KR100897039B1 - A fire simulating experimental epuipment of tunnel that use hydrogen bubble happened in electrolysis - Google Patents

Abstract

The present invention relates to a fire reproducing experiment apparatus of a tunnel using hydrogen bubbles generated by electrolysis, and more specifically, to simulate the fire in the tunnel through a simulated fire test using hydrogen bubbles generated by electrolysis. By analyzing the smoke flow in accordance with the fire (hereinafter referred to as `` smoke '') caused by the actual fire, and analyzing the flow trend of the smoke according to the fire and experiments such as smoke flow during the operation of the ventilator The present invention relates to a fire reproducing experiment apparatus of a tunnel using hydrogen bubbles generated by electrolysis.

The present invention for achieving the above object is characterized in that it is composed of a base fixed to the ground, a fire reproducing unit installed on the upper portion of the base to reproduce the fire, and a liquid circulation unit for circulating the liquid in the fire reproducing unit.

Electrolysis, Hydrogen Bubble, Simulation Tunnel, Electric Car, Tunnel

Description

A fire simulating experimental epuipment of tunnel that use hydrogen bubble happened in electrolysis}

The present invention relates to a fire reproducing experiment apparatus of a tunnel using hydrogen bubbles generated by electrolysis, and more specifically, to simulate the fire in the tunnel through a simulated fire test using hydrogen bubbles generated by electrolysis. By analyzing the smoke flow in accordance with the fire (hereinafter referred to as `` smoke '') caused by the actual fire, and analyzing the flow trend of the smoke according to the fire and experiments such as smoke flow during the operation of the ventilator The present invention relates to a fire reproducing experiment apparatus of a tunnel using hydrogen bubbles generated by electrolysis.

In general, due to the geographical characteristics of Korea, where 70% of the country is a mountainous area, tunnels are constructed in a mountainous area so that vehicles can pass smoothly. In the case of such a conventional tunnel, a fire occurs in a vehicle or inside a tunnel. In case of emergency, the ventilation device for discharging high-temperature smoke diffused inside the tunnel is insufficient in domestic tunnels. And there was a big problem that the evacuated passengers choked and lost their lives.

In addition, in foreign countries, a ventilator is installed inside the tunnel to discharge hot smoke, which diffuses into the tunnel outside the tunnel in the event of an emergency due to a fire. Ventilation fan is installed in the duct installed in contact with the outside air in the ceiling of the tunnel without considering the gradient, and only the ventilation fan drive has a limitation in discharging smoke in the tunnel to the outside of the tunnel. Since the hot smoke spreads throughout the tunnel faster and faster than the time and discharge flow rate to the outside of the tunnel, this also diffuses into the tunnel before the smoke in the tunnel is completely discharged outside the tunnel. Smoke causes the passengers in the vehicle and the evacuated passengers to choke and lose their lives There was also a point.

In the case of the conventional ventilation device as described above, since the size and performance of the ventilation device varies according to the characteristics and conditions of the tunnel, it is very difficult to simply apply the conventional ventilation device to the domestic tunnel, and to install the ventilation device, There was also a cumbersome problem of redesigning and installing in accordance with the domestic tunnel situation.

In addition, since the fire simulation for verifying the ventilation performance of the tunnel under construction is done by computer simulation only, it is a hassle to apply a number of assumptions in addition to the actual conditions such as the tunnel gradient and the air flow inside the tunnel. In particular, the accuracy of fire simulation data using computer simulations is less accurate than the data obtained by performing fire simulations using model tunnels, model tracks and model railroad cars manufactured by miniaturizing actual tunnels and tracks and vehicles. Accordingly, there is also a problem such that the reliability by the data is greatly reduced.

Therefore, in recent years, by miniaturizing vehicles and tunnels, supplying smoke into the interior, simulated fire experiments in tunnels are performed under the same conditions as those caused by actual fires. We have secured evacuation routes through experiments and apply them to the actual tunnel construction.

However, in order to generate smoke to be supplied to the inside of the tunnel which has been reduced, conventionally, a flame is actually generated by using fuel, and the smoke thus generated is supplied to the inside of the tunnel to be reduced for use as a simulation fire experiment. Due to the negligence of the experimenter, a safety accident such as a burn or a fire at the test site is generated, and the simulation is performed by using the smoke, which makes it difficult to visually check the situation inside the tunnel.

In addition, there is a problem that it takes a lot of time to post-process and set up to prepare for the next simulation fire experiment after the simulation fire experiment in the tunnel.

The present invention has been made in order to solve the above problems, by using a tunnel made of a model to simulate the fire that is already being constructed or under construction by using hydrogen bubbles generated during the electrolysis to the actual fire and By supplying hydrogen bubbles under the same conditions, since the flame is not used as in the prior art, the post-treatment is simple after preparation and completion of the experiment, which saves the time of the simulation fire experiment and prevents the occurrence of a safety accident due to the flame. The purpose is to make it.

In addition, when performing a simulation fire test using a hydrogen bubble generated by electrolysis at the time of a simulation fire test for a tunnel, laser beams are irradiated to a test location, whereby hydrogen bubbles discharged from the simulation tunnel can be observed in detail. The purpose of the visualization device is to make it easy to identify trends in the movement of hydrogen bubbles due to fire.

In addition, a circulation tube for circulating the liquid contained inside the case is provided, and a pump is provided in the circulation tube, and a flow rate meter for measuring the flow rate of the liquid circulated in the circulation tube is provided to circulate the liquid using the pump. Simultaneously, the flow rate is controlled to enable the simulation device to operate as closely as possible in the actual situation when operating the ventilation system of the simulated tunnel so that more effective experimental data can be obtained.

In addition, by providing an inclination control unit that can adjust the inclination angle of the mock tunnel, the purpose is to enable various tunnel forms.

In addition, when the liquid circulated through the circulation pipe is supplied to the case again, the storage tank is supplied to the cover case in order to prevent the vibration of the pump from being transferred to the inside of the case, thereby not affecting the simulated tunnel fire reproduction experiment. The goal is to get accurate data.

The present invention for achieving the above object is characterized by consisting of a base which is fixed to the ground, a fire reproducing unit is installed on the upper portion of the base to reproduce the fire, mounted on the fire reproducing portion, the pump is provided with a circulation pipe do.

Here, the fire reproducing portion is mounted on the upper portion of the base is formed in a container shape is provided with a case in which the liquid is received therein, one side is accommodated in the inner side of the case, the outer tunnel mock tunnel fastened and fixed; It is provided on the inside of the case is characterized in that it consists of a hydrogen bubble generating unit for generating hydrogen bubbles by electrolysis, and a power supply for supplying a current to the hydrogen bubble generating unit.

Furthermore, the case is formed in a rectangular shape, the front and rear wall surface is formed of transparent glass, characterized in that the through-hole is formed in any one of both side walls.

In addition, one side of the mock tunnel is located in the interior of the case is formed with a liquid suction hole and a hydrogen discharge hole, the other side is fitted into the through hole of the case is provided to protrude outward to open the end protruding to the outside of the case It is characterized in that the circulation pipe is fastened.

And, the liquid suction hole is formed in the lower end of the mock tunnel, the hydrogen discharge hole is formed in the upper portion of the mock tunnel, characterized in that formed in the proximal position with the wall in the direction protruding out of the case do.

In addition, the through hole of the case is provided with a fastening fastener capable of flow, characterized in that the simulation tunnel is fitted to the fastening fastener.

In addition, the hydrogen bubble generating unit is characterized in that the "+", "-" electrodes are respectively provided to receive the external current is electrolyzed by the current to generate hydrogen bubbles.

Here, the "+" electrode is provided on the inner bottom surface of the case, the "-" electrode is provided on the inner bottom surface of the mock tunnel, characterized in that provided between the liquid suction hole and the hydrogen discharge hole. .

Further, the "+" electrode is graphite, the "-" electrode is characterized in that the copper plate.

In addition, a first honeycomb is fastened to the connection portion of the mock tunnel and the circulation pipe, one side is fastened to the first honeycomb, and the other side is further provided with a diffuser for fastening and fastening the circulation pipe.

In addition, the circulation pipe is further provided with a flowmeter for measuring the flow rate, the flowmeter is characterized in that it is provided to be located in the front portion of the pump.

In addition, the circulation pipe is further provided with a storage tank for supplying the circulated liquid to the case, the storage tank is characterized in that provided in the rear of the pump.

In addition, a second honeycomb is further provided in the circulation pipe, and the second honeycomb is installed between the diffuser and the flowmeter.

In addition, the upper portion of the base is characterized in that the angle adjusting unit for adjusting the angle of the mock tunnel is further provided.

Here, the angle adjuster is provided with a cover body installed on the upper portion of the base, the inner side of the cover body, is installed in the longitudinal direction, the screw shaft formed with a gear in the lower portion, and is coupled to the screw shaft to be movable A fluid having a support to protrude to the upper portion of the cover body, a support provided at an upper portion of the support of the fluid to fix the mock tunnel, and a gear installed at an upper portion of the base and engaged with a gear of the screw shaft. It is characterized by consisting of a motor.

On the other hand, it is characterized in that the laser is further provided for irradiating the laser light to the inside of the case.

Here, the laser is provided with a vertical frame protruding to correspond to each other to the upper portion of the case, characterized in that the horizontal frame is provided on the upper end of the vertical frame is installed in this horizontal frame.

Further, the lower end of the laser is characterized in that the convex lens for further irradiating the laser light is further provided.

The present invention configured as described above uses hydrogen bubbles generated at the time of electrolysis in order to simulate fire tests of tunnels already constructed or under construction using modeled tunnels by supplying hydrogen bubbles under the same conditions as actual fires. Because the flame is not used as in the prior art, the post-treatment after the experiment preparation and the completion of the experiment is simple, thereby saving time of the simulation fire experiment and preventing the occurrence of a safety accident due to the flame.

In addition, when performing a simulation fire test using a hydrogen bubble generated by electrolysis at the time of a simulation fire test for a tunnel, laser beams are irradiated to a test location, whereby hydrogen bubbles discharged from the simulation tunnel can be observed in detail. The visualization device has an effect of making it easy to grasp the tendency of the movement of hydrogen bubbles due to fire.

In addition, a circulation tube for circulating the liquid contained inside the case is provided, and a pump is provided in the circulation tube, and a flow rate meter for measuring the flow rate of the liquid circulated in the circulation tube is provided to circulate the liquid using the pump. At the same time, the flow rate can be adjusted to achieve the most similar shape of smoke flow to the operation of the ventilator in the event of a fire in a tunnel, thereby obtaining more effective experimental data.

In addition, by further comprising a tilt control unit for adjusting the inclination angle of the mock tunnel, there is an effect that can implement a variety of tunnel forms.

When the liquid circulated through the circulation pipe is supplied to the case again, the liquid of the storage tank is supplied to the case to prevent the vibration of the pump from being transferred to the inside of the case so as not to affect the simulation tunnel fire reproduction experiment. It is effective to obtain accurate data.

Hereinafter, a fire reproducing apparatus using microhydrogen bubbles generated by electrolysis according to the present invention will be described in detail with reference to the accompanying drawings.

1 is a perspective view showing a fire reproducing experimental apparatus of the tunnel using the hydrogen bubbles generated by the electrolysis according to the present invention, Figure 2 is a fire reproducing apparatus using hydrogen bubbles generated by the electrolysis according to the present invention. 3 is a perspective view showing a fire reproducing portion of the present invention, FIG. 4 is a cross-sectional view showing a fire reproducing portion of the present invention, and FIG. 5 is a cross-sectional view showing an angle adjusting portion of the present invention.

1 to 5, the fire reproducing experiment apparatus 100 of the present invention is provided with a base 110 which is fixed to the ground, the fire reproducing unit installed on the base 110 to reproduce the fire ( 210 and the liquid circulation unit 300 for circulating the liquid in the fire reproducing unit (210).

Here, the fire reproducing unit 210 is fixed to the upper portion of the base 110, is formed in a container shape is provided with a case 212, the liquid is contained therein.

Furthermore, the case 212 is formed in a square shape, and the front and rear surfaces are formed of front and rear glass 214 and 214a which are transparent glass, and the through hole 216 is formed in any one of both side walls. The fastening fixture 218 is fixedly coupled to the through hole 216.

In addition, a mock tunnel 220 is provided to accommodate one side inside the case 212.

That is, the mock tunnel 220 is formed in a rectangular shape so that one side portion is formed with a liquid suction hole 222 and a hydrogen discharge hole 224 formed inside the case 212, and the other side is the case ( 212 is inserted into the fastening fixture 218 fastened and fixed to the through hole 216 is provided to protrude outward, the end of the mock tunnel 220 protruding to the outside of the case 212 is provided to open.

Here, the liquid suction hole 222 is formed at the lower end of the mock tunnel 220, the hydrogen discharge hole 224 is formed on the top of the mock tunnel 220, the case 212 It is formed at a position close to the through hole 216.

In addition, a hydrogen bubble generator 230 is provided inside the case 212 to generate hydrogen bubbles by electrolysis.

Here, the hydrogen bubble generator 230 is provided with "+", "-" electrode 232, 234 is electrolyzed by the current applied to the external current to generate hydrogen bubbles.

Further, the "+" electrode 232 is provided on the inner bottom surface of the case 212, the "-" electrode 234 is provided on the inner bottom surface of the mock tunnel 220, the liquid suction It is provided between the ball 222 and the hydrogen discharge hole (224).

In addition, the "+", "-" electrode 232, 234 is a "+" electrode 232 is graphite, the "-" electrode 234 is to use a copper plate so that the electrolysis is good It is preferable.

In addition, a power supply unit 240 is connected to the “+” and “−” electrodes 232 and 234 of the hydrogen bubble generator 230 and the wire 242 to transmit an external current.

Here, the power supply 240 is provided on the outside of the case 212, may be installed on the upper portion of the base 110, or may be installed in a separate place.

Therefore, the current is supplied from the power supply unit 240 so that the electrolysis is performed through the currents by the liquid contained in the case 212 between the "+" and "-" electrodes 232 and 234. In this case, hydrogen bubbles are generated in the copper plate of the “−” electrode 234.

In addition, a liquid circulation unit 300 is mounted to the simulation tunnel 220 of the fire reproducing unit 210 to circulate the liquid, wherein the liquid circulation unit 300 protrudes out of the case 212. A first honeycomb 312 having a honeycomb-shaped through hole is installed at an end of the mock tunnel 220, and a diffuser 314 is fastened to the first honeycomb 312 and connected to the diffuser 314. However, the pump 316 is provided at a predetermined position so that the end portion is provided with a circulation tube 310 in communication with the inner portion of the case 212.

Here, a flow rate meter capable of measuring the flow rate of the liquid circulated through the circulation pipe 310 between a predetermined position of the circulation pipe 310, that is, between the pump 316 and the first honeycomb 312 ( 318 is further provided.

Furthermore, a second honeycomb 320 is provided on the circulation pipe 310 between the first honeycomb 312 and the flow meter 318 to make the flow rate of the liquid circulated into the circulation pipe 310 the same and more accurate. This can be measured by the flow meter 318.

In addition, the liquid circulated in a predetermined position between the connection part of the case 212 and the pump 316 is stored and supplied to the case 212 so that the liquid circulated in the fire reproducing unit 210 is a fire reproducing unit 210. The storage tank 322 is further provided so as to suppress the influence of the flow rate of the liquid to the maximum.

Further, an angle adjusting unit 410 is further provided on the base 110 to adjust the angle of the mock tunnel 220.

Here, the angle adjusting unit 410 is provided with a cover body 412 is installed on the upper portion of the base 110, is provided on the inside of the cover body 412, is installed in the vertical direction, gears at the bottom A screw shaft 414 having a 416 formed therein is provided, and a fluid body 418 having a support 420 is formed to be coupled to the screw shaft 414 so as to protrude upward from the cover body 412. do.

Furthermore, a fixing stand 422 is provided on the support 420 of the fluid 418 and the mock tunnel 220 is fixed. The fixing stand 422 is provided on the base 110, and the screw shaft 414 of the screw shaft 414 is provided. A motor 426 is provided with a gear 424 that meshes with the gear 416.

In addition, the laser 510 for irradiating the laser light to the inside of the case 212 of the fire reproducing unit 210 is further provided.

Here, the laser 510 is formed to correspond to the vertical frame 215 on the front and rear glass 214 (214a) of the case 212, the horizontal frame (215) between the vertical frame (215) 215a is formed and the laser 510 is fixed to the horizontal frame 215a.

In addition, the convex lens 512 is further mounted so that the laser beam irradiated from the laser 510 can be irradiated to the inside of the case 212 widely.

 Therefore, the laser beam irradiated from the laser 510 passes through the convex lens 512 and is irradiated to the inner front surface of the case 212 or a position to be tested.

Referring to the relationship between the fire reproducing experimental apparatus of the tunnel using hydrogen bubbles generated by the electrolysis according to the present invention configured as described above are as follows.

Figure 6 is a schematic diagram showing the operation of the fire reproducing experimental apparatus of the tunnel using hydrogen bubbles generated by the electrolysis according to the present invention.

As shown therein, the fire reproducing experiment apparatus 100 of the present invention first transmits a current from the power supply unit 240 to the "+" and "-" electrodes 232 and 234 through the wire 242. When each of the power is applied, the electrolysis is performed inside the case 212 by the applied current, whereby hydrogen is generated in the copper plate of the "-" electrode 234 by the electrolysis.

As the hydrogen generated in the “−” electrode 234 rises due to the electrolysis, bubbles are generated.

As such, the hydrogen bubbles generated by the electrolysis are spread to the inner space of the mock tunnel 220, and some of them are discharged to the inner space of the case 212 through the hydrogen discharge hole 224.

When the diffuser 314 is operated in a state where hydrogen bubbles are generated, the liquid contained in the case 212 is transferred to the circulation tube 310 through the liquid suction hole 222 of the simulation tunnel 220. Will move.

In this case, the airflow phenomenon generated when a fire occurs in the actual tunnel by the flow velocity of the liquid moving to the circulation pipe 310 can be similarly implemented in the simulation tunnel 220.

In addition, the ventilation flow rate in the simulation tunnel 220 is implemented, and the ventilation flow rate is measured by the flow rate meter 318 to adjust the flow rate according to the experimental environment to implement the experimental conditions.

In this case, when the flow rate is measured by the flow meter 318, the liquid passes through the second honeycomb 320 to adjust the flow of the liquid, thereby enabling a more accurate flow rate measurement.

Therefore, by accurately analyzing the flow trend and reproducibility of the smoke in the tunnel in the event of a fire in a tunnel already constructed or under construction by using hydrogen bubbles generated by electrolysis, the safe preparation of the passenger and the evacuation of the evacuated passenger You can protect your life.

In this case, when a fire in a tunnel is implemented by using hydrogen bubbles generated by electrolysis, laser light is irradiated to a location where hydrogen bubbles are generated, thereby facilitating a tendency for the movement of hydrogen bubbles by using a visualization device (not shown). This can lead to more accurate experimental data.

On the other hand, the operation of the pump 316 is more smoothly the flow of the liquid circulated to the circulation tube 310, the liquid circulating the circulation tube 310 passes through the storage tank 322 again the case ( By being supplied to the inside of 212, the vibration generated by the operation of the pump 316 is transmitted to the case 212 in the storage tank 322 to block the vibration of the pump 316 to the case 212 The transmission is prevented from affecting the experiment in the fire reproducing unit 210.

In addition, when the motor 426 is operated, the screw shaft 414 meshed between the gears 416 and 424 rotates in one direction, and moves the fluid 418 upwards. As the 418 moves upward, one side of the mock tunnel 212 seated on the stator 422 is raised.

By adjusting the angle of the simulation tunnel 220 to the experimental conditions by the forward and reverse rotation of the motor 426, it is possible to implement more accurate experimental conditions.

Thus, prior to the fire test of the simulation tunnel 220, the inclination angle is adjusted according to the actual tunnel gradient.

In this way, in order to observe the flow trend of hydrogen bubbles at a constant illuminance according to the fire in the simulation tunnel 220, laser beams are irradiated to visualize the flow of hydrogen bubbles with a visualization device, and the data are recorded by moving pictures and still images. This data can be used to accurately analyze the flow trends and reproducibility of smoke in tunnels in the event of a fire in a tunnel that is already being constructed or under construction. In addition, it is possible to verify the ventilation performance of the ventilation equipment of the tunnel more accurately in advance, and furthermore, to achieve a fire safety design in the construction of a long tunnel.

In the above, a preferred embodiment of a fire reproducing experiment apparatus of a tunnel using hydrogen bubbles generated by electrolysis according to the present invention has been described, but the present invention is not limited thereto, and the claims and the detailed description of the invention and Various modifications can be made within the scope of the accompanying drawings, which also belong to the present invention.

The present invention relates to a fire reproducing experiment apparatus of a tunnel using hydrogen bubbles generated by electrolysis, and more specifically, to simulate the fire in the tunnel through a simulated fire test using hydrogen bubbles generated by electrolysis. By analyzing the smoke flow in accordance with the fire (hereinafter referred to as `` smoke '') caused by the actual fire, and analyzing the flow trend of the smoke according to the fire and experiments such as smoke flow during the operation of the ventilator The present invention relates to a fire reproducing experiment apparatus of a tunnel using hydrogen bubbles generated by electrolysis.

1 is a schematic perspective view showing an apparatus for reproducing a fire of a tunnel using hydrogen bubbles generated by electrolysis according to the present invention.

Figure 2 is a front view showing a fire reproducing apparatus using hydrogen bubbles generated by the electrolysis according to the present invention.

Figure 3 is a perspective view of the fire reproducing portion of the present invention.

Figure 4 is a cross-sectional view showing a fire reproducing portion of the present invention.

Figure 5 is a cross-sectional view showing the angle adjustment portion of the present invention.

Figure 6 is a schematic diagram showing the working relationship of the fire reproducing experimental apparatus of the tunnel using hydrogen bubbles generated by the electrolysis according to the present invention.

[Description of Symbols for Main Parts of Drawing]

100: fire reproducing apparatus 110: base

210: fire reproducing unit 212: case

214, 214a: front and rear glass 216: through hole

218: fastening fixture 220: mock tunnel

222: liquid suction hole 224: hydrogen discharge hole

230: hydrogen bubble generating unit 232, 234: "+", "-" electrode

240: power supply 242: electric wire

300: Achenchen circulation 310: circulation tube

312: first honeycomb 320: second honeycomb

314: Diffuser 316: Pump

318: flow meter 322: storage tank

410: angle adjuster 412: cover body

414: screw shaft 416, 424: gear

418: fluid 420: support

422: holder 426: motor

Claims (20)

A base installed on the ground, a fire reproducing unit installed on top of the base to reproduce the fire, and a liquid circulation unit for circulating liquid in the fire reproducing unit, The fire reproducing unit is mounted to the upper portion of the base is formed in a container shape is provided with a case in which the liquid is received therein, the one side is accommodated in the inner side of the case, the outer tunnel is connected to the circulating pipe fixed to the case, the case It is provided in the inner side of the hydrogen bubble generating portion is generated by the hydrogen bubbles by electrolysis, A first honeycomb is fastened to the connection portion of the mock tunnel and the circulation pipe, one side is fastened to the first honeycomb, and the other side of the hydrogen is generated by electrolysis, further comprising a diffuser for fastening and fastening the circulation pipe. Experimental apparatus for fire reproduction of tunnel using bubbles. delete The method of claim 1, The fire reproducing unit is a fire reproducing experiment apparatus using a hydrogen bubble generated by electrolysis, characterized in that the power supply for supplying a current to the hydrogen bubble generating unit is further configured. The method of claim 1, The case is formed in a square shape, the front and rear wall surfaces are formed of transparent glass, through-holes formed on any one of the two side walls, the fire reproducing experiment apparatus using hydrogen bubbles generated by electrolysis The method of claim 1, One side of the mock tunnel is positioned to form a liquid suction hole and a hydrogen discharge hole in the inner side of the case, the other side is inserted into the through hole of the case is provided to protrude to the outside, the end protruding to the outside of the case is open and circulated Fire reproducing experimental apparatus of the tunnel using hydrogen bubbles generated by electrolysis, characterized in that the pipe is fastened. The method of claim 5, wherein The liquid suction hole is formed in the lower end of the mock tunnel, the hydrogen discharge hole is formed in the upper portion of the mock tunnel, the electricity characterized in that it is formed in close proximity to the wall in the direction protruding out of the case Experimental apparatus for fire reproduction of tunnel using hydrogen bubbles generated by decomposition. The method according to any one of claims 3 to 6, The through hole of the case is provided with a fastening fastener capable of flow, the simulation apparatus for fire reproduction of the tunnel using hydrogen bubbles generated by electrolysis, characterized in that the simulation tunnel is fitted to the fastening fastener. The method of claim 1, The hydrogen bubble generating unit is a tunnel of the hydrogen bubble generated by the electrolysis, characterized in that each of the "+", "-" electrode which is electrolyzed by the current receives the external current to generate the hydrogen bubbles are provided. Fire Reproduction Experiment Device. The method of claim 8, The "+" electrode is provided on the inner bottom surface of the case, the "-" electrode is provided on the inner bottom surface of the mock tunnel, the electrolysis, characterized in that provided between the liquid suction hole and the hydrogen discharge hole Experimental apparatus for fire reproduction of tunnel using hydrogen bubbles generated by The method of claim 9, The "+" electrode is graphite, and the "-" electrode is a copper plate, characterized in that the fire regeneration experimental apparatus of the tunnel using hydrogen bubbles generated by electrolysis. delete The method of claim 1, The liquid circulation unit is connected to the mock tunnel and the circulation pipe circulating the liquid supplied to the fire reproducing portion and the fire of the tunnel using hydrogen bubbles generated by electrolysis, characterized in that the pump circulating the liquid of the circulation tube Reproduction experiment device. The method of claim 12, The circulation pipe is further provided with a flow rate meter for measuring the flow rate, the flow rate meter is a fire reproducing experiment apparatus using a hydrogen bubble generated by electrolysis, characterized in that provided in the position in the front of the pump. The method of claim 12, The liquid circulation unit is further provided with a storage tank for storing the circulated liquid and supplying it to the case, the storage tank is a tunnel using hydrogen bubbles generated by electrolysis, characterized in that provided in the rear of the pump. Fire Reproduction Experiment Device. The method of claim 12, A second honeycomb is further provided in the liquid circulation unit, and the second honeycomb is a fire reproducing experiment apparatus using hydrogen bubbles generated by electrolysis, characterized in that installed between the diffuser and the flow meter. The method according to any one of claims 1, 3 to 6, 8 to 10, 12 to 15, An apparatus for reproducing a tunnel using hydrogen bubbles generated by electrolysis, characterized in that an angle adjusting unit is installed on the base to adjust the angle of the simulation tunnel. The method of claim 16, The angle control unit and the cover body is installed on the upper portion of the base, A screw shaft provided inside the cover body and installed in a vertical direction and having a gear formed at a lower portion thereof; A fluid fluidly coupled to the screw shaft and provided with a support to protrude upwardly of the cover body; A fixing stand provided on the support of the fluid to fix the mock tunnel; An apparatus for reproducing a tunnel using hydrogen bubbles generated by electrolysis, characterized in that the motor is provided on the base and has a gear that meshes with the gear of the screw shaft. The method of claim 1, Fire reproducing experimental apparatus of a tunnel using hydrogen bubbles generated by electrolysis, characterized in that the laser is further provided to irradiate the laser light to the inside of the case. The method of claim 18, The laser is provided with a vertical frame protruding to correspond to each other to the upper portion of the case, the upper portion of the vertical frame is provided with a horizontal frame is installed in the horizontal frame tunnel using hydrogen bubbles generated by electrolysis Fire Reproduction Experiment Device. The method of claim 19, The lower end of the laser is a convex lens for further irradiating a laser light is further characterized in that the fire reproduction experiment apparatus of the tunnel using hydrogen bubbles generated by electrolysis.

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