JP3972168B2 - Fire extinguishing equipment - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to fire extinguishing equipment.
[0002]
[Prior art]
Conventional fire extinguishing equipment is provided with a fire extinguishing nozzle (automatic directional fire extinguishing nozzle) provided with a fire detecting means. In this fire-extinguishing nozzle, the fire detection means always turns to monitor the fire monitoring area, and when a fire is detected, a fire signal is sent to the control panel. The control panel that has received the fire signal directs the fire-extinguishing nozzle toward the fire source and starts water discharge.
[0003]
[Problems to be solved by the invention]
The conventional example has the following problems.
(1) Since the fire detection means and the fire-extinguishing nozzle are exposed, they may be damaged due to accidental external force or mischief. In order to avoid this, even if a protective cover is to be used, the fire detection means for monitoring the turning at all times is in a situation where exposure cannot be avoided because the field of view is blocked and monitoring is impossible.
Here, when the fire detection means is a sensor of a type that detects infrared rays, it is conceivable to use sapphire glass that transmits infrared rays as a protective cover.
[0004]
However, glass cannot be sufficiently protected because it is weak against external forces.
If this sapphire glass is made thick enough to give it enough strength, this time, the transmitted light is attenuated due to the thickness and scratches due to aging on the surface of the sapphire glass and external forces, and fire The sensitivity of the sensing means is reduced.
[0005]
The decrease in sensitivity of fire detection means shortens the warning distance, so it is necessary to clean the surface frequently. However, since the scratches cannot be repaired, replacement of a thick and large area very expensive sapphire glass is necessary. Will also be needed.
In this way, the cover made of sapphire glass is unintentional because it lowers the sensitivity of the fire detection means, increases the time required for cleaning, and increases parts replacement.
[0006]
After all, if the function of the auto-directed fire extinguishing nozzle is performed without causing a decrease in sensitivity, the exposure of the fire detection means cannot be avoided.
In addition, the exposure of the movable part cannot eliminate external force or mischief, and always has a possibility of failure.
[0007]
Therefore, in order to reduce the external force as much as possible, for example, an automatic fire-extinguishing nozzle can be embedded in the wall and retracted.
However, the automatic directional fire-extinguishing nozzle has a situation where it is more likely to receive external force because it must protrude sufficiently from the wall where it is installed, for example, when the warning viewing angle is 180 °. The possibility of mechanical failure increases.
[0008]
By the way, this failure is largely obvious, for example, if the lens of the fire detection means is damaged, it can be noticed and repaired at the time of maintenance, but the failure is small and unknown, such as a fire extinguishing nozzle or fire detection means. If an external force is applied to the lens and the orientation or axis is bent slightly, it will be overlooked.
For this reason, fire detection cannot be performed accurately or water cannot be discharged in the set direction, and fire extinguishing efficiency may be reduced.
[0009]
In this way, a failure due to the exposure of an automatically directed fire extinguishing nozzle is easily predicted, and even though the avoidance of the failure is very important especially in disaster prevention facilities, protective measures have been found so far. It wasn't.
[0010]
(2) Since the fire detection means constantly turns and monitors the fire, the moving parts are likely to wear out and frequent parts replacement is required. Therefore, maintenance is troublesome.
(3) Since the fire detection principle of the fire detection means was a single method such as exploring the amount of infrared radiation, a non-fire heat source was mistakenly determined to be a fire, accidentally discharged, and water loss could occur. .
[0011]
In view of the above circumstances, an object of the present invention is to prevent failure of the fire detection means and the fire extinguishing nozzle while maintaining the sensitivity of the fire detection means.
Another purpose is to enable effective fire extinguishing and to make an accurate fire judgment and prevent water loss.
[0012]
[Means for Solving the Problems]
Means for solving the problems are as follows.
[0013]
The present invention includes an automatic fire alarm facility for receiving a fire signal from a first fire detector means for constantly monitoring a fire; a second fire detector means activated by receiving a fire signal from the automatic fire alarm facility; A fire-extinguishing nozzle that discharges water toward a fire source detected by the fire-sensing means; storing the second fire-sensing means and the fire-extinguishing nozzle; and receiving the fire-sensing means and the fire-extinguishing nozzle by receiving from the automatic fire alarm facility A fire extinguishing facility comprising: a containment box having an open front; wherein the second fire sensing means captures a heat ray and identifies a fire source direction; and a flame-specific CO2 resonance radiation And a movable flame sensor that detects fluctuations in the intensity of the infrared linear sensor. The infrared linear sensor swivels according to an instruction from the control unit to search for a heat source in the entire monitoring area, and the control unit The position of the heat source is detected based on the data of the sensor, and the flame detector is turned by an instruction from the control unit and stopped at the position where the infrared linear sensor detects the fire source, and the direction of the fire source is determined. The storage box is provided with a door that closes at a normal time and opens the front of the second fire detecting means and the fire-extinguishing nozzle when receiving a start signal. A door of the storage box integrally stores and fixes the second fire detection means and the fire-extinguishing nozzle, and swings around a rotation support shaft.
[0014]
The door of the present invention is a revolving door formed in a mountain shape.
[0015]
DETAILED DESCRIPTION OF THE INVENTION
According to the present invention, the second fire detection means and the fire extinguishing nozzle are stored in a storage box and are always in a standby state. When the first fire detecting means detects a fire, the storage box is opened and the second fire detecting means is activated to detect the fire source, and the fire extinguishing nozzle is directed to the detected fire source to discharge water.
Therefore, the storage box is opened only when the first fire detection means detects a fire, and the second fire detection means and the fire extinguishing nozzle are also activated, so that the second fire detection means and the fire extinguishing nozzle are protected by the storage box during standby. Also, the consumption of the operating part is eliminated.
[0016]
Further, as the second fire detection means, a fire direction search means for detecting the direction of the fire source, and a fire for determining the detected fire source based on a principle different from that of the fire direction search means for detecting the fire source. Since the confirmation means is provided, the fire source is specified more accurately.
[0017]
【Example】
A first embodiment of the present invention will be described with reference to FIGS.
The storage box 1 is formed in a frontal shape, and its surface 1 a is covered with a mountain-shaped door 2.
[0018]
The door 2 includes a fixed door 2A and a revolving door 2B. On the fixed door 2A side, the power supply unit 4 of the turning motor 3 having the small gear 3A, the gear 5A of the rotation support shaft 5 that meshes with the small gear 3A, and the encoder 6 that measures the rotation angle of the rotation support shaft 5 And a control unit 7 for controlling the turning motor 3 and the like, and storing and calculating data. That is, the turning mechanism T of the rotary door 2B is accommodated on the fixed door 2A side.
[0019]
As shown in the fire extinguishing facility of FIG. 10, the control unit 7 is connected to the automatic fire notification facility M via the central operation panel N. This automatic fire alarm facility M is provided with a first fire detection means R and a fire receiver P. The first fire detection means R is composed of, for example, a smoke sensor R1 and a heat sensor R2.
[0020]
A fire extinguishing nozzle having second fire detection means is housed and fixed on the side of the revolving door 2B. As the second fire detection means, fire detectors 9A and 9B are used, and a movable water discharge head 8 is used as a fire extinguishing nozzle. The second fire detection means, the fire extinguishing nozzle, and the turning mechanism T constitute a so-called automatic directional fire extinguishing nozzle SR.
[0021]
Note that the pivot axis of the rotary door 2B, that is, the axis of the rotary support shaft 5, is at least forward of the radius of the nozzle opening with respect to the left and right side edges 1d of the opening 1c of the storage box 1 where the door 2B is closed. Protruding. This is to ensure that the warning range viewing angle θ = 180 degrees can be obtained for any of the viewing angles or water discharge angles of the fire detectors 9A and 9B and the water discharge head 8.
[0022]
The water discharge head 8 is connected to a water supply flange 8F via a rotary pipe joint (not shown), and the door 2B is fixed to the water discharge head 8 so that the right inner wall of the rotary door 2B is along the head 8. . The rotary support shaft 5 is erected on the secondary elbow L of the rotary pipe joint so as to be coaxial with the vertical rotary axis of the rotary pipe joint.
As shown in FIG. 5, the axis 8d of the head 8 is housed at an angle α ₁ , for example, 20 degrees with respect to the back surface 1b of the storage box 1.
[0023]
As shown in FIG. 4, the water discharge head 8 is composed of a throwing head 8A, a middle throwing head 8B, and a near throwing head 8C in which the respective axes are directed in the same direction. The long throw head 8A is provided in the upper stage, and its water discharge width is narrower than the water discharge width of the middle stage middle throw head 8B but has a long flight distance.
[0024]
The near throwing head 8C is provided at the lowermost stage, and the water discharge width from the middle head 8B. However, since the flight distance is short, only the vicinity of the water discharge head 8 can be sprinkled.
When fire-extinguishing water is discharged from the water discharge heads 8, the fire-extinguishing waters ejected from the water discharge heads 8 are scattered while attracting each other.
Therefore, a tapered water discharge pattern, that is, a water discharge pattern close to a trapezoidal shape having a wide water discharge width on the rear end side that is the water discharge head 8 side and a narrow water discharge width on the front end side is formed.
[0025]
Two types of fire detectors 9A and 9B are arranged on the side of the water discharge head 8 in order to make an accurate fire determination. The sensors 9A and 9B are fixed to the water discharge head 8. The axis 9c, 9d of the fire detectors 9A, 9B is directed in a different direction from the axis 8d of the water discharge head 8, and the rotation locus of the mountain-shaped rotary door 2B formed when the water discharge head 8 turns. It is located inside the circle 2C. This position is located in a range where the fire-extinguishing water does not scatter, that is, outside the water scatter area.
[0026]
The fire detector 9A is a flame detector housed in a case having a rectangular cross section, and makes a flame determination by detecting CO ₂ resonance radiation peculiar to the flame and fluctuation of its intensity.
The axis 9c of the flame detector 9A is inclined with respect to the axis 8d of the water discharge head 8 by an inclination angle α ₂ . As the inclination angle α ₂ , for example, 30 degrees is adopted.
[0027]
The fire detector 9B is an infrared linear sensor that is housed in a case having a square cross section and is larger than the flame detector 9A, and is used to specify the fire source direction.
The sensor 9B is disposed along the left inner wall of the rotary door 2B, and is fixed to the door 2B or the water discharge head 8.
The axis 9d is inclined at an inclination angle α ₃ with respect to the axis 9c of the flame detector 9A. For example, 90 degrees is adopted as the inclination angle α ₃ .
[0028]
The crossing angle between the axis 8d of the water discharge head 8 and the axis 9d of the infrared linear sensor 9B is α ₂ + α ₃ , that is, 120 degrees, and the flame detector 9A is connected to the water discharge head 8 and the infrared linear sensor 9B. And is fixed to the rotary door 2B or the water discharge head 8 in a state of being sandwiched between the two. Therefore, the axis 9d of the infrared linear sensor 9B is stored with an angle α ₄ , that is, inclined by 40 degrees with respect to the back surface 1b of the storage box 1.
The viewing angle β of the infrared sensor 9B is substantially equal to that of the flame detector 9A.
[0029]
Next, the operation of this embodiment will be described.
When the automatic fire alarm facility M is activated (S1), the smoke detector R1 and the heat detector R2 start fire monitoring (S2). Smoke detectors R1 detects a fire and outputs a fire signal to the fire receiver P (S3, Yes), the fire alarm system M is selected a representative automatic Shiko extinguishing nozzles SR corresponding to該煙detector R ₁ Then, a fire signal is sent to the control unit 7 of the nozzle SR (S4).
[0030]
The control unit 7 instructs the fire detectors 9A and 9B on standby to start the detection of the fire source (S5, Yes) and activates the turning motor 3, and as shown in FIG. 5, the infrared linear sensor 9B is moved to the arrow A8. Rotate in the direction by an angle α ₄ , ie 40 degrees. Then, the axis 9d of the infrared linear sensor 9B is positioned on a straight line O (origin) parallel to the back surface 1b.
[0031]
Next, fire source search by the fire detectors 9A and 9B is started based on an instruction from the control unit 7. First, as shown in FIG. 6, the water discharge head 8 is swung around the rotation support shaft 5 in the direction of arrow A8, for example, 180 degrees, and the infrared linear sensor 9B searches for the heat source in the entire monitoring area in charge ( S6).
When the control unit 7 detects the position of the heat source G based on the data of the infrared sensor 9B (S7, YES), a fire signal is output to the control unit 7 and the turning is stopped. This stop position is measured by the encoder 6 and sent to the control unit 7.
[0032]
The water discharge head 8 is turned by an instruction from the control unit 7, and when the flame detector 9A reaches the detection position and stops, the flame detector 9A is directed in the direction of the detected heat source G. Then, on the spot, the flame detector 9A swings and swings to search for a fire source (S8).
As shown in FIG. 7, when the flame detector 9A captures the fire source G (S9), it stops, outputs a fire signal to the control unit 7, and determines the fire source (S10).
Here, the fire detector 9A captures the heat rays, and the fire detector 9B captures the characteristics of the flame, so that the fires are confirmed based on different principles. Therefore, the fire detector 9A is accurate and avoids false alarms.
In the present embodiment, the smoke detector R1 (heat detector R2), which is the first fire detection means, detects a fire, so that the fire is confirmed by three different fire detection principles. So it is extremely reliable.
The stop position determined by the flame detector 9 </ b> A is detected by the encoder 6 and sent to the control unit 7.
[0033]
In response to an instruction from the control unit 7, the water discharge head 8 turns around the rotation support shaft 5 and stops at the stop position of the flame detector 9A, and as shown in FIG. Water discharge is started toward G (S11).
[0034]
When the fire source G disappears and a restoration signal (S12) is issued from the central operation panel N by hand, the water discharge from the water discharge head 8 is stopped (S13).
[0035]
After the end of the water discharge, the water discharge head 8 turns according to the instruction of the control unit 7 and returns to the position before the start as shown in FIG. 5, and is accommodated in the storage box 1 and the rotary door 2B is closed (S14). Since the water discharge head 8 and the fire detectors 9A and 9B are directed in different directions and are located within the rotation locus circle 2c of the rotary door 2B, they are small. Therefore, since the storage space can be reduced, the overall size is reduced.
[0036]
Further, since the revolving door 2B of the storage box 1 integrally accommodates and fixes the fire detectors 9A and 9B and the water discharge head 8, the revolving drive of the revolving door 2B, the fire detectors 9A and 9B and the water discharge head 8 is performed. The mechanism is shared. Therefore, there are few parts and it is hard to break down.
[0037]
In addition, the fire detectors 9A and 9B and the water discharge head 8, that is, the rotary door 2B formed in a mountain shape so as to wrap around the side surface of the device that is swiveled integrally with the door 2B, are housed and fixed. Even while 9A and 9B are turning, they are free from damage due to flying objects from the side. Further, in this state, since the auto-directed fire extinguishing nozzle SR is hidden, it becomes a preferable state in terms of aesthetics.
[0038]
A second embodiment of the present invention will be described with reference to FIG. 11. The difference between this embodiment and the first embodiment is that the fire detectors 9A and 9B and the water discharge head 8 are provided on the revolving door 2B of the first embodiment. That is, a fan-shaped rotating storage box 12 is configured in the storage box 11 by attaching a fan-shaped top plate 121 and a partial cylindrical side plate 122 surrounding these devices 9A, 9B, and 8.
[0039]
The side plate 122 is formed with openings 123A, 123B, 123C that do not obstruct water discharge near the head openings of the water discharge heads 8A, 8B, 8C, and openings 124A, 124B that respectively secure the field of view of the fire detector 9A9B. Has been.
[0040]
The rotary storage box 12 has no bottom and is open. Further, the part corresponding to the revolving door 2B is a front plate 12f. When the fire detectors 9A, 9B and the like are facing the back, the appearance is the same as in FIG.
Further, the openings 123A and 123B may be, for example, star-shaped, and the other openings 123C, 124A, and 124B may be trapezoidal, and the openings may be designed for aesthetic purposes.
[0041]
In this embodiment, the opening portion faces the back during normal times, and safety during standby is ensured. Although the opening faces to the front at the time of start-up, the sensor and nozzle are still housed in the rotating storage box 12, so that they are protected from surrounding hazards.
Further, since the rotary storage box 12 is made of a conductive material such as stainless steel, the detectors 9A and 9B can be protected from electromagnetic noise from a mobile phone or the like.
Furthermore, if all of the openings 124A and 124B on the front surface of the sensors 9A and 9B are covered with a conductive sheet that conducts to the storage box 12, it is completely protected from electromagnetic noise.
[0042]
Not only during standby, but also during startup, that is, while the fire detector is turning or discharging, the detector and nozzle are free from damage or performance deterioration caused by any flying objects or external force, so they exhibit their original performance. it can. As a result, a highly reliable automatic directional fire extinguishing nozzle can be obtained.
[0043]
In this embodiment, the storage box 12 covers most of the equipment other than the minimum necessary opening for ensuring performance. Therefore, the aesthetic appearance is not impaired, and the device is not exposed to the human eye, so that the person in the fire extinguishing area is not worried.
[0044]
A third embodiment of the present invention will be described with reference to FIG. 12. The difference between this embodiment and the second embodiment is that the fan-shaped rotary storage box 12 is a cylindrical rotary storage box 13.
The storage box 13 is a bottomed cylindrical body having a top plate 131 and a bottom plate 133, and is pivotally supported so as to be held in the center of the front of the trunk of the storage box 11.
In the side plate 132, openings 134A, 134B, and 134C that do not hinder water discharge are formed in the immediate vicinity of the head openings of the water discharge heads 8A, 8B, and 8C, but so as to surround these openings 134A, 134B, and 134C. A side recess 134 is formed.
[0045]
The side plate 132 is formed with openings 135A and 135B that secure the visual fields of the fire detectors 9A and 9B. These openings 135A and 135B are formed from the side plate 132 to the bottom plate 133. .
Also in this embodiment, the same effect as in the second embodiment can be obtained.
[0046]
A fourth embodiment of the present invention will be described with reference to FIG.
In this embodiment, it is formed in a substantially hexagonal columnar cylinder, ie, a bottomed cylindrical storage box, and its support is from the upper water supply pipe 81 to the water supply flange 8F, main pipe 8P, rotary pipe joint 82, branch pipe 8T, fixing This is done via the flange 8E.
A water supply flange 8F is connected to the upper end of the main pipe 8P, and a rotary pipe joint 82 is connected to the lower end of the main pipe 8P. , Has been fixed.
[0047]
A rotary pipe joint 82 is connected to the upper end of the branch pipe 8T, and a fixing flange 8E is connected to the lower end. The fixing flange 8E is fixed to the bottom plate 143 of the storage box 14. A gear 5 </ b> A that engages with the small gear 3 </ b> A of the turning motor 3 is fixed immediately below the rotary pipe joint 82 above the branch pipe 8 </ b> T. Further, the gear 5A is fixed to the side of the control unit 7 and is also engaged with an encoder gear 6A that is fixed to the encoder 6 that measures the rotation angle of the branch pipe 8T. Since the gears 6A and 5A have the same number of teeth, both rotation angles move equally.
[0048]
Further, the central portion of the branch pipe 8T is branched and connected to a water discharge head 8 comprising long throw, middle throw, and close throw 8A, 8B, 8C. Furthermore, fire detectors 9A and 9B are supported and fixed at the center of the branch pipe 8T by a support body (not shown).
[0049]
In the center of the top plate 141 of the storage box 14, a sleeved hole 141 </ b> A through which the main pipe 8 </ b> P, the power supply line 83 and the signal line 84 are inserted is formed with a sufficient size. The power supply line 83 and the shielded signal line 84 are inserted through a conduit 82 fixed to the lower end of a horizontal water supply pipe 81 and connected to the power supply unit 4 and the control unit 7 through the hole 141A. .
[0050]
The electric wires 83 and 84 have a sufficient length so that they can sufficiently cope with the 180 ° rotation of the storage box 14 or 360 ° or more, and are provided with a coating of heat resistance, corrosion resistance and damage resistance. ing.
[0051]
The side plate 142 of the stainless steel storage box 14 has a vertically long opening 144 that does not obstruct water discharge in the vicinity of each head opening of the water discharge heads 8A, 8B, and 8C, and an opening that secures the field of view of the fire detectors 9A and 9B. Portions 145A and 145B are formed across the bottom plate 143.
These openings 144, 145A, 145B may be provided with a shielding stainless net so as to cover all of them.
In addition, choose a net that does not interfere with water discharge.
The nets of the openings 144, 145A and 145B are selected so as not to reduce the sensitivity of the sensors 9A and 9B so much.
These openings 144, 145 </ b> A, 145 </ b> B are formed to be biased to substantially the same side in the storage box 14.
[0052]
In the above embodiment, the flame detector 9A is directed to search for the swinging fire source at the position where the infrared sensor 9B has detected the heat source G in the operation, but the flame detector 9A has a wide-angle visual field (for example, 90 °). The fire source may be determined without swinging. In this case, the fire source position is the position detected by the infrared sensor 9B.
[0053]
The fire extinguishing equipment of this embodiment is provided close to the wall surface of the altitude. During normal times, for example, the fire detector 9A is waiting toward the back surface, that is, the wall surface, and when receiving the start signal, it faces the front side. For example, it turns 180 degrees to perform fire source exploration, fire source determination, and water discharge operation.
[0054]
【The invention's effect】
The present invention has the following remarkable effects.
(1) Since the first fire detection means for constantly monitoring the fire and the second fire detection means that is activated when the first fire detection means detects a fire, the operation time of the second fire detection means is shortened. can do. For this reason, the movable part of the second fire detection means is not easily consumed, and maintenance is facilitated.
[0055]
(2) Since the second fire detection means and the fire extinguishing nozzle are accommodated in the storage box according to the present invention, no accidental external force is applied or tampered with during standby. Therefore, a normal state can always be maintained.
[0056]
(3) In the present invention, since the second fire detection means is composed of an infrared sensor and a flame detector, it is possible to accurately identify the fire source, so it is possible to avoid water discharge and water loss due to false alarms. .
[0057]
(4) The containment box has an opening that secures at least the field of view of the fire detector and the water discharge of the fire extinguishing nozzle, which is a fire extinguishing means, and integrally stores and fixes the fire detector and the fire extinguishing nozzle. As such, the fire detector and fire extinguishing means are not exposed to the human eye. As a result, the aesthetics are preserved and there is no risk of anxiety for people in the fire extinguishing area.
[Brief description of the drawings]
FIG. 1 is a plan view of a fire extinguishing apparatus according to a first embodiment of the present invention when the door is opened.
FIG. 2 is a front view when the door is opened.
FIG. 3 is a front view when the door is closed.
FIG. 4 is a side view of the water discharge head.
FIG. 5 is a plan view showing a situation when the storage box is closed.
FIG. 6 is a plan view showing an operating state of the infrared sensor.
FIG. 7 is a plan view showing an operating state of the flame detector.
FIG. 8 is a plan view showing a water discharge state of the water discharge head.
FIG. 9 is a flowchart of fire extinguishing equipment.
FIG. 10 is a block diagram of fire extinguishing equipment.
FIG. 11 is a perspective view of a fire extinguisher according to a second embodiment of the present invention.
FIG. 12 is a perspective view of a fire extinguishing apparatus according to a third embodiment of the present invention.
FIG. 13 is a perspective view of a fire extinguishing apparatus according to a fourth embodiment of the present invention.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 1 Storage box 2 Door 7 Control part 8 Movable water discharge head 9A Flame detector 9B Infrared sensor

Claims (2)

An automatic fire alarm facility for receiving a fire signal from the first fire detector means for constantly monitoring the fire; a second fire detector means activated by receiving a fire signal from the automatic fire alarm facility; A fire-extinguishing nozzle that discharges water toward the detected fire source; housing the second fire-sensing means and the fire-extinguishing nozzle; and receiving from the automatic fire alarm facility, the front faces of the fire-sensing means and the fire-extinguishing nozzle are opened. A fire fighting facility comprising a storage box;
The second fire detection means includes a movable infrared linear sensor that detects a heat ray and identifies a fire source direction, and a movable flame detector that detects a CO2 resonance radiation peculiar to a flame and a fluctuation of its intensity,
The infrared linear sensor swivels according to an instruction from the control unit to search for a heat source in the entire monitoring area, and the control unit detects the position of the heat source based on the data of the infrared linear sensor, and also detects the flame. The instrument is turned by the instruction of the control unit and stopped at the position where the infrared linear sensor detects the fire source, and the fire source is searched in the direction of the fire source.
The containment box is provided with a door that closes when flat, and opens the front of the second fire detecting means and the fire-extinguishing nozzle when receiving a start signal ,
Firefighting equipment door of the storage boxes, which accommodates fixed integrally and said extinguishing nozzles and the second fire sensing means, characterized that you pivot about the rotation support shaft. The door of the storage boxes, fire extinguishing equipment according to claim 1, wherein the rotary door der Rukoto formed in chevron shape.

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