KR102663953B1 - In-line flame arrester system - Google Patents

Abstract

An in-line flame blocking system is disclosed. The in-line flame blocking system of the present invention is disposed between the first and second hydrogen supply lines through which hydrogen is supplied, and is provided with a predetermined element to allow hydrogen to flow along the first and second hydrogen supply lines. Flame blocking device to block reverse movement of flame; A first device connection unit connecting the first hydrogen supply line and the flame blocking device; a second device connection unit connecting the second hydrogen supply line and the flame blocking device; A first lock fitting unit coupled to one side of the first device connection unit and including a first temperature sensor that detects the temperature within the first device connection unit adjacent to the first hydrogen supply line; A second lock fitting unit coupled to one side of the second device connection unit and including a second temperature sensor that detects the temperature within the second device connection unit adjacent to the second hydrogen supply line; An oxygen supply lock fitting unit coupled to at least one of the first and second lock fitting units and connected to an oxygen supply line that supplies oxygen in the oxygen tank; A solenoid valve provided in the oxygen supply line; and connected to the first and second temperature sensors through the first and second lock fitting units and connected to the solenoid valve, and operating the solenoid valve based on the sensing values of the first and second temperature sensors. It includes a control panel (CONTROL PANEL) equipped with a controller that controls ON/OFF.

Description

In-line flame arrester system{IN-LINE FLAME ARESTER SYSTEM}

An embodiment according to the concept of the present invention relates to an in-line flame blocking system, and in particular, to an in-line flame blocking system that can minimize the spread of damage caused by explosion or flame by monitoring the temperature in the hydrogen supply line and controlling the system. .

It is necessary to quench ignition or ignition in hydrogen supply line facilities filled with flammable gas, tanks storing flammable liquids or mixed gases, or burners or furnaces. At this time, a flame blocking system may be applied.

In particular, in the case of a hydrogen supply line for hydrogen charging, a flame blocking system is required because it can be vulnerable to flames caused by explosion, etc. In this case, an in-line flame blocking system is required because it must be connected to the hydrogen supply line.

However, when applying an in-line flame blocking system to such a hydrogen supply line, it is necessary to control the system by monitoring the temperature within the hydrogen supply line.

Korea Intellectual Property Office Application No. 20-1999-0020723

The technical task to be achieved by the present invention is to provide an in-line flame blocking system that can minimize the spread of damage due to explosion or flame by monitoring the temperature in the hydrogen supply line and controlling the system.

The purpose is to provide an element disposed between the first and second hydrogen supply lines through which hydrogen is supplied, and to allow hydrogen to flow along the first and second hydrogen supply lines while allowing the flame to move in the reverse direction. A flame blocking device that blocks; A first device connection unit connecting the first hydrogen supply line and the flame blocking device; a second device connection unit connecting the second hydrogen supply line and the flame blocking device; A first lock fitting unit coupled to one side of the first device connection unit and including a first temperature sensor that detects the temperature within the first device connection unit adjacent to the first hydrogen supply line; A second lock fitting unit coupled to one side of the second device connection unit and including a second temperature sensor that detects the temperature within the second device connection unit adjacent to the second hydrogen supply line; an oxygen supply lock fitting unit coupled to at least one of the first and second lock fitting units and connected to an oxygen supply line that supplies oxygen in the oxygen tank; A solenoid valve provided in the oxygen supply line; and connected to the first and second temperature sensors through the first and second lock fitting units and connected to the solenoid valve, and operating the solenoid valve based on the sensing values of the first and second temperature sensors. This is achieved by an in-line flame blocking system characterized by including a control panel (CONTROL PANEL) equipped with a controller that controls ON/OFF.

a first line coupling lock fitting unit coupled to an end of the first device connection unit and coupled to the first hydrogen supply line; And it is coupled to the end of the second device connection unit, and may further include a second line coupling lock fitting unit coupled to the second hydrogen supply line.

The first lock fitting unit. The first device connection unit is provided in all of the second lock fitting unit, the oxygen supply lock fitting unit, the first line coupling lock fitting unit, and the second line coupling lock fitting unit, and is in contact with the unit. Alternatively, it may further include a functional leak prevention ring that prevents leakage to the contact surface with the second device connection unit.

The functional leakage prevention ring includes a ring body; a cushion portion provided within the ring body; and is formed to protrude from the outer wall of the ring body, and includes the first lock fitting unit, the second lock fitting unit, the oxygen supply lock fitting unit, the first line coupling lock fitting unit, and the second line coupling lock fitting unit. A contact surface between the lock fitting units and the first device connection unit or the second device connection unit may include a plurality of leakage prevention protrusions that contact at least two places to prevent leakage.

It is provided to protrude from all of the first lock fitting unit, the second lock fitting unit, the oxygen supply lock fitting unit, the first line coupling lock fitting unit, and the second line coupling lock fitting unit, The unit may further include a leak-prevention metal sealing protrusion that penetrates into a contact surface with the first device connection unit or the second device connection unit to prevent leakage.

It is connected to the controller and is provided on the control panel, and may further include an emergency notification unit that generates an explosion notification signal, and the controller receives temperature values at both ends of the element in real time from the first and second temperature sensors. In addition, the flame blocking device can be controlled by analyzing the temperature values received in real time, and the emergency notification unit can be controlled to operate according to the analysis results.

According to the present invention, the spread of damage due to explosion or flame can be minimized by controlling the system by monitoring the temperature in the hydrogen supply line.

1 is a configuration diagram of an in-line flame blocking system according to an embodiment of the present invention.
Figure 2 is an enlarged view of the area of the flame arrester of Figure 1;
Figure 3 is an enlarged view of area A of Figure 2.
Figure 4 is a top view of a functional leak prevention ring.
Figure 5 is a cross-sectional view taken along line BB in Figure 4.
Figures 6 (a) and (b) are diagrams showing the use state of the functional leakage prevention ring.
Figure 7 is a control block diagram of an in-line flame blocking system according to an embodiment of the present invention.
8 to 13 are operational diagrams of an in-line flame blocking system according to an embodiment of the present invention.
Figure 14 shows a graph of the elements and the first state displayed on the display of the control panel.
Figure 15 shows a graph of the elements and the second state displayed on the display of the control panel.
Figure 16 shows a graph of the elements and the third state displayed on the display of the control panel.

Specific structural or functional descriptions of the embodiments according to the concept of the present invention disclosed in this specification are merely illustrative for the purpose of explaining the embodiments according to the concept of the present invention. They may be implemented in various forms and are not limited to the embodiments described herein.

Since the embodiments according to the concept of the present invention can make various changes and have various forms, the embodiments will be illustrated in the drawings and described in detail in this specification. However, this is not intended to limit the embodiments according to the concept of the present invention to specific disclosed forms, and includes all changes, equivalents, or substitutes included in the spirit and technical scope of the present invention.

Terms such as first or second may be used to describe various components, but the components should not be limited by the terms. The above terms are used only for the purpose of distinguishing one component from another component, for example, without departing from the scope of rights according to the concept of the present invention, a first component may be named a second component and similarly a second component. A component may also be named a first component.

When a component is said to be "connected" or "connected" to another component, it is understood that it may be directly connected to or connected to that other component, but that other components may also exist in between. It should be. On the other hand, when it is mentioned that a component is “directly connected” or “directly connected” to another component, it should be understood that there are no other components in between. Other expressions that describe the relationship between components, such as "between" and "immediately between" or "neighboring" and "directly adjacent to" should be interpreted similarly.

The terms used in this specification are only used to describe specific embodiments and are not intended to limit the invention. Singular expressions include plural expressions unless the context clearly dictates otherwise. In this specification, terms such as “comprise” or “have” are intended to designate the presence of features, numbers, steps, operations, components, parts, or combinations thereof described in this specification, but are not intended to indicate the presence of one or more other features. It should be understood that it does not exclude in advance the existence or possibility of addition of elements, numbers, steps, operations, components, parts, or combinations thereof.

Unless otherwise defined, all terms used herein, including technical or scientific terms, have the same meaning as commonly understood by a person of ordinary skill in the technical field to which the present invention pertains. Terms as defined in commonly used dictionaries should be interpreted as having meanings consistent with the meanings they have in the context of the related technology, and unless clearly defined in this specification, should not be interpreted in an idealized or overly formal sense. No.

Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings attached to this specification.

Figure 1 is a configuration diagram of an in-line flame blocking system according to an embodiment of the present invention, Figure 2 is an enlarged view of the flame blocking device area of Figure 1, Figure 3 is an enlarged view of area A of Figure 2, and Figure 4 is a functional leakage A top view of the prevention ring, Figure 5 is a cross-sectional view taken along line B-B of Figure 4, Figures 6 (a) and (b) are a state diagram of the functional leakage prevention ring, and Figure 7 is an in-line flame according to an embodiment of the present invention. The control block diagram of the blocking system and FIGS. 8 to 13 are operational diagrams of the in-line flame blocking system according to an embodiment of the present invention.

Referring to these drawings, the in-line flame blocking system according to this embodiment monitors the temperature within the first and second hydrogen supply lines 11 and 12 to control the system to minimize the spread of damage caused by explosion or flame. do.

The in-line flame blocking system according to the present embodiment that can provide this effect includes a flame blocking device 120 and first and second device connection units 111 and 112, as mainly shown in FIGS. 1 and 2, and these It has a structure disposed between the first and second hydrogen supply lines 11 and 12 through which hydrogen is supplied. In addition, the in-line flame blocking system according to this embodiment further includes an oxygen tank 20 and a control panel 180.

The first and second hydrogen supply lines 11 and 12 are lines through which hydrogen is supplied. It is assumed that hydrogen is supplied from the first hydrogen supply line 11 to the second hydrogen supply line 12.

For reference, hydrogen gas is highly explosive at a concentration of 4 to 74% in air and 5 to 95% in chlorine compounds. The mixture spontaneously explodes with flame, heat or sunlight, and its spontaneous ignition temperature is approximately 500°C. Therefore, when a flame is formed due to an explosion, it is necessary to block the flame from being transmitted in the reverse direction, and for this purpose, a flame blocking device 120 is provided.

The flame blocking device 120 is disposed between the first and second hydrogen supply lines 11 and 12 and has a predetermined element 121 to connect the first and second hydrogen supply lines 11 and 12. It allows hydrogen to flow and blocks the reverse movement of the flame.

In other words, the flame blocking device 120 is a means of transmitting gas but preventing flame backfire or explosion. For this purpose, the flame blocking device 120 includes a plurality of elements 121. The elements 121 may be implemented in the form of crumpled metal ribbons. Elements 121 prevent flame backfire. An element support (ELEMENT SUPPORT) is provided to support the elements 121. Element support refers to structures such as bushes and rings.

First and second device connection units 111 and 112 are provided to install the flame blocking device 120 in-line between the first and second hydrogen supply lines 11 and 12.

The first device connection unit 111 is a structure that connects the first hydrogen supply line 11 and the flame blocking device 120, and the second device connection unit 112 is a structure that connects the second hydrogen supply line 12 and the flame blocking device 120. It is a structure that connects the device 120.

In this way, in this system, a flame blocking device 120 is placed in-line between the first and second hydrogen supply lines 11 and 12 as a means to prevent backfire of the flame in the event of a hydrogen explosion. The implementation of this system is For this purpose, several rock fitting units (ROCK FITTING UNIT, 130, 140, 1150, 151, 152) are provided for connection between structures. These include a first lock fitting unit 130, a second lock fitting unit 140, a lock fitting unit 150 for oxygen supply, a lock fitting unit 151 for first line coupling, and a lock fitting unit for second line coupling ( 152).

The first lock fitting unit 130 is coupled to one side of the first device connection unit 111. The first lock fitting unit 130 is provided with a first temperature sensor 131 that detects the temperature within the first device connection unit 111 adjacent to the first hydrogen supply line 11. The first temperature sensor 131 is connected to the controller 170 of the control panel 180.

The second lock fitting unit 140 is coupled to one side of the second device connection unit 112. The second lock fitting unit 140 is provided with a second temperature sensor 141 that detects the temperature within the second device connection unit 112 adjacent to the second hydrogen supply line 12. The second temperature sensor 141 is connected to the controller 170 of the control panel 180.

Ultimately, in this system, the first and second temperature sensors 131 and 141 are mounted only on the first and second lock fitting units 130 and 140, and the lock fitting unit 150 for oxygen supply and the lock fitting unit for combining the first line ( 151) and the second line coupling lock fitting unit 152.

The lock fitting unit 150 for oxygen supply is coupled to the second lock fitting unit 140. An oxygen supply line 21 that supplies oxygen in the oxygen tank 20 is connected to the lock fitting unit 150 for oxygen supply. The lock fitting unit 150 for oxygen supply may be connected to the first lock fitting unit 130, but considering that the explosion occurs on the second hydrogen supply line 12, the lock fitting unit 150 for oxygen supply ) is advantageous for being coupled to the second lock fitting unit 140.

A solenoid valve 155 is provided in the oxygen supply line 21. The operation of the solenoid valve 155 is controlled on/off by the controller 170.

The first line coupling lock fitting unit 151 is coupled to the end of the first device connection unit 111 and is coupled to the first hydrogen supply line 11. In addition, the second line coupling lock fitting unit 152 is coupled to the end of the second device connection unit 112 and is coupled to the second hydrogen supply line 12.

Meanwhile, when applying these lock fitting units (130, 140, 1150, 151, 152), leakage on the contact surface with the opposing structure must be prevented. Accordingly, the application of O-Rings, etc. can be considered, but it is difficult to completely prevent leakage with a simple structure using O-Rings. Accordingly, a functional leakage prevention ring 160 and a metal sealing protrusion 165 for leakage prevention are applied to this system. The functional leakage prevention ring 160 and the leakage prevention metal sealing protrusion 165 are applied to all of the lock fitting units 130, 140, 1150, 151, and 152.

The functional leakage prevention ring 160 is a first lock fitting unit 130 as shown in FIGS. 3 to 6. It is provided in all of the second lock fitting unit 140, the oxygen supply lock fitting unit 150, the first line coupling lock fitting unit 151, and the second line coupling lock fitting unit 152, and the corresponding units (130, 140, 1150, 151, 152) serves to prevent leakage on the contact surface with the first device connection unit 111 or the second device connection unit 112.

This functional leakage prevention ring 160 includes a ring body 161, a cushion portion 162 provided within the ring body 161, and a plurality of leakage prevention protrusions 163 protruding from the outer wall of the ring body 161. ) includes.

A plurality of leakage prevention protrusions 163 are formed to protrude from the outer wall of the ring body 161 and the first lock fitting unit 130. The second lock fitting unit 140, the lock fitting unit 150 for oxygen supply, the lock fitting unit 151 for first line coupling, the lock fitting unit 152 for second line coupling, and the corresponding units (130, 140, 1150) , 151, 152) prevents leakage by contacting at least two places on the contact surface with the first device connection unit 111 or the second device connection unit 112. In the case of this embodiment, the leakage prevention protrusion 163 is implemented in the form of three protrusions, so that the effect of applying three O-Rings can be expected. In addition, when the lock fitting units 130, 140, 1150, 151, and 152 are installed as shown in (b) of FIG. 6, the cushion portion 162 is pressed, so the three leakage prevention protrusions 163 are slightly spaced between the two structures. It can fit more closely. Therefore, it is very effective in preventing leakage. For reference, three leakage prevention protrusions 163 are shown, but there may be two or four or more. Accordingly, the scope of the present invention is not limited to the shape of the drawings. Figure 6 (a) is a top view of the functional leak prevention ring, and Figure 6 (b) is a side view of the functional leak prevention ring.

Applying such a functional leakage prevention ring 160 can provide a great effect in preventing leakage, but in this embodiment, a perfect leakage prevention function is provided by further applying the metal sealing protrusion 165 for leakage prevention.

The leakage prevention metal sealing protrusion 165 includes the first lock fitting unit 130, the second lock fitting unit 140, the oxygen supply lock fitting unit 150, the first line coupling lock fitting unit 151, and the second lock fitting unit 130. It is provided to protrude from all of the two line coupling lock fitting units 152, and is a contact surface with the first device connection unit 111 or the second device connection unit 112 that the corresponding units (130, 140, 1150, 151, 152) come into contact with. Be sure to prevent leakage while digging.

Meanwhile, the control panel 180 (CONTROL PANEL) is further applied to the in-line flame blocking system according to this embodiment.

The control panel 180 is connected to the first and second temperature sensors 131 and 141 through the first and second lock fitting units 130 and 140, and is connected to the solenoid valve 155, and the first and second temperature sensors ( It includes a controller 170 that controls ON/OFF the operation of the solenoid valve 155 based on the sensing value of 141).

Additionally, an emergency notification unit 181 is further installed in the control panel 180 along with a display (not shown). The emergency notification unit 181 is connected to the controller 170 and is provided in the control panel 180, and generates an explosion notification signal.

The controller 170 receives temperature values at both ends of the element 121 from the first and second temperature sensors 141 in real time, analyzes the received temperature values in real time, and controls the flame blocking device 120. , the emergency notification unit 181 is controlled to operate according to the analysis results. In addition, it controls the output of the graph displayed on the display of the control panel 180.

The controller 170 that performs this role may include a central processing unit (171, CPU), memory (172, MEMORY), and a support circuit (173, SUPPORT CIRCUIT).

In this embodiment, the central processing unit 181 receives temperature values at both ends of the element 121 from the first and second temperature sensors 141 in real time, and analyzes the temperature values received in real time to provide a flame blocking device ( 120), and may be one of various computer processors that can be applied industrially to control the operation of the emergency notification unit 181 according to the analysis results.

Memory 182 (MEMORY) is connected to the central processing unit 181. Memory 182 is a computer-readable recording medium that can be installed locally or remotely, for example, in a readily available storage medium such as random access memory (RAM), ROM, floppy disk, hard disk, or any other digital storage form. It may be at least one memory.

The support circuit 183 (SUPPORT CIRCUIT) is combined with the central processing unit 181 to support typical operations of the processor. This support circuit 183 may include a cache, power supply, clock circuit, input/output circuit, subsystem, etc.

In this embodiment, the controller 180 receives temperature values at both ends of the element 121 in real time from the first and second temperature sensors 141, analyzes the temperature values received in real time, and operates the flame blocking device 120. Meanwhile, the emergency notification unit 181 is controlled to operate according to the analysis results. This series of control processes can be stored in the memory 182. Typically, software routines may be stored in memory 182. Software routines may also be stored or executed by other central processing units (not shown).

Although the process according to the present invention has been described as being executed by software routines, it is also possible that at least some of the processes according to the present invention are performed by hardware. As such, the processes of the present invention may be implemented as software running on a computer system, as hardware such as an integrated circuit, or as a combination of software and hardware.

Hereinafter, the operation of the in-line flame blocking system according to this embodiment will be described with reference to FIGS. 8 to 13.

Figure 8 shows a general situation in which hydrogen flows along the first and second hydrogen supply lines 11 and 12. Then, as shown in Figure 9, an explosion occurs in the first and second hydrogen supply lines (11 and 12). As previously described, an explosion may form on the second hydrogen supply line (11, 12).

When an explosion occurs, a flame forms on the top of the element 121 of the flame blocking device 120, as shown in FIG. 10, and continuous combustion occurs. At this time, the first and second temperature sensors 131 and 141 around the flame blocking device 120 detect the temperature.

Meanwhile, the first and second temperature sensors 131 and 141 continuously check the temperature of the flame. For example, if the temperature rises above the set range for more than 1 minute, the controller 170 turns on the operation of the solenoid valve 155 as shown in FIG. 11. (ON) to supply oxygen to the line. As shown in Figure 12, oxygen is supplied into the first and second hydrogen supply lines 11 and 12, thereby increasing the oxygen concentration and creating an environment in which ignition cannot occur.

Next, as shown in FIG. 13, when the set temperature, for example, 150 to 200° C. or lower, is recognized as complete combustion, the controller 170 turns off the operation of the solenoid valve 155. Then, the oxygen supply is cut off, and hydrogen supply can proceed normally.

Meanwhile, the detailed process for temperature detection by the controller 170 will be further explained with reference to FIGS. 14 to 16.

Figure 14 shows a graph of the first state displayed on the display of the elements and the control panel, Figure 15 shows a graph of the second state displayed on the display of the elements and the control panel, and Figure 16 shows the graph of the elements and the control panel Shows the graph of the third state displayed on the display.

Let's learn more about the operation of the controller 170 with reference to these drawings and FIGS. 1 and 2.

Referring to FIGS. 1, 2, and 14, the first state refers to a state in which the first temperature value (T1) falls, rises again, and falls again to meet the second temperature value (T2). In Figure 14, the number of elements 121 is 5. Depending on the embodiment, the number of elements 121 may vary.

The first temperature value T1 is a value measured by the first temperature sensor 131. The first temperature sensor 131 is in contact with the first element 121-1 located at the right end among the elements 121 and measures the temperature of the first element 121-1. Generally, flames occur on the right side of the first element 121-1. Therefore, as shown in the graph, the first temperature value (T1) is high. The flame sequentially moves from the first element (121-1) to the second element (121-2), the third element (121-3), the fourth element (121-4), and the fifth element (121-5). move When the flame moves to the fifth element 121-5, backfire occurs.

The second temperature value T2 is a value measured by the second temperature sensor 141. The second temperature sensor 141 is in contact with the element 121-5 located at the left end of the elements 121 and measures the temperature of the element 121-5. When a flame occurs on the right side of the element 121-1, the flame has not yet moved from the elements 121, so the second temperature value T2 is relatively lower than the first temperature value T1.

In the first case, there is a possibility that the flame arrestor explodes within 30 minutes to 2 hours from the time the fire first breaks out. At this time, the probability that the flame blocking device 120 will be in the first state is within 5%.

In the first section (P1), the controller 170 determines whether the first temperature value (T1) among the temperature values (T1 and T2) is greater than or equal to a certain temperature (TH).

When the controller 170 determines that the first temperature value T1 is above a certain temperature TH, the controller 170 determines whether the first temperature value T1 decreases in the second section P2. To determine whether the first temperature value T1 is decreasing, it may be determined that the first temperature value T1 is decreasing when the temperature difference between two temperature values measured at different points in time is greater than a certain temperature. Each of the elements 121 is implemented in the form of a crumpled metal ribbon. In the process of manufacturing each of the elements 121, the crumpled metal ribbon may not be precisely arranged. The reason why the first temperature value T1 decreases is because the metal ribbon shape, which is not precisely arranged, is rearranged and the element 121-1 absorbs the flame, temporarily reducing the temperature.

When the controller 170 determines that the first temperature value T1 decreases, the controller 170 determines whether the first temperature value T1 increases again in the third section P3. To determine whether the first temperature value T1 is rising, it may be determined that the first temperature value T1 is rising when the temperature difference at different points in time is greater than a certain temperature. The reason why the first temperature value T1 rises again is because the rearranged metal ribbon-shaped element 121-1 rises due to the flame.

When the controller 170 determines that the first temperature value T1 rises again, the controller 170 determines whether the first temperature value T2 falls again in the fourth section P4.

In the fifth section P5, the controller 170 determines whether the first temperature value T1 falls again and meets the second temperature value T2 among the temperature values. To determine whether the first temperature value (T1) is falling, it can be determined that the first temperature value (T1) is falling when the temperature difference between two temperature values measured at different time points is greater than a certain temperature. there is. The first section (P1) to the fifth section (P5) can be set to an arbitrary time.

The second temperature value T2 gradually increases over time. This is because the heat of the flame of the element 121-1 is conducted.

When the controller 170 determines that the first temperature value T1 and the second temperature value T2 meet, the controller 170 analyzes that the flame blocking device 120 is in the first state.

When the controller 170 determines that the flame blocking device 120 is in the first state, the controller 170 controls the solenoid valve 155 to block oxygen supplied to the flame blocking device 120.

Referring to FIGS. 1, 2, and 14, the second state refers to a state in which the first temperature value (T1) falls and meets the second temperature value (T2). In the second state, there is a possibility that the flame arrestor explodes within 30 minutes. In other words, the second state means a state in which the flame is transmitted within a short period of time. The probability that the flame blocking device 120 will be in the second state is about 90%.

In the first section P1, the controller 170 determines whether the first temperature value T1 among the temperature values T1 and T2 is above a certain temperature.

When the controller 170 determines that the first temperature value T1 is above a certain temperature TH, the controller 170 determines whether the first temperature value T1 decreases in the second section P2.

In the third section (P3), when the controller 170 determines that the first temperature value (T1) does not rise again, the controller 170 meets the first temperature value (T1) and the second temperature value (T2). judge whether When the flame moves quickly, the first temperature value (T1) does not rise. When the temperature difference between two temperature values measured at different points in time is below a certain temperature, it can be determined that the first temperature value T1 does not rise again.

When the controller 170 determines that the first temperature value (T1) does not rise again and that the first temperature value (T1) and the second temperature value (T2) meet, the controller 170 operates the flame blocking device 120. is analyzed as the second state.

When the controller 170 determines that the flame blocking device 120 is in the second state, the controller 170 performs control to block the gas supplied to the flame blocking device 120. When the controller 170 determines that the flame blocking device 120 is in the second state, the controller 170 injects nitrogen gas into the flame blocking device 120 through a separate line connected to the flame blocking device 120. You can. For example, a nitrogen supply lock fitting unit (not shown) similar to the oxygen supply lock fitting unit 150 may be coupled to the lower part of the first device connection unit 111. The lock fitting unit for nitrogen supply may be combined with the separate line.

In the second state, since the flame moves quickly within the elements 121, there is a need to quickly control the flame.

Referring to Figures 1, 2, and 16, the third state refers to a state in which the first temperature value (T1) falls, rises again, and falls again, but does not meet the second temperature value (T2). . In the third state, there is no possibility that the flame blocking device 120 explodes. The probability that the flame blocking device 120 will enter the third state is about 5%.

The controller 170 determines whether the first temperature value (T1) among the temperature values (T1 and T2) is above a certain temperature (TH).

When the controller 170 determines that the first temperature value (T1) is above a certain temperature (TH), the controller 170 maintains the first temperature value (T1) and the second temperature value (T1) even if the first temperature value (T1) falls again. When determining that the temperature value T2 is not met, the controller 170 analyzes that the flame blocking device 120 is in the third state.

When the controller 170 determines that the flame blocking device 120 is in the third state, the controller 170 performs control to reduce the gas supplied to the flame blocking device 120.

In the first section P1, the controller 170 determines whether the first temperature value T1 among the temperature values T1 and T2 is above a certain temperature.

When the controller 170 determines that the first temperature value T1 is above a certain temperature TH, the controller 170 determines whether the first temperature value T1 decreases in the second section P2.

When the controller 170 determines that the first temperature value T1 decreases, the controller 170 determines whether the first temperature value T1 increases again in the third section P3. To determine whether the first temperature value T1 is rising, it may be determined that the first temperature value T1 is rising when the temperature difference between two temperature values measured at different points in time is greater than a certain temperature.

When the controller 170 determines that the first temperature value T1 rises again, the controller 170 determines whether the first temperature value T2 falls again in the fourth section P4.

In the fifth section (P5), the controller 170 determines whether the first temperature value (T1) falls again and meets the second temperature value (T2) among the temperature values.

When the controller 170 determines that the first temperature value T1 and the second temperature value T2 do not meet, the controller 170 analyzes that the flame blocking device 120 is in the third state.

When the controller 170 determines that the flame blocking device 120 is in the third state, the controller 170 performs control to block the gas supplied to the flame blocking device 120.

In the third state, unlike the second state, nitrogen gas is not introduced because there is no possibility of the flame blocking device 120 exploding. If nitrogen gas is uniformly introduced without distinguishing the state of the flame blocking device 120, nitrogen gas will be wasted and unnecessary actions such as replacement of the flame blocking device 120 will be necessary even when nitrogen gas injection is not necessary.

According to this embodiment, which operates based on the structure described above, the spread of damage due to explosion or flame can be minimized by controlling the system by monitoring the temperature within the first and second hydrogen supply lines 11 and 12. There will be.

As such, the present invention is not limited to the described embodiments, and it is obvious to those skilled in the art that various modifications and changes can be made without departing from the spirit and scope of the present invention. Therefore, it should be said that such modifications or variations fall within the scope of the claims of the present invention.

11: first hydrogen supply line 12: second hydrogen supply line
20: oxygen tank 21: oxygen supply line
111: first device connection unit 112: second device connection unit
120: Flame blocking device 121: Element
130: first lock fitting unit 131: first temperature sensor
140: second lock fitting unit 141: second temperature sensor
150: Lock fitting unit for oxygen supply 151: Lock fitting unit for first line connection
152: Lock fitting unit for second line connection 155: Solenoid valve
160: Functional leakage prevention ring 161: Ring body
162: Cushion part 163: Protrusion for preventing leakage
165: Metal sealing protrusion to prevent leakage 170: Controller
180: Control panel 181: Emergency notification unit

Claims (5)

A flame is disposed between the first and second hydrogen supply lines through which hydrogen is supplied, and has a predetermined element (ELEMENT) to allow hydrogen to flow along the first and second hydrogen supply lines while blocking reverse movement of the flame. blocking device;
A first device connection unit connecting the first hydrogen supply line and the flame blocking device;
a second device connection unit connecting the second hydrogen supply line and the flame blocking device;
A first lock fitting unit coupled to one side of the first device connection unit and including a first temperature sensor that detects the temperature within the first device connection unit adjacent to the first hydrogen supply line;
A second lock fitting unit coupled to one side of the second device connection unit and including a second temperature sensor that detects the temperature within the second device connection unit adjacent to the second hydrogen supply line;
An oxygen supply lock fitting unit coupled to at least one of the first and second lock fitting units and connected to an oxygen supply line that supplies oxygen in the oxygen tank;
A solenoid valve provided in the oxygen supply line;
It is connected to the first and second temperature sensors through the first and second lock fitting units and connected to the solenoid valve, and operates the solenoid valve based on the sensing values of the first and second temperature sensors. A CONTROL PANEL including a controller for ON/OFF control;
a first line coupling lock fitting unit coupled to an end of the first device connection unit and coupled to the first hydrogen supply line;
a second line coupling lock fitting unit coupled to an end of the second device connection unit and coupled to the second hydrogen supply line;
It is provided in all of the first lock fitting unit, the second lock fitting unit, the oxygen supply lock fitting unit, the first line coupling lock fitting unit, and the second line coupling lock fitting unit, and the unit is A functional leak prevention ring that prevents leakage on a contact surface with the first device connection unit or the second device connection unit; and
It is provided to protrude from all of the first lock fitting unit, the second lock fitting unit, the oxygen supply lock fitting unit, the first line coupling lock fitting unit, and the second line coupling lock fitting unit, It includes a leak-prevention metal sealing protrusion that prevents leakage by digging into the contact surface of the first device connection unit or the second device connection unit that the unit is in contact with,
The functional leak prevention ring is,
ring body;
a cushion portion provided within the ring body; and
The first lock fitting unit is formed to protrude from the outer wall of the ring body. The first device connection unit or the second lock fitting unit in contact with the second lock fitting unit, the oxygen supply lock fitting unit, the first line coupling lock fitting unit, and the second line coupling lock fitting unit. It includes a plurality of leak-prevention protrusions that contact at least two places on the contact surface with the device connection unit to prevent leakage,
The control panel is equipped with an emergency notification unit along with a display, and the emergency notification unit generates an explosion notification signal,
The controller receives temperature values at both ends of the element from the first and second temperature sensors in real time, analyzes the received temperature values in real time, and controls the flame blocking device, while controlling the fire protection device according to the analysis results. An in-line flame blocking system characterized by controlling the operation of the notification unit and controlling the output of the graph displayed on the display. delete delete delete delete

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