JP2881482B2 - Fire extinguisher operation training device - Google Patents

Description

Description: FIELD OF THE INVENTION The present invention relates to an operation training device for a manually operated fire extinguisher.

[Related Art] The mitigation of fire damage depends largely on the success or failure of an initial fire extinguishing activity, and a manually operated fire extinguisher is very useful for the initial fire extinguishing activity. However, at present, there are many erroneous operations due to inexperience in using a fire extinguisher. Therefore, fire extinguishing training using a fire extinguisher is desired. However, training using a real fire extinguisher has the following problems. In other words, the practice of refilling fire extinguishers with fire extinguisher at schools and business establishments limits the number of actual fire extinguishing agent emissions, and most of the training participants are just visitors. However, since training is usually conducted by igniting the kerosene in the oil pan, it does not correspond to various fire situations that can actually occur, and it takes time to relight the oil pan once filled with fire extinguisher However, disposal of oil and fire extinguisher after use is troublesome, and powder fire extinguisher scatters a large amount of chemicals around it, making it difficult to secure a training place. In the case of rainy weather, field training is not possible.

Various devices have been proposed in order to eliminate the problem of operation training using a real fire extinguisher as described above. For example, draw a picture of a flame on a translucent plate, place a light source behind the translucent plate, place an optical sensor on the front of the translucent plate, install a light emitter on the nozzle of the fire extinguisher mimic, There is a training device that emits a light beam toward a light-transmitting plate, and a sensor of the light-transmitting plate detects the light beam so as to diminish or extinguish the light source.

[Problems to be Solved by the Invention] In the apparatus as described above, since the flame on the translucent plate is a single still image, if the fire extinguishing operation fails, the flame increases, and the fire extinguishing operation is effectively performed. If it does, the flame cannot be reduced and disappear.
Further, in the above-described conventional apparatus, light sensors are arranged on a still image of the flame, for example, at an appropriate interval from the periphery of the flame toward the inside of the flame. The light from the light emitting device of the fire extinguisher nozzle is applied, and the light is sequentially applied to the light sensors arranged inward from the periphery of the flame, thereby sequentially dimming or extinguishing the illumination light sources arranged over the range of the flame. It has become. However, in order to actually extinguish a fire, it is necessary to radiate a fire extinguisher to the center of the flame, but in the above conventional device, light rays are applied from the periphery of the flame, so practice the operation of the fire extinguisher that is actually necessary Can not do it. Also, it is impossible for an operator to know exactly where the nozzle (light emitter) of the fire extinguisher is directed at the flame. Further, in the above-described conventional apparatus, since the distance relationship between the flame and the operator of the fire extinguisher is neglected, it is not possible to perform training for determining the most effective operation position of the fire extinguisher with respect to the size of the flame.

[Means and Actions for Solving the Problems] The present invention employs the following configurations in order to solve the above-described problems.

1. The image of the flame to be displayed is an image that changes stepwise or continuously.

2. Detects the direction of the light emitter simulating the nozzle of the fire extinguisher (the position where the light from the light emitter hits the image on the display surface: the fire extinguisher emission position or the light irradiation position). The displayed image of the flame changes (increases or decreases) according to the positional relationship and the time during which the light from the light emitter hits the display flame (fire extinguishing agent effective emission time or light effective irradiation time).
I tried to make it.

3. The light irradiation position is displayed in real time on the display image.

4. The size of the displayed image is changed according to the distance between the image display surface and the fire extinguisher operator.

That is, the apparatus of the present invention comprises: storage and reproduction display means for storing and reproducing a series of images respectively showing a process from generation to disappearance of a flame from a fire source and a process of spreading a fire to the vicinity; A simulated nozzle incorporating a light emitting means in the apparatus; and a manually operated fire extinguisher simulated body which is separate from and independent of the storage / reproduction display means; provided in association with a display surface of the storage / reproduction display means; Calculating an irradiation position of a light beam from the light beam emitting means detected by the light beam detector on a display surface of the storage and reproduction display means, and reproducing and displaying the irradiation position on the display surface; Control means for selectively reproducing the stored image of the storage reproduction display means and displaying it on the display surface in accordance with the relative positional relationship between the stored image and the flame position of the stored image. Each of the series of images is stored as at least two different images taken at different distances and short distances on the memory playback display means, and the simulated nozzle is further provided with an ultrasonic wave emitting means, and the ultrasonic wave from the ultrasonic wave emitting means is provided. Is disposed in the vicinity of the display surface of the storage / reproduction display unit, and the control unit detects the nozzle from the display surface by the ultrasonic wave from the ultrasonic emission unit detected by the ultrasonic detection unit. Is calculated, and the stored far / near images are selectively reproduced according to this distance and displayed on the display surface. This allows the trainee to see an image having a size corresponding to the distance between the position where the player is standing and the base of the fire.

The apparatus of the present invention further comprises an irradiation position on the display surface of the light beam (a position at which the fire extinguisher is emitted to the fire source) superimposed on the reproduced image displayed on the display surface of the display storage / reproduction means. ) Can be provided as a mark.

When the image indicating the occurrence of the flame is displayed, the trainee operates the simulated fire extinguisher and emits light rays and ultrasonic waves with the nozzle directed at the image. The emitted ultrasonic wave is detected by the ultrasonic detector,
The control means calculates a distance between the display surface and the nozzle, and displays an image having a size corresponding to the distance on the display surface. The control means also displays the irradiation position of the light beam on the display surface as a mark so as to be superimposed on the image, and reduces or eliminates the flame according to the positional relationship between the irradiation position of the light beam and the origin of the image (fire suppression).
An image to be displayed, an image in which the flame spreads, and an image indicating the flame in another change pattern are selectively displayed.

[Examples] Hereinafter, illustrated examples will be described in detail.

FIG. 1 is a schematic configuration diagram of the apparatus, and FIG. 2 is a configuration diagram of a control circuit.

In Figure, A represents housing, 1 television receiver, 2 is a laser disc player, the control unit 3, 4 _1, 4 _2, 4 _3, 4 ₄ infrared sensor 5 is an ultrasonic sensor, a control keyboard 6 , 7 is a connection panel, 8 is a connection cable, 9 is a speaker, 10 is a stereo integrated amplifier, 11 is a simulated fire extinguisher, and 12 is a simulated nozzle.

The simulated nozzle 12 incorporates an infrared emitter 121 and an ultrasonic emitter 122, and the controllers 111 and 1 for the infrared emitter 121 and the ultrasonic emitter 122 are included in the fire extinguisher simulated body 11.
12 and a battery 113 are housed. When the safety plug (not shown) of the fire extinguisher is removed and the lever 123 is gripped, the switch 124 is closed, and the infrared emitter 121 and the ultrasonic emitter 12 are closed.
2 works.

The infrared sensors 4 ₁ , 4 ₂ , 4 ₃ , 4 ₄ are arranged in a cross shape on four sides of the outer periphery of the front of the television receiver 1, and the ultrasonic sensor 5 is located at an appropriate place on the periphery of the surface of the television receiver 1, as shown in the drawing. in is disposed in the vicinity of the infrared sensor 4 _4.

The laser disc player 2 has a fire source, for example, an image of a pan filled with oil being heated on a gas stove in a kitchen, a fire starts from the oil in the pan, the oil burns up, and the flame increases. Various types of flames related to fire-extinguishing operations by fire extinguishers, such as a state in which the fire extinguishes due to the effective fire extinguishing operation by the operation of Change patterns, and these patterns according to the distance between the fire source and the operating position of the fire extinguisher, for example, a moving image obtained by previously shooting at a short-range fire extinguisher operating position and a long-range fire extinguisher operating position, and the like Information about flames, images of information necessary for fire extinguishing training, etc. are stored together with necessary sounds such as sound of burning oil, sound of released fire extinguishing agent acting on oil, sound of explanation of images, etc. .

In Figure 2, CPU infrared sensor ₄₁ to ₄ infrared detection signal from the A / D converter 41 _{1-41 4} via the orientation of the uptake simulated nozzle 12, i.e., the infrared emitters 121 of the simulated nozzle 12 Calculates the position where the infrared light from the camera is irradiated on the display surface of the TV receiver (the position where the fire extinguisher is applied)
According to the relative relationship between the infrared irradiation position and the position of the flame displayed on the display surface and the irradiation time, the moving image stored in the laser disk player 2 is selectively reproduced with a corresponding change pattern. The sound is displayed on the display surface of the television receiver, and the sound is output from the speaker 9 via the sound amplifier SA. At this time, the CPU takes in the ultrasonic waves emitted from the simulated nozzle 12 of the fire extinguisher simulated body 11 detected by the ultrasonic sensor 5 through the distance measurement counter DC, and the position of the simulated nozzle 12 (practice) and the fire source (image (A display surface), a flame image of a short-distance or a long-distance pattern stored in the laser disk player 2 is selected and displayed according to the distance, and the image associated with the image is displayed. The sound is generated by the speaker 9 via the sound amplifier SA. SG is a sound effect generator which generates, for example, a sound of a siren of a fire engine. The CPU also causes the graphic controller GC to display the infrared irradiation position on the display surface as an appropriate mark on the display surface by superimposing it on the moving image of the flame of the selectively reproduced pattern via the image synthesizer IS. Thus, the operator of the simulation nozzle 12 can know where the nozzle held in his / her hand is facing.

The CPU further causes the television receiver 1 to display information related to a fire other than the moving image of the flame stored in the laser disk player 2 in response to a command input from the keyboard 6 and to generate a corresponding sound.

3 (A) to 3 (E) and (X) to (Z) show typical frames of a moving image stored in the laser disk player 2, where (A) is a normal state before a fire occurs. And (B)
(E) shows the process from fire to extinguishment, (X) to (Z)
Shows the process in which the flame increases without extinguishment and spreads to the surroundings. The image actually displayed is a continuous moving image, and it is desirable that the image is continuously changed between frames. However, a still image of each frame may be switched and displayed. In addition,
Each image display time is, for example, (A) about 1 to 3 minutes,
(B) to (E) and (X) to (Z) can be about 3 to 5 seconds each.

When the device is started by pressing a start switch (not shown), the image (A) is displayed on the television receiver 1.
Eventually, when the image (B) at the beginning of the fire is displayed, the trainee lifts the fire extinguisher model 11, removes the safety plug, and starts the simulation nozzle 12.
Is pointed at the starting point of the image and the release lever 123 is gripped.

Thus the switch 124 is closed the controller 111 and 112 is infrared firing than the previous operation was simulated nozzle 12, the infrared sensor ₄₁ to ₄ irradiation position on the display surface of the television receiver detects the infrared Is calculated, and the irradiation position is superimposed and displayed on the screen as a mark. At the same time, the ultrasonic waves emitted from the simulated nozzle 12 are detected by the ultrasonic sensor 5 and the position of the trainee (simulated nozzle) is calculated, and the image of the currently displayed size is maintained or handled according to the position. The size of the image is switched. The infrared irradiation position (fire extinguisher emission position) matches or is near the fire-extinguishing effective position (position near the top of the pan, near the base of the flame rising from the pan) of the displayed image Is maintained, the image is (B) → (C) → (D) →
Change to (E) and extinguish the fire. However, if the infrared irradiation position is out of the fire extinguishing effective position range, the displayed image is (B) →
The flame expands as (X) → (Y) → (Z). Even if the flame expands to the image (X), the image returns from (X) to (B) and changes from (C) to (D) (E) to extinguish the fire if the tip of the simulation nozzle 12 is correctly directed to the fire source. But the flame is image (Y)
Or, if it is expanded to the state shown in (Z), the fire cannot be extinguished. Even if the flame shrinks from the image (B) to the image (C), if the hand gets out of order and the infrared irradiation position is out of the effective fire extinguishing position range, the image returns to (B) and further changes from (X) to (Y). I do. Various image change pattern programs can be set according to the positional relationship between the infrared irradiation position and the fire extinguishing effective position and the holding time at that position. After the operation practice, the time required for extinguishing the fire and the evaluation of the practice operation can be displayed as a score, for example.

Further, the stored image such as the information on the flame can be displayed as necessary before and after the extinguisher operation practice.

[Effects of the Invention] As described above, according to the present invention, it is possible to practice the operation of a fire extinguisher in a realistic manner according to the actual flame state and the fire extinguishing state. It is possible to know on the display screen, there is no consumption of the fire extinguisher, and the surroundings are not polluted, and a large number of trainees can effectively practice in a short time.

[Brief description of the drawings]

FIG. 1 is a perspective view showing a schematic configuration of an embodiment of the present invention, FIG. 2 is a block diagram showing the configuration, and FIGS. 3 (A) to (E) and (X), (Y), (Z). )
FIG. 4 is a diagram showing images of flames in various variations. 1 ...... television receiver, 2 ...... laser disc player, 3 ...... control unit, 4 _1, 4 _2, 4 _3, 4 ₄ ...... infrared sensor, 5 ...... ultrasonic sensor, 6 ...... control keyboard, 7 … Connection panel, 8… Connection cable, 9… Speaker, 10… Stereo integrated amplifier, 11… Simulated fire extinguisher, 12… Simulated nozzle.

Claims (6)

(57) [Claims] 1. A storage / reproduction display means for storing / reproducing and displaying a series of images respectively showing a process from generation to extinction of a flame from a fire source and a process of spreading a fire to a vicinity thereof; Means for simulating a manually operated fire extinguisher, comprising a simulated nozzle incorporating means, separated from and independent of the storage and reproduction display means; and provided in association with a display surface of the storage and reproduction display means, for emitting light from the light emitting means. Calculating an irradiation position of a light beam from the light beam emitting unit detected by the light beam detecting unit on a display surface of the storage / reproduction display unit; and detecting the irradiation position and the reproduction / reproduction displayed on the display surface. Control means for selectively reproducing the stored image of the storage and reproduction display means and displaying it on the display surface in accordance with the relative positional relationship between the stored image and the flame position. Indicating means for storing the series of images as images taken from at least two different distances, wherein the simulated nozzle includes ultrasonic emitting means, and ultrasonic detecting means for detecting ultrasonic waves from the ultrasonic emitting means. Is arranged in relation to the display surface of the storage / reproduction display means, and the control means calculates the distance of the simulated nozzle from the display surface by the ultrasonic waves from the ultrasonic detection means detected by the ultrasonic detection means. A fire extinguisher operation training device having a function of selectively reproducing the stored image in accordance with the distance and displaying the selected image on the display surface. 2. A fire extinguisher according to claim 1, further comprising means for superimposing the reproduced image displayed on the display surface and displaying a position of the light beam irradiated on the display surface as a mark. Operation practice device. 3. The fire extinguisher operation training apparatus according to claim 1, wherein the series of images are continuously changing images. 4. The fire extinguisher operation training apparatus according to claim 1, wherein the series of images are images that change stepwise. 5. A fire extinguisher operation training apparatus according to claim 1, wherein said storage / reproduction display means comprises a laser disk player and a television receiver. 6. The fire extinguisher operation training apparatus according to claim 1, wherein the light beam emitting means is an infrared ray emitting means.