and a bypass tube 250 for passing the sample to be exhausted, but one side of the first transfer line 140 is provided. ) And the other two other sides are connected to each of the sampling tube 260 and the bypass tube 250 to transfer the flow of the air sample transferred through the first transfer line 140 to the sampling tube 260. The first three-way valve 230 to selectively guide the flow to any one of the bypass pipe 250, one side is connected to the second transfer line 150 and the other two other side is the sampling pipe ( 260 and the bypass pipe 250, respectively, selectively flows the flow of air sample transferred through the second transfer line 150 to the other pipe not guided by the first three-way valve 230. Inducing second three-way valve 240, the sampling pipe 260 and the bypass pipe 250 A pump block 270 connected to the pump to individually suck and discharge the sensing target sample and the exhaust target sample transferred through each pipe; And an exhaust pipe 280 for discharging the exhaust target sample discharged from the pump block 270 to the outside.

On the other hand, the pump block 270, the exhaust pump 274 for sucking the exhaust target sample delivered through the bypass pipe 250 and discharged to the exhaust pipe 280; And a sampling pump 278 that sucks the sample to be detected delivered through the sampling tube 260 and discharges the sample to the gas sensing unit 300.

Outlet, the gas detection unit 300, the flow meter 310 for supplying a suction target sample of a constant flow rate required for gas detection; It includes an infrared gas detector 320 for passing the infrared light through the supplied detection target sample and measuring the intensity of the infrared light and outputting it as a gas detection signal in the form of a current signal.

In addition, the central controller 400 calculates the concentration of the gas present in the sample to be detected based on the gas detection signal transmitted from the gas detection unit 300, controls the operation of each of the units, from outside A controller 450 for controlling the operation of each unit of the central controller 400 based on the input work command; An input display unit 420 configured as a touch screen device to receive a work command from the outside, display a work result according to the input work command, a gas concentration value calculated from a gas detection signal, and operation state information of each unit; ; A PLC (430) for outputting a control signal for issuing an alarm when it is determined that the gas detection signal is equal to or greater than a reference value; And an alarm unit 440 for issuing an alarm based on the control signal output from the PLC 430.

The control unit 450 may include a calculation module 452 for receiving a gas detection signal in the form of a current signal from the gas detection unit 300 and calculating a concentration of the combustible gas based on a pre-stored arithmetic formula; The opening and closing of the solenoid valve 120,130, the first three-way valve 230, the second three-way valve 240, the operation of the exhaust pump 274 and the sampling pump 278, the gas detection unit It includes a control module 454 to control the operation of (300).

These first detection zones and second detection zones may each be two different annular combustors of a thermal power plant.

According to the present invention as described above, it is possible to detect the gas leak in real time using only a single gas detector, without having to install a separate gas detector in each of a plurality of zones where there is a gas leakage concern, it is installed a plurality of gas detectors It is possible to reduce the equipment cost due to the cost and to simplify the communication equipment and signal processing and analysis equipment necessary for the signal transmission from each gas detector to the central controller. Have

Hereinafter, with reference to the accompanying drawings will be described in detail the configuration and operation of the gas leak detection system according to the present invention.

2 is a schematic diagram of a gas leak detection system according to the present invention, FIG. 3 is an overall system diagram showing detailed configurations of respective functional units of the gas leak detection system according to the present invention, and FIG. 4 is a central controller 400. Is a functional block diagram.

As shown in FIG. 2, the gas leak detection system according to the present invention includes a sampling unit 100, a sample classification unit 200, a gas detection unit 300, and a central controller 400.

The sampling unit 100 is a part for collecting the air sample from a specific area or facility where there is a gas leakage concern, such as an annular combustor of a thermal power plant, in the present invention a wide range of areas that require gas detection in two different zones, That is, the first detection zone (I) and the second detection zone (II) were divided. As an example of a thermal power plant, the first detection zone I corresponds to one annular combustor, and the second detection zone II corresponds to another annular combustor. The first detection zone (I) and the second detection zone (II) are each divided into a plurality of partial detection zones, and sampling pipes 110 and 110 ′, each of which is composed of ducts or pipes, are installed in each partial detection zone. . Therefore, the air sample present in each partial detection zone is configured to be collected as it flows through the sampling pipe (110,110 ').

3 shows a preferred configuration of a sampling unit 100 having two annular combustors installed in a thermal power plant as a first sensing zone I and a second sensing zone II. As shown, the interior of two different annular combustors installed in a thermal power plant is a plurality of partial detection zones A, K, G, C, I, E and D, J, F, B, L, H, D, respectively. It is partitioned, and collecting pipes 110 and 110 'for collecting air samples in each partial detection zone are separately installed. Here, the plurality of partial detection zones are classified into a first detection zone and a second detection zone. Each sampling pipe 110 and 110 ′ is provided with solenoid valves 120 and 130 which are opened and closed electronically, respectively. Hereinafter, solenoid valves installed in the first detection zone I will be referred to as a first solenoid valve 120 and solenoid valves installed in the second detection zone II will be referred to as a second solenoid valve 130.

These solenoid valves 120 and 130 are controlled by the central controller 400 to be described later open and close. Conventionally, as illustrated in FIG. 1, a separate gas detector is installed in the partial detection zones of each detection zone, but in the present invention, instead of installing the gas detectors individually, instead, the air sample is collected from each partial detection zone. Sampling pipes (110, 110 ') is installed. Through this configuration, air samples to be detected for gas leakage can be collected from the partial sense zones of each detection zone.

As shown in FIG. 2, the air samples collected from the first sensing region I and the second sensing region II are independent of each other, namely, a first transfer line 140 and a second transfer line 150. It is transferred to a sample distribution unit described later through a separate pipe.

The first transfer line 140 and the second transfer line 150 are pipes for sucking and transporting air samples collected from the first detection zone I and the second detection zone II, and any of the detection zones. One, for example, a plurality of sampling pipes 110 installed separately for each partial detection zone of the first detection zone (I) are converged and connected to the first transfer line 140, and the other detection zone, for example, the second A plurality of sampling pipes 110 ′ individually installed for each partial detection zone of the detection zone II are converged and connected to the second transfer line 150. The first transfer line 140 and the second transfer line 150 may be equipped with a separate suction fan for suction and transfer of the air sample, to drive the suction pumps provided in the pump block 270 to be described later. By the suction force generated according to the air sample may be configured to be transported along each suction pipe. Through this configuration, the air sample collected from the first detection zone (I) and the air sample collected from the second detection zone (II) are separate pipes of the first transfer line 140 and the second transfer line 150. Are separated and transported.

The air sample separately separated and transferred to the first transfer line 140 and the second transfer line 150 is a detection target sample to be gas leakage detection target from the sample classification unit 200, and is moved to the outside instead of the detection target. It is classified as an exhaust sample to be discharged. The sample to be detected is transferred to a gas sensing unit 300 to be described later, and the sample to be exhausted is sent to an exhaust facility such as a chimney through an exhaust pipe 280.

3 shows a preferred configuration of such a sample classification unit 200. As shown, the sample classification unit 200 is the first air filter 210, the second air filter 220, the first three-way valve 230, the second three-way valve 240, the sampling tube 260 , Bypass tube 250, and pump block 270.

The first air filter 210 and the second air filter 220 are pre-processed to remove dust and particles contained in the air sample transferred through the first transfer line 140 and the second transfer line 150, respectively. Air filtration filter of the process. The air filter should be checked from time to time so that a normal suction flow path can be formed, and the filter element should be replaced when the filter is heavily contaminated.

The first three-way valve 230 and the second three-way valve 240 are connected to rear ends of the first air filter 210 and the second air filter 220, respectively. The first three-way valve 230 and the second three-way valve 240 is a means for classifying the air sample conveyed through the first transfer line 140 and the second transfer line 150 to the sample to be detected and the exhaust target sample. As a 3-way solenoid valve in which opening and closing is controlled electronically according to the control of the central controller 400 to be described later.

For the classification of the air sample, one side of the first three-way valve 230 and the second three-way valve 240 is connected to the first transfer line 140 and the second transfer line 150, respectively, and are transported through them. Get an air sample. The two other sides of the first three-way valve 230 and the two other sides of the second three-way valve 240 are connected to the sampling tube 260 and the bypass tube 250 in common, respectively. The sample to be detected may be transferred through 260 to be supplied to the gas detection unit 300, and the sample to be exhausted may be discharged to the exhaust pipe 280 described later through the bypass pipe 250. It is configured to be. That is, the first three-way valve 230 guides the air sample supplied from the first transfer line 140 to one of the sampling pipe 260 and the bypass pipe 250, and the second three-way valve 240 The air sample supplied from the second transfer line 150 is guided to the other side of the sampling pipe 260 and the bypass pipe 250 which is not guided by the first three-way valve 230, the sample to be detected and exhaust Classify as a sample. The method of classifying the air sample by the first three-way valve 230 and the second three-way valve 240 will be described in more detail later.

The pump block 270 is connected to the sampling tube 260 and the bypass tube 250. The pump block 270 is a portion for suctioning and discharging the sample to be detected and the sample to be discharged separately, and the pump block 270 is provided with an exhaust pump 274 and a sampling pump 278. The exhaust pump 274 has an intake side connected to the bypass pipe 250 to suck the air sample classified as the exhaust target sample, and the discharge side is connected to the exhaust pipe 280 to exhaust the sucked exhaust target sample to the outside. Perform the function. In addition, the sampling pump 278 has a suction side connected to the sampling tube 260 to suck the air sample classified as the sample to be detected, and the discharge side is connected to the gas detection unit 300 which will be described later. To serve as a gas detector 320. In addition, the exhaust pump 274 and the sampling pump 278 serve as a suction force providing source so that air samples can be collected from the first sensing region I and the second sensing region II.

As described above, the air sample classified as the exhaust target sample in the sample classification unit 200 is exhausted to the outside through the exhaust facility such as the chimney through the exhaust pipe 280, and the air sample classified as the target sample is the gas detection unit 300. Is transferred to). The gas detecting unit 300 is composed of a flow meter 310 and a gas detector 320.

The flow meter 310 is to supply the gas detector 320 to be described later by sucking the sample to be detected at a constant flow rate required for gas detection, it is configured to supply a maximum flow rate of 5L / min, usually in the gas detection As a required amount, a sample to be detected at a flow rate of 3 L / min is supplied to the gas detector 320.

The gas detector 320 detects the combustible gas contained in the sample to be detected at a predetermined flow rate supplied from the flow meter 310, but there is no limitation in the type thereof, and it is particularly preferable that the gas detector is an infrared type gas sensor. The infrared type gas sensor passes infrared rays through the air sample, receives them, measures the intensity after infrared attenuation by absorption of flammable gas molecules, and converts and amplifies the gas detection signal in the form of a 4-20 mA current signal to a central tube which will be described later. Send to filed 400.

The central controller 400 receives the gas detection signal from the gas detector 320 and calculates the concentration value of the flammable gas included in the sample to be detected through the signal processing to determine whether the gas leaks and the result. It is a remote central control device for displaying and controlling the respective unit of the gas detection system according to the present invention by receiving the work command of the monitor from the outside.

4 is a functional block diagram of the central controller 400 according to the present invention. As illustrated, the central controller 400 includes a power supply unit 410, an input display unit 420, a PLC 430, an alarm unit 440, and a controller 450.

The power supply unit 410 is a part for supplying the power required for the operation of each part of the central controller 400, converts the 220V AC power input from the outside into a 24V DC power supply to each part of the central controller 400. .

The input display unit 420 receives the work command of the monitor from the outside and transfers it to the control unit 450 to be described later, and analyzes the work result according to the input work command and the gas detection signal transmitted from the gas detector 320. The touch screen device is configured to display various information such as the concentration value of the combustible gas obtained according to the present invention and the current state of each functional unit of the gas detection system according to the present invention.

The PLC (Programmable Logic Controller) 430 is a kind of small computer in which only ON / OFF control is performed by programmable sequential logic, and receives a ON / OFF control signal to perform a predetermined ON / OFF control. , Car production lines, display device production lines such as LCD or PDP, and advanced IT manufacturing fields such as mobile phones, as well as large automated machinery such as automatic car washes, medical devices or bio-devices, can be controlled, and factory automation and computer integrated production ( It is an essential device for CIM.

In the present invention, when the PLC 430 receives the gas detection signal from the gas detector 320 and determines that the concentration value of the combustible gas is greater than or equal to the reference value by a preprogrammed logic, the PLC 430 controls the control signal. Send an alarm to sound the alarm.

The alarm unit 440 is a part for generating an alarm signal informing that the gas is leaked according to the control signal of the PLC 430, is attached to the central controller 400, or in a separate place in the control room, and gas It may be a buzzer or a warning lamp installed in the leak detection zone, and may further include a smoke removal system installed in the gas leak detection zone to remove the gas.

The control unit 450 controls the operation of each of the above-described central controller 400 and at the same time calculates the concentration value of the gas present in the air sample from the gas detection signal transmitted from the gas detector 320, and the monitor Control the operation of various valves and suction pumps based on the entered work instructions. To this end, the control unit 450 of the central controller 400 includes a calculation module 452, a control module 454, an input / output module 456, and a memory 458.

The calculation module 452 receives a gas detection signal from the gas detector 320 and calculates a concentration value of the gas included in the air sample therefrom. The gas detection signal transmitted from the gas detector 320 is a signal value of the intensity of the infrared light after the infrared rays having a specific wavelength are absorbed by the gas molecules, from which the infrared absorption rate (absorbance) by the gas molecules can be calculated. The concentration of the gas molecules may be calculated based on the absorption rate information. The calculation of the gas concentration value is performed in the calculation module 452.

Infrared wavelength band used in the gas detector 320 of the present invention is a medium-infrared band of 3-5㎛, by using the gas molecules have a property of selectively absorbing only the energy corresponding to the unique vibration energy level, respectively Measure the gas concentration. In the present invention, the concentration of the combustible gas or the like is measured using the principle of non-dispersive infrared (NDIR) which allows light to pass through without being dispersed. This method is a method of measuring the gas concentration by converting the infrared absorption rate of the measurement gas into current or voltage.

In the present invention, the gas detector 320 outputs a gas detection signal as a current signal of 4-20mA and the calculation module 452 analyzes the gas detection signal and is included in the air sample by a pre-programmed equation. Calculate the concentration of the gas. The method of calculating the concentration of gas from the infrared gas detector 320 is a known method and further detailed description thereof will be omitted.

The control module 454 is a part for controlling the operation, stop and open / close operation of various valves, pumps, and gas detectors 320 installed in the respective functional units of the gas detection system according to the present invention. .

Specifically, as shown in FIG. 4, the control module 454 includes a plurality of first solenoid valves 120 and second sensing zones II installed in each partial sensing zone of the first sensing zone I. FIG. Controls a plurality of second solenoid valve 130 installed in each partial detection zone.

The solenoid valves 120 and 130 in each detection zone are controlled to be opened and closed sequentially in the first 20 seconds. That is, as the first solenoid valves 120 in the first detection zone I are sequentially opened and closed, an air sample is collected and gas leak is detected.

At the same time, the second solenoid valves 130 in the second detection zone II are also opened and closed in order to collect air samples. However, the air sample collected from the second detection zone (II) is classified in the sample classification unit 200 as an exhaust target, not a gas leak detection target, and exhausted through the exhaust pipe 280. This operation is repeated continuously so that continuous and sequential sampling of air samples from different partial sensing zones and sensing zones is performed in real time.

On the other hand, the opening and closing operation order of the solenoid valves (120, 130) can be arbitrarily changed by the monitor. For example, when any one of the first solenoid valves 120 in the first detection zone I is opened and the air sample is collected, it is determined that the gas leak in the second detection zone II is suspect. When a work command is input by touching one of the second solenoid valves 130 of the second detection zone II through the touch screen of the input display unit 420, the control module 454 touches the corresponding solenoid. Open the valve to collect the air sample. If there is no work command of the monitor for a predetermined time, the control module 454 again controls the opening and closing of each solenoid valve (120, 130) every 20 seconds.

In addition, the control module 454 controls the opening and closing operations of the first three-way valve 230 and the second three-way valve 240. The control module 454 repeatedly changes the opening and closing directions of the first three-way valve 230 and the second three-way valve 240 by a predetermined time unit, and detects the air sample collected from each detection zone. The samples are classified sequentially. On the other hand, the opening and closing direction and the order of the first three-way valve 230 and the second three-way valve 240 may be changed arbitrarily by the monitor by inputting a work command through the touch screen of the input display unit 420.

In addition, the control module 454 controls the exhaust pump 274 and the sampling pump 278. The control module 454 controls the exhaust pump 274 and the sampling pump 278 to be always driven at the same time as the detection of gas leakage starts and provides a suction force when collecting the air sample from the partial detection zone of the first detection zone. The sample to be detected classified in the sample classification unit 200 is transferred to the gas detector 320 by the suction force of the sampling pump 278, and the sample to be exhausted is discharged from the exhaust pipe 280 by the suction force of the exhaust pump 274. To be discharged.

The input / output module 456 is a kind of data communication interface that enables data communication by transmitting signals in the controller 450 of the central controller 400 and exchanging signals with external devices. More specifically, the input / output module 456 has an RS485 communication module to perform data communication with the gas detector 320, and has an RS232C communication module to perform data communication with the input display unit 420 and the PLC 430. Perform. That is, through this configuration, the input / output module 456 receives a gas detection signal between 4-20 mA from the gas detector 320 and transfers it to the calculation module 452 and the PLC 430, and the calculation module 452. The gas concentration value calculated by) is output to the touch screen of the input display unit 420. Then, the operation command is input from the input display unit 420 configured as the touch screen device and transferred to the control module 454. In addition, the input / output module 456 displays various system state information, such as driving states of various valves and pumps controlled by the control module 454, and collection status of air samples, on the touch screen device.

The controller 450 further includes a memory 458. The memory 458 stores arithmetic expressions necessary for calculating a gas concentration value from a gas detection signal, programs necessary for various controls, information data related to a real-time measured gas concentration value, a warning history, and other system states. .

So far, the detailed configuration of the gas detection system according to the present invention has been described. Hereinafter, a method of detecting whether the gas leaks in the gas detection system according to the present invention will be described.

The first control program first detects whether a gas leak has occurred in the first detection zone (I) of the first detection zone (I) and the second detection zone (II), and then sequentially stores the gas in the second detection zone (II). It is set to detect whether a leak has occurred. To this end, first, the first solenoid valve 120 provided in the sampling pipe 110 installed in each partial detection zone of the first detection zone (I) at intervals of 20 seconds under the control of the central controller 400. Open and closed sequentially. Then, the air sample is collected through the sampling pipe installed in each partial detection zone, the collected air sample is transferred through the first transfer line 140, and supplied to one side of the first three-way valve 230. At this time, the sampling of the second detection zone (II) air samples to be detected in a lower order is also started. That is, according to the control of the central controller 400, the second solenoid valves 130 installed in the second detection zone (II) are also opened to collect air samples through the respective sampling pipes 110 ', and collect the collected air samples. Is transferred through the second transfer line 150, and is supplied to one side of the second three-way valve 240. Thus, the reason for collecting the air sample in the first detection zone (I) and the air sample in the second detection zone (II) at the same time is after all the gas detection for the air samples in the first detection zone (I) is performed. If the sampling of the air sample in the second detection zone (II) is started, there is a delay during the time taken to collect the air sample in the second detection zone (II), which prevents continuous gas detection in real time. .

As described above, in the state in which air samples are simultaneously collected from the first sensing zone I and the second sensing zone II, the two other sides of the first three-way valve 230 are controlled by the control of the central controller 400. The side connected to the sampling tube 260 is open and the side connected to the bypass tube 250 is closed. Then, the air sample collected from the first detection zone I is transferred to the gas detection unit 300 through the sampling tube 260.

Meanwhile, at the same time, the central controller 400 controls the second three-way valve 240 to close the side connected to the sampling pipe 260 of the two other sides of the second three-way valve 240 and bypass the pipe 250. The side connected to is opened. Then, the air sample collected from the second detection zone (II) is sent to the exhaust pipe 280 through the bypass pipe 250 and is discharged to the outside accordingly. That is, while the air sample collected from the first detection zone (I) is classified as the detection target sample and the gas leak is detected, the air sample collected from the second detection zone (II) is classified as the exhaust target sample and moved outside. Exhausted.

After the detection result of the air sample collected from the first detection zone (I) is output, the opening and closing directions of the first three-way valve 230 and the second three-way valve 240 are controlled in reverse. That is, the air sample collected from the first detection zone (I) is collected by closing the side connected to the sampling tube 260 and the side connected to the bypass tube 250 among the other two sides of the first three-way valve 230. Is classified as an exhaust target sample and is exhausted to the outside, and the side connected to the sampling tube 260 of the other two sides of the second three-way valve 240 is opened, and the side connected to the bypass tube 250 is closed and the second The air sample collected from the detection zone (II) is classified as the sample to be detected and gas leak is detected.

The gas in the first detection zone (I) and the second detection zone (II) in real time according to the repeated opening and closing control of the first three-way valve 230 and the second three-way valve 240 by the central controller 400. Leak detection is repeated sequentially.

The gas detection signal measured by the gas detector 320 is output in the form of a current signal of 4-20 mA and transmitted to the controller 450 and the PLC 430. The transmitted gas detection signal is converted into a gas concentration value by a calculation formula previously input by the controller 450 and displayed on the input display unit 420. And, if it is determined that the gas concentration value is greater than or equal to the preset reference value, the PLC 430 controls the alarm unit 440 to issue a warning indicating that a gas leak has occurred.

The sampling of the air sample and the measurement in the gas detector 320 is continuously performed in real time, and the monitor checks in real time through the input display unit 420 configured as a touch screen, the measurement result and information on the current state of the system. If necessary, the operation of the valves and pumps can be remotely controlled by inputting a work command on the touch screen to immediately check whether there is a gas leak in a specific area. In addition, it can be used as statistical information by reading the trend graph and the history of alerts for the gas concentration during a specific period.

So far, the present invention has been described in detail with reference to embodiments of the present invention, but the scope of the present invention is not limited thereto, and the scope of the present invention is substantially equivalent to the embodiments of the present invention.

1 is a schematic diagram of a conventional gas leak detection system for detecting a gas leak in a plurality of zones using a plurality of gas detectors,

2 is a schematic diagram of a gas leak detection system according to the present invention;

3 is an overall system configuration diagram showing the detailed configurations of the respective functional units of the gas leak detection system according to the present invention;

4 is a functional block diagram of a central controller.

Explanation of symbols on the main parts of the drawings

100: sampling unit 110,110 ': sampling piping

120: first solenoid valve 130: second solenoid valve

140: first transfer line 150: second transfer line

200: sample classification unit 210: first air filter

220: second air filter 230: first three-way valve

240: second three-way valve 250: bypass pipe

260: sampling tube 270: pump block

274: exhaust pump 278: sampling pump

280: exhaust pipe 300: gas detection unit

310: flow meter 320: gas detector

400: central controller 410: power supply

420: input display unit 430: PLC

440: alarm unit 450: control unit

452 operation module 454 control module

456: input / output module 458: memory

Claims (8)

A sampling unit 100 for collecting air samples from a plurality of detection zones in which there is a risk of leakage of flammable gas; A sample classification unit 200 for classifying each air sample collected from the sampling unit 100 into a detection target sample to be a gas leak detection target and an exhaust target sample to be discharged to the outside; A gas detection unit 300 for sampling a flammable gas present in the sample to be sampled by sampling the air sample classified as the sample to be detected by the sample classification unit 200; The gas detection signal is received from the gas detecting unit 300, the concentration of the gas is calculated based on the determination of the gas leakage, and the result is displayed, the gas leak alarm is issued, and the operation input from the outside. Gas leak detection system comprising a central controller (400) for controlling the operation of each of the units based on the command. The method of claim 1, The sampling unit 100 includes: sampling pipes 110 and 110 'that are individually connected to each detection zone to collect air samples present in the plurality of detection zones; Solenoid valves (120, 130) for controlling the flow of air samples through the sampling pipe (110, 110 ') installed for each detection zone; A first transfer line 140 classifying the detection zone into a first detection zone and a second detection zone, and transferring the air sample collected from the sampling pipe connected to the first detection zone to the sample classification unit 200; ; And a second transfer line (150) for transferring the air sample collected from the sampling pipe connected to the second detection zone to the sample classification unit (200). The method of claim 2, The sample classification unit 200 includes a sampling tube 260 for collecting and transporting the sample to be detected and a bypass tube 250 for passing the sample to be exhausted, one side of which is connected to the first transfer line 140. The other two sides connected to the sampling pipe 260 and the bypass pipe 250 to bypass the flow of the air sample transferred through the first transfer line 140 to the sampling pipe 260. The first three-way valve 230 to selectively guide the flow to any one of the pipes 250, and one side is connected to the second transfer line 150 and the other two side is the sampling pipe 260 And are respectively connected to the bypass pipe 250 and selectively guide the flow of the air sample transferred through the second transfer line 150 to the other pipe not guided by the first three-way valve 230. Connected to the second three-way valve 240, the sampling pipe 260 and the bypass pipe 250 Air pump block 270 to detect the target sample and the exhaust target sample is transported through the respective suction and discharge tubes individually to and; Gas leak detection system, characterized in that it comprises an exhaust pipe (280) for discharging the exhaust target sample discharged from the pump block (270) to the outside. In the third, The pump block 270 includes: an exhaust pump 274 for sucking the exhaust target sample delivered through the bypass pipe 250 and discharging the exhaust target sample to the exhaust pipe 280; Gas leak detection system, characterized in that it comprises a sampling pump (278) for sucking the sample to be delivered through the sampling tube (260) to discharge the gas detection unit (300). The method according to claim 1 or 2, The gas detecting unit 300 includes: a flow meter 310 for sucking and supplying a sample to be detected at a constant flow rate required for gas detection; And an infrared gas detector (320) for measuring the intensity of the infrared light after passing the infrared light through the supplied sensing target sample, and outputting it as a gas detection signal in the form of a current signal. The method according to claim 1 or 2, The central controller 400 calculates the concentration of gas present in the sample to be detected based on the gas detection signal transmitted from the gas detection unit 300, controls the operation of the units, and is input from the outside. A controller 450 for controlling the operation of each unit of the central controller 400 based on the work command; An input display unit 420 configured as a touch screen device to receive a work command from the outside, display a work result according to the input work command, a gas concentration value calculated from a gas detection signal, and operation state information of each unit; ; A PLC (430) for outputting a control signal for issuing an alarm when it is determined that the gas detection signal is equal to or greater than a reference value; And a alarm unit (440) for issuing an alarm based on the control signal output from the PLC (430). The method of claim 5, wherein The control unit 450 may include a calculation module 452 which receives a gas detection signal in the form of a current signal from the gas detection unit 300 and calculates a concentration of the combustible gas based on a pre-stored arithmetic formula; The opening and closing of the solenoid valve 120,130, the first three-way valve 230, the second three-way valve 240, the operation of the exhaust pump 274 and the sampling pump 278, the gas detection unit Gas leak detection system comprising a control module (454) for controlling the operation of (300). The method of claim 2, And said first and second sensing zones are two different annular combustors of a thermal power plant, respectively.

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