WO2016080590A1 - Interactive fire drill simulation system - Google Patents

Abstract

The present invention relates to an interactive fire drill simulation system and, particularly, to an interactive fire drill simulation system in which a person, who intends to experience fire fighting, uses a fire extinguisher on a fire image outputted on a screen by an image output unit, the interactive fire drill simulation system comprising: a fire extinguisher having a laser emitting unit for emitting a laser at a fire image; a photographing unit for photographing the image at which the laser is emitted; a control device for controlling, overall, the interactive fire drill simulation system; a hot air blower adjusting the strength of heat according to the size of a flame image displayed on the fire image, and jetting out the heat; and a lighting unit for adjusting brightness according to the size of the flame image.

Description

Digestive fire drill simulation system

The present invention relates to a tangible fire training simulation system, which can be used in the game format to learn how to use a fire extinguisher and how to respond to the fire and how to use a fire extinguisher to experience a fire suppression on the fire image output by the image output unit. It is related to a immersive fire drill simulation system.

In general, various types of simulation systems have been developed for disaster experience or fire drills. These systems typically simulate a fire situation that is close to the actual situation, using a simulator to allow firefighters to conduct fire drills or to allow the general public to experience the fire site.

Recently, there is a disaster experience education system that enables the experience facility to be switched between the public mode and the expert mode, so that it can be applied to the training of disaster experts such as firefighters and children and adults. The disaster experience education system has been proposed in Korea Patent Registration Publication No. 10-0865028, but the domestic registration Patent Publication No. 10-0865028 simply to experience the disaster, such as fire to suppress the fire suppression There is a problem that cannot be experienced.

The problem to be solved by the present invention is to provide a tangible fire training simulation system that can be used by a child or an adult experienced person to experience the fire suppression in the fire image output to the image output unit to cope with the fire by using a fire extinguisher.

In order to solve the above problems, the present invention is a haptic fire training simulation system using a fire extinguisher in the fire image displayed on the screen, the image output unit for outputting the fire image; A fire extinguisher equipped with a laser irradiation unit for irradiating a laser onto a fire image output by the image output unit; A photographing unit which photographs an image irradiated with the laser on a fire image output by the image output unit; A hot air fan for injecting heat corresponding to the size of the flame image; And comparing the flame image with a fire image on which the laser irradiator irradiates the fire image to display a fire image and outputting an operation signal of the fire extinguisher and controlling a heat of the hot air blower. Can provide.

The flame image may include a flame region divided into a plurality of regions. A fire extinguishing time corresponding to the laser irradiation time may be set in the plurality of flame regions for each region.

If the laser is located in any one of a plurality of regions in the flame image, the controller may control to output the next flame image after the set extinguishing time corresponding to the region.

The haptic fire training simulation system may further include a storage unit for storing the fire image.

The haptic fire training simulation system may further include an illumination unit whose brightness is adjusted according to the size of the flame image.

The fire extinguisher body can be filled with fog liquid; An operation handle formed on the body; An injection nozzle coupled to the body and having the laser irradiator formed thereon; A supply line for supplying air supplied from an air compressor for generating air into the body; And it may include an on-off valve for opening and closing the supply line.

The fire extinguisher body can be filled with fog liquid; A fog liquid container installed in the body and filled with fog liquid; A heater filled in the fog liquid container and vaporizing by applying heat to the fog liquid supplied to the spray nozzle; A connection line connecting the fog liquid container and the spray nozzle; A spiral tube provided in the connection line and positioned inside the heater to receive heat from the heater; It may include a heat insulating material provided between the outer circumferential surface of the heater and the inner circumferential surface of the body and the opening and closing valve for opening and closing the connection line.

The fire extinguisher is provided with the laser irradiation part in the front end of the injection nozzle of the fire extinguisher, the laser irradiation part is provided in the front end of the injection nozzle; An inner tube which is inserted and fixed to the inside of the exterior and has a through hole formed at a rear side opposite to the front side; And a fixing member provided between the laser irradiation member provided inside the inner tube and the outer circumferential surface of the laser irradiation member and the inner circumferential surface of the inner tube to fix the laser irradiation member to the inner side of the inner tube.

In the haptic fire training simulation system according to the present invention, a fire extinguishing situation in which a child or an adult experienced person who wants to experience fire suppression in a fire image outputted on a screen by using an extinguisher using a fire extinguisher, may spread to a large accident. You can experience.

In addition, the immersive fire drill simulation system enables fire suppression experiences regardless of location or time at local fire departments, including local fire departments, the firefighting disaster prevention agency, children's experience centers, national kindergartens, and day care centers.

The immersive fire drill simulation system is a purely domestic technology that saves money and can be distributed at a low price, which has a general effect that can be used in any educational facility.

1 is a view schematically showing a tangible fire training simulation system according to an embodiment of the present invention.

Figure 2 is a block diagram showing a control device of the haptic fire training simulation system shown in FIG.

3 is an external perspective view of the control device shown in FIG.

Figure 4 is a left side cross-sectional view showing an embodiment of a fire extinguisher in the tangible fire training simulation system.

Figure 5 is a right side view showing an embodiment of a fire extinguisher in the tangible fire training simulation system.

6 is a partially enlarged cross-sectional view schematically showing a state in which the laser irradiation part of the fire extinguisher of the haptic fire training simulation system is separated from the injection nozzle.

7 is a cross-sectional view taken along line AA of FIG. 6.

8 is a partially enlarged cross-sectional view schematically showing a state in which the laser irradiation part of the fire extinguisher of the haptic fire drill simulation system is separated from the injection nozzle.

9 is a flowchart illustrating an example of a simulation method using a tangible fire drill simulation system according to an embodiment of the present invention.

10 is a flowchart illustrating another example of a simulation method using a tangible fire drill simulation system according to an embodiment of the present invention.

11 is a view showing a flame image of the simulation method shown in FIG.

Haptic fire training simulation system, the image output unit for outputting a fire image including the flame image; A fire extinguisher equipped with a laser irradiation unit for irradiating a laser onto the fire image; A photographing unit which photographs the image irradiated with the laser; Compared with the hot air blower that injects the heat corresponding to the size of the flame image and the fire image of the flame image and the laser image irradiated by the laser irradiation unit to the fire image outputs the operation signal of the fire extinguisher, and the heat of the hot air fan It may include a control unit for controlling.

Hereinafter, the description of the present invention with reference to the drawings is not limited to specific embodiments, and various changes may be made and various embodiments may be provided. In addition, the contents described below should be understood to include all transformations, equivalents, and substitutes included in the spirit and technical scope of the present invention.

In the following description, terms such as “first” and “second” are terms used to describe various components, and are not limited in themselves, and are used only to distinguish one component from other components.

Like reference numerals used throughout the present specification refer to like elements.

As used herein, the singular forms "a", "an" and "the" include plural forms unless the context clearly indicates otherwise. In addition, the terms "comprise", "comprise" or "have" described below are intended to designate that the features, numbers, steps, operations, components, parts, or combinations thereof described in the specification exist. It is to be understood that it does not exclude in advance the possibility of the presence or the addition of one or more other features or numbers, steps, actions, components, parts or combinations thereof.

Hereinafter, an embodiment of the present invention will be described in detail with reference to FIGS. 1 to 11.

1 is a view schematically showing a tangible fire training simulation system according to an embodiment of the present invention.

The haptic fire training simulation system according to an embodiment of the present invention may include a screen 110, a fire extinguisher 30, an air compressor 301, a hot air fan 70, an illumination unit 80, and a control device 100.

In detail, the screen 110 may display a fire image output from the control device 100.

Fire extinguisher 30 may spray the mist. The fire extinguisher 30 may simultaneously spray mist and laser onto the fire image displayed on the screen 110.

The air compressor 301 may inject air into the fire extinguisher 30. The air compressor 301 may be operated by engine driving or electric driving. The air compressor 301 injects air into the fire extinguisher 30 while operating under the control of the control device 100. For example, the air compressor 301 may supply air into the fire extinguisher 30 through a supply line provided between the body of the fire extinguisher 30 and the air compressor 301. The air compressor 301 may be reusable to avoid one-time use of the fire extinguisher 30.

The hot air blower 70 may include a hot wire coil and a fan to blow out heat to the outside. The hot air blower 70 may adjust the intensity of the hot air according to the size of the flame image. For example, the hot air fan 70 may be operated by the controller 50 so that the intensity of heat decreases when the flame image output on the screen 110 decreases, and the intensity of heat increases when the flame image increases. The hot air fan 70 may be provided in plurality. For example, the hot air blower 70 may be provided as the number of flames of the fire image displayed on the screen 110. Each hot air fan 70 may supply a user with hot air having different heat intensities according to the size of each flame image. The hot air fan 70 has an effect of feeling the heat of the flame at the fire site.

The lighting unit 80 may adjust brightness according to the size of the flame image displayed on the fire image. The lighting unit 80 may reduce the brightness when the size of the flame image is reduced, and also increase the brightness when the flame image is large. The lighting unit 80 may be provided in plurality in order to increase or decrease the variable effect of brightness. The lighting unit 80 has an effect that can give life to the fire scene.

The control device 100 may output a fire image on the screen 110. The control device 100 may capture a fire image irradiated with a laser on the fire image output on the screen 110. The control device 100 compares the fire image output to the screen 110 with the photographed fire image to specify the position of the leisure. The control device 100 compares whether the location of the specified laser beam is within the range of the flame image included in the fire image. As a result of the comparison, the control device 100 outputs the operation signal of the fire extinguisher 30 to the fire extinguisher 30 until the laser is located within the range of the flame image. If the laser is located in the range of the flame image, the control device 100 may output a stop signal of the fire extinguisher 30 to the fire extinguisher 30.

The control device 100 may control the hot air fan 70. For example, the control device 100 outputs an operation signal for adjusting the intensity of the hot air according to the size of the captured flame image.

The control device 100 may control the lighting unit 80. For example, the control device 100 outputs an operation signal for adjusting the brightness of the lighting unit according to the size of the captured flame image.

The control device will be described in more detail with reference to FIGS. 2 and 3 below.

FIG. 2 is a block diagram illustrating a control device of the tangible fire training simulation system shown in FIG. 1, and FIG. 3 is an external perspective view of the control device shown in FIG. 1.

2 and 3, the control device 100 may include an image output unit 10, a photographing unit 20, a storage unit 40, and a controller 50. In addition, although not shown in the drawing, the control device 100 may include a power button, a volume button, a speaker, and a laser controller.

In detail, the image output unit 10 may display the fire image stored in the storage unit 40 on the screen 110. The image output unit 10 may be a projector device. The image output unit 10 may be displayed by a monitor or other external device. The image output unit 10 may be displayed by a connection cable or a wireless device using Wi-Fi and Bluetooth, not a projector. The image output unit 10 may be located outside the control device 100.

The photographing unit 20 may photograph a fire image in which a laser is displayed. The photographing unit 20 may send the photographed image to the storage unit 40. The photographing unit 20 may be a CCD camera.

The storage unit 40 may store a fire image displayed on the screen 110 and a fire image on which the laser shown in FIG. 11 is displayed. The storage unit 40 may store the range of the flame image and the time set in each range. The storage unit 40 may store software for comparing and calculating a fire image and a fire image on which a laser is displayed. The storage unit 40 may store a plurality of applications such as fire generating graphics software, laser location tracking software, fire extinguisher control software, and the like. The storage unit 40 may be a hard disk or flash memory. The storage unit 40 is an auxiliary memory device that the control unit 50 can load and utilize.

The controller 50 may control an operation signal of the image output unit 10 displayed on the screen 110 to output a fire image. The controller 50 may control an operation signal of the photographing unit 20 to photograph the fire image irradiated with the laser. The controller 50 may output an operation signal of the fire extinguisher 30 by comparing the fire image in which the laser image irradiated with the flame image and the fire image is displayed. The controller 50 may control an operation signal of the hot air blower 70 for injecting heat corresponding to the size of the flame image. The controller 50 may control an operation signal of the lighting unit 80 whose brightness is adjusted according to the size of the flame image. The controller 50 may control an operation signal such as software stored in the storage 40 or the storage 40. The controller 50 may control the overall operation of the control device 100.

The power button is an operation button of the control device 100. The operation of the power button may operate with an external remote control by the infrared sensor 11. The power button may be located at the lower rear side of the control device 100. The location of the power button may be located at the top or the outside of the user's convenience.

The speaker can output sound. The speaker may be installed on the bottom surface of the control device 100. Speakers may be provided in plurality on the outer surface or the top surface to increase the amplification of the sound. The speaker may be further provided on one side of the fire extinguisher to allow the experienced person to hear the sound in more detail.

The volume button may control the sound of the speaker. The operation of the volume button may be operated by the infrared remote sensor 11 as an external remote controller. The volume button may be located on the top surface or the outside surface of the user's convenience.

The laser controller may control the operation signal of the laser irradiation unit 25 and the operation signal of the air compressor 301 by the operation signal of the controller 50.

 The laser controller can have two connecting cables. Two connection cables of the laser controller may be connected to the air compressor 301 and the laser irradiator 25, respectively.

Figure 4 is a left side cross-sectional view showing an embodiment of the fire extinguisher of the haptic fire training simulation system.

Referring to FIG. 4, the fire extinguisher 30 may include a body 300, a supply line 302, an injection nozzle 311, and an open / close valve 303.

Specifically, the body 300 may include a fog liquid container.

An operating handle 309 and an injection nozzle 311 may be provided at an upper portion of the body 300. The supply line 302 may be provided between the body 300 and the air compressor 301 to supply air generated by the air compressor 301 to the inside of the body 300.

The front end of the supply line 302 may be connected to the rear side of the air compressor 301 opposite to the front side of the air compressor 301 so as to communicate with the air compressor 301.

The rear end of the supply line 302 may be vertically penetrated through the bottom center of the body 300 and introduced into the body 300 to a predetermined length.

The on-off valve 303 may be configured as a solenoid valve or the like. The open / close valve 303 may be located inside the body 300 in a state provided at the rear end of the supply line 302. The open / close valve 303 may open and close the supply line 302 by the controller 50.

Next, although not shown in the drawings, the operation handle 309 of the fire extinguisher 30 may be provided with an operation switch, such as a push button method.

The injection nozzle 311 may include a laser irradiation part 25. The spray nozzle 311 may also use the laser irradiation unit 25 and the one-touch coupling method or other easy coupling method.

The air compressor 301 may supply air to the inside of the body 300. The air compressor 301 may be connected to the supply line 302 formed under the body 300 of the fire extinguisher 30 through a cable. The air compressor 301 is a device for refilling air in the body 300 to avoid one-time use of the fire extinguisher 30.

5 is a right side cross-sectional view showing an embodiment of a fire extinguisher in the tangible fire training simulation system.

Referring to FIG. 5, the fire extinguisher 30 includes a body 300, a fog liquid container 304, a heater 305, a connection line 306, a spiral tube 307, a heat insulating material 308, and an open / close valve 303. It may include.

The body 300 may include a fog liquid container.

The fog liquid container 304 is installed inside the lower front side of the body 300. Fog liquid may be filled in the fog liquid container 304. The opening and closing door 300a may be provided on the lower front side outer circumferential surface of the body 300 for the convenience of replacing the fog liquid container 304.

The heater 305 may be installed at an inner lower side of the body 300 to be positioned at a distance adjacent to the fog liquid container 304. The heater 305 may vaporize the fog liquid by applying heat to the fog liquid supplied to the injection nozzle 311.

The lower end of the connection line 306 may be in communication with the lower end of the fog liquid container 304. The upper end of the connection line 306 may be provided inside the body 300 in a state in communication with the lower end of the operation handle 309.

The spiral tube 307 may be provided at the lower end of the connection line 306 in communication with the connection line 306. The spiral tube 307 may be located inside the heater 305 to receive heat from the heater 305. The spiral tube 307 may be vaporized by heating the fog liquid passing through the spiral tube 307 by the heat transmitted from the heater 305.

Here, the fog liquid rising through the spiral tube 307 may stay in the spiral tube 307 for a longer time, and thus the vaporization efficiency of the fog liquid may be further maximized.

The heat insulating material 308 may be provided between the outer circumferential surface of the heater 305 and the inner circumferential surface of the body 300. The thermal insulation material 308 may more easily block the high heat generated from the heater 305 to be transmitted to the body 300.

Due to this, the thermal insulation material 308 is no fear that high heat is generated in the body 300 can be prevented in advance the risk of safety accidents such as burns to children or adults using the fire extinguisher 30 in advance. .

The insulation 308 may be made of sponge, styrofoam or various materials.

The open / close valve 303 may be provided at an upper end of the connection line 306 to open and close the connection line 306 by the controller 50.

6 to 8, a laser irradiation part 25 may be provided at the front end of the injection nozzle of the fire extinguisher 30.

The laser irradiation unit 25 may include an exterior 251, an inner tube 252, a laser irradiation member 253, and a fixing stand 254.

The exterior 251, the inner tube 252, and the fixing stand 254 may be made of a synthetic resin material such as plastic, but are not necessarily limited thereto.

The exterior 251 may be integrally provided at the front end of the injection nozzle 311. The inner tube 252 may be inserted and fixed while being screwed into the inner side of the outer tube 251.

The front side of the inner tube 252 may be open, and the plate portion 252a for closing the inner tube 252 may be vertically formed integrally with the rear side of the inner tube 252. One side of the plate portion 252a may be formed with a through hole 252b through which air or fog liquid may pass.

The laser irradiation member 253, which may be made of a laser pointer, may be provided at an inner center of the inner tube 252.

The fixing table 254 may be integrally formed at regular intervals between the outer circumferential surface of the laser irradiation member 253 and the inner circumferential surface of the inner tube 252 to fix the position of the laser irradiation member 253 at the inner center of the inner tube 252.

9 is a flowchart illustrating an example of a simulation method using a tangible fire drill simulation system according to an embodiment of the present invention.

Hereinafter, FIG. 9 will be described with reference to components and reference numerals of FIGS. 1 to 2.

9, the flow chart of the haptic fire training simulation system according to an embodiment of the present invention is the fire image output step (S100), the laser shooting step (S120) displayed on the fire image, the laser position comparison step (S130) ), A fire extinguisher operation stop signal output step (S140) and speaker notification step (S150).

Specifically, the fire image output step (S100) outputs a fire image stored in the storage unit 40 of the control device 100 to the screen 110 through the image output unit 10.

Here, the child or adult experienced person to remove the safety pin from the operation handle 309 of the fire extinguisher 30, and then press the operation switch with the operation handle 309 so that air and fog liquid can be injected through the injection nozzle 311 do.

In this state, the child or adult experienced person can adjust the direction toward which the front end of the injection nozzle 311 is directed so that the laser of the laser irradiation unit 25 is directed to the fire image.

Next, in the laser photographing step (S120) displayed on the fire image, the photographing unit 20 provided in the control device 100 is operated to capture a fire image.

Here, when shooting a fire image can be taken continuously or by one screen at a set time.

Next, the controller 50 compares the fire image output to the screen with the photographed fire image (S130).

Here, the comparison between the fire image and the fire image on which the laser is displayed is compared to the original fire image stored in the storage by displaying the fire image in which the laser image is recorded at a frame per second and loading the software stored in the storage unit. .

Here, when the time set for each of the flame image within the limited time is exhausted by the laser of the laser irradiation unit 25 sends a fire extinguisher operation stop (S140) signal, otherwise the fire image and the laser image displayed on the laser again ( S120).

Next, when comparing the fire image and the fire image displayed on the laser (S130) and the laser is matched with the set flame range, the controller 50 sends a stop signal for the fire extinguisher 30.

Here, the speaker provided on one side of the fire extinguisher 30 informs the experienced person that the fire extinguisher (S150).

10 is a flowchart illustrating another example of a simulation method using a tangible fire drill simulation system according to an exemplary embodiment of the present invention, and FIG. 11 is a diagram illustrating a range partitioned in a flame image displayed on a fire image.

10 will be described with reference to the components and reference numerals of FIGS. 1 to 2.

10 and 11, the fire image output step (S500), the fire image and laser image display step (S510), the fire image and laser image display step (S520), the counting time counting step ( S530) and flame 36 may include a step S540.

Specifically, the fire image output step (S500) outputs a fire image in the storage unit 40 of the control device 100 to the screen 110 through the image output unit 10 (S500).

Next, the photographing unit captures a fire image and a fire image on which the laser is displayed (S510).

The control unit 50 compares the fire image and the fire image displayed on the laser is stored in the storage unit 40, the fire image is displayed on the original fire image stored in the storage unit 40 is displayed in each frame per second laser The control unit 50 loads and compares the software capable of contrasting and comparing the image frames (S520). If the laser is inconsistent within the range of the displayed flame 36, the fire image and the laser image are displayed in the fire image photographing step S510.

Here, different times may be set in the partitioned one region 31, the two region 32, and the three region 33 of the flame 36. For example, a time set in the first region 31 may be set to be less than a time set in the three region 33. Therefore, the laser should be irradiated to one area 31 for quick fire extinguishing.

Next, when the laser is matched within the range of the displayed flame 36, the controller 50 counts the set time (S530). Here, if the laser is out of the range of the flame 36 before the set time is counted, the fire image and the laser are displayed again to the fire image photographing step (S510).

In addition, if the counted time is not reset again and the laser is instructed in the same flame 36 range, the remaining time is counted.

Next, when there is no counting set time, the image of flame 36 is reduced (S540).

The present invention described above is not limited to the above-described embodiments, and various substitutions, modifications, and changes can be made without departing from the technical spirit of the present invention. It will be obvious to him.

Claims (8)

1. In the fire-extinguishing simulation system using a fire extinguisher on the flame image output on the screen,

   An image output unit configured to output a fire image including the flame image;

   A fire extinguisher equipped with a laser irradiation unit for irradiating a laser onto the fire image;

   A photographing unit which photographs the image irradiated with the laser;

   A hot air fan for injecting heat corresponding to the size of the flame image;

   And a control unit for comparing the flame image and the fire image on which the laser irradiator irradiates the fire image to display a fire image and outputting an operation signal of the fire extinguisher and controlling the heat of the hot air blower.
2. The method of claim 1,

   The flame image,

   And a fire extinguishing time corresponding to the laser irradiation time is set in the fire regions for each of the plurality of regions, wherein the fire regions are divided into a plurality of regions.
3. The method of claim 2,

   The flame image includes a plurality of flame images corresponding to the plurality of flame regions,

   The control unit,

   When the laser is located in any one of a plurality of areas in the flame image, the haptic fire training simulation system, characterized in that for controlling to output the next flame image after the set fire time corresponding to the area.
4. The method according to any one of claims 1 to 3,

   Haptic fire training simulation system further comprising a storage unit for storing the fire image.
5. The method of claim 1,

   The haptic type fire training simulation system further comprises a lighting unit whose brightness is adjusted according to the size of the flame image.
6. The method of claim 1,

   The fire extinguisher,

   A body into which the fog fluid can be filled;

   An operation handle formed on the body;

   An injection nozzle coupled to the body and having the laser irradiation part formed thereon;

   A supply line for supplying air supplied from an air compressor that generates air into the body;

   Haptic fire training simulation system including an on-off valve for opening and closing the supply line.
7. The method of claim 1,

   The fire extinguisher,

   A body into which the fog fluid can be filled;

   A fog liquid container installed in the body and filled with the fog liquid;

   A heater filled in the fog liquid container and vaporizing by applying heat to the fog liquid supplied to the spray nozzle;

   A connection line connecting the fog liquid container and the spray nozzle;

   A spiral tube provided in the connection line and positioned inside the heater to receive heat from the heater;

   Insulating material provided between the outer peripheral surface of the heater and the inner peripheral surface of the body and

   Haptic fire training simulation system including an on-off valve for opening and closing the connection line.
8. The method of claim 1,

   The fire extinguisher,

   The laser irradiation part is provided at the front end of the injection nozzle of the fire extinguisher,

   The laser irradiation unit,

   An appearance provided at a front end of the injection nozzle;

   An inner tube inserted into and fixed to the inner side of the exterior and having a through hole formed at a rear side opposite to the front side;

   And a fixture formed between the laser irradiation member provided inside the inner tube and the outer circumferential surface of the laser irradiation member and the inner circumferential surface of the inner tube to fix the position of the laser irradiation member to the inner side of the inner tube.

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