JP6954544B1 - Fire extinguishing equipment and nozzles for extinguishing combustible materials - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a fire-fighting facility capable of reducing the initial cost and running cost of the facility by lowering the lift of a fire-extinguishing pump for supplying water to a combustible fire extinguishing nozzle and lowering the output. SOLUTION: A fire extinguishing agent supply unit 5 for supplying a fire extinguishing agent 8, a pipe 7 extending from the fire extinguishing agent supply unit 5, and being supplied from the fire extinguishing agent supply unit 5 provided in the pipe 7 and flowing through the pipe 7. The fire extinguishing equipment 1 has a combustible fire extinguishing nozzle 9 that discharges the fire extinguishing agent 8 from the spirally formed fire extinguishing agent discharging unit 13 toward the fire extinguishing object 3. [Selection diagram] Fig. 1

Description

The present invention relates to fire extinguishing equipment and a nozzle for extinguishing a combustible material, and more particularly to a fire extinguishing agent that discharges a fire extinguishing agent from a spiral fire extinguishing agent discharging portion to extinguish a fire.

Conventionally, fire extinguishing equipment for designated combustibles storage has been known. In this fire extinguishing system, water is discharged from the ceiling to designated combustibles stored below by a water spray nozzle (water discharge type head). In conventional fire extinguishing equipment, for example, as shown in Patent Document 1, a water spray nozzle that can extend the flight distance in the horizontal direction and expand the protection area while ensuring the size of the water droplets to be sprayed is adopted. Will be done.

Further, in the conventional fire extinguishing equipment, the discharge pressure of the water spray nozzle is set to 0.35 MPa to 0.55 MPa. Then, the discharge amount per water spray nozzle is set to 500 L / min, and water is discharged at 0.35 MPa to 0.55 MPa and 500 L / min in ^{a range of about 11 m in diameter (50 m 2 in the floor area of the inscribed square).} By doing so, ^{10 L / min of water is discharged per 1 m 2} to satisfy the conditions of the Fire Service Law.

Japanese Unexamined Patent Publication No. 2013-128629

By the way, as described above, in the conventional firefighting equipment, if the discharge amount of 500 L / min is secured by one water spray nozzle (nozzle for extinguishing combustibles), the discharge pressure of the water spray nozzle rises to, for example, 0.35 MPa. Resulting in.

Therefore, there is a demand to reduce the initial cost and running cost of the equipment by lowering the lift of the fire extinguishing pump that supplies water to the combustible fire extinguishing nozzle of the fire equipment and lowering the output.

The present invention is a fire-fighting facility capable of reducing the initial cost and running cost of the equipment by lowering the lift of the fire extinguishing pump that supplies water to the combustible fire extinguishing nozzle and lowering the output, and the combustible fire extinguishing equipment used in the fire extinguishing equipment. It is an object of the present invention to provide a nozzle for fire fighting.

According to the first invention, a fire extinguishing agent supply unit for supplying a fire extinguishing agent, a pipe extending from the fire extinguishing agent supply unit, and a pipe provided in the pipe and supplied from the fire extinguishing agent supply unit have flowed through the pipe. the fire extinguishing agent, and combustible materials fire-extinguishing nozzles that release toward the extinguishing object from fire extinguishing agent releasing portion formed in a spiral shape, possess the combustibles fire-extinguishing nozzles, end group connected to the pipe It is configured to include a side portion and a spiral tip side portion protruding from the proximal end side portion, and the proximal end side portion is provided with a first cavity portion connected to the pipe. A second cavity connected to the first cavity is provided in the tip side portion, and the fire extinguishing agent discharging portion is provided in the tip side portion and the pipe. And the fire extinguishing agent flowing through the first cavity portion and the second cavity portion is configured to be discharged from the fire extinguishing agent discharging portion, and the second cavity portion from the first cavity portion. The direction toward the top is from the top to the bottom, and the discharge direction of the fire extinguishing agent discharged from the fire extinguishing agent discharging portion is a direction intersecting the direction from the top to the bottom. A first fire extinguishing agent guide surface, a second fire extinguishing agent guide surface, and a third fire extinguishing agent guide surface are provided on the side portion, and the first fire extinguishing agent guide surface is the tip side portion. , The second fire extinguishing agent guide surface is located on the base end side portion side, and the second fire extinguishing agent guide surface is opposite to the proximal end side portion sandwiched between the first fire extinguishing agent guide surface, and the tip end thereof. The third fire extinguishing agent guide surface is arranged on the side portion, and the third fire extinguishing agent guide surface is arranged on the tip side portion on the side opposite to the first fire extinguishing agent guide surface sandwiched between the second fire extinguishing agent guide surface. The first fire extinguishing agent guide surface is configured so that the fire extinguishing agent discharged from the fire extinguishing agent discharging portion is discharged in an obliquely upward direction, and the third fire extinguishing agent guide surface is used. The fire extinguishing agent released from the extinguishing agent discharging portion is configured to be discharged diagonally downward, and the second extinguishing agent guide surface allows the extinguishing agent released from the extinguishing agent discharging portion. , The fire extinguisher equipment is configured to be discharged in a direction between the diagonally upward direction by the first fire extinguishing agent guide surface and the diagonally downward direction by the third fire extinguishing agent guide surface.

The second invention is the fire extinguishing equipment according to the first invention, in which the direction from the first cavity portion to the second cavity portion is a direction from top to bottom, and the fire extinguishing agent is released. The discharge direction of the fire extinguishing agent discharged from the portion is a direction intersecting the direction from the top to the bottom, and the fire extinguishing agent is obliquely upward from a part of the fire extinguishing agent discharging portion. It is a fire extinguishing system that is configured to release.

The third invention is the fire extinguishing equipment according to the first invention, in which the discharge pressure of the fire extinguishing agent from the combustible material fire extinguishing nozzle is set to about 0.1 MPa and directed downward from the combustible material fire extinguishing nozzle. When the fire extinguishing agent is released, one fire extinguishing agent for combustible material can be used to sprinkle 10 L / min of fire extinguishing agent per 1 m2 in a range of about 11 m in diameter centered on the combustible material fire extinguishing nozzle. It is a fire extinguishing facility.

A fourth invention includes a base end side portion provided with a fire extinguishing agent supply port to which a fire extinguishing agent is supplied, a first cavity portion extending in a predetermined direction from the fire extinguishing agent supply port, and the first. A second cavity connected to the cavity 1 and a spiral fire extinguishing agent discharging portion for discharging the fire extinguishing agent in the second cavity are formed and project from the base end side portion. In the second cavity, from the base end side, which is the first cavity side, to the tip side, which is the opposite side to the first cavity portion. The fire extinguishing agent is configured to flow toward the fire extinguishing agent, and a first fire extinguishing agent guide surface is formed on the tip side portion, and the first fire extinguishing agent guide surface releases the fire extinguishing agent from the extinguishing agent discharging portion. The fire extinguishing agent to be fired is discharged in the first oblique direction, and the first oblique direction is from the tip side in a direction in which the base end side and the tip end side are connected to each other. a direction toward the proximal side, up direction der tailored and away from the distal end portion of the said distal side to the proximal side in a direction orthogonal to the direction connecting to each other, the tip end A second fire extinguishing agent guide surface and a third fire extinguishing agent guide surface are formed in the portion, and the first fire extinguishing agent guide surface is a portion of the tip side portion on the proximal end side portion side. The second fire extinguishing agent guide surface is arranged on the tip side portion on the opposite side of the base end side portion with the first fire extinguishing agent guide surface in between. The third fire extinguishing agent guide surface is arranged on the tip side portion on the side opposite to the first fire extinguishing agent guide surface sandwiched between the second fire extinguishing agent guide surface, and the third fire extinguishing agent guide surface is arranged. The agent guide surface is configured so that the fire extinguishing agent discharged from the fire extinguishing agent discharging portion is discharged in the second oblique direction, and the second oblique direction is the base end side and the tip end side. The direction from the base end side to the tip end side in the direction in which the base end side and the tip end side are connected to each other, and the direction in which the base end side and the tip end side are separated from the tip end side portion in a direction orthogonal to the direction in which the base end side and the tip end side are connected to each other. The fire extinguishing agent discharged from the extinguishing agent discharging portion by the second extinguishing agent guide surface is the first oblique direction by the first extinguishing agent guide surface and the third A combustible fire extinguishing nozzle configured to be discharged in a direction between the fire extinguisher guide surface and a second oblique direction.

According to the present invention, the initial cost and running cost of equipment can be reduced by lowering the lift of the fire extinguishing pump that supplies water to the nozzle for extinguishing combustible materials and lowering the output. It has the effect of being able to provide a fire extinguishing nozzle.

It is a piping diagram of the fire extinguishing equipment which concerns on embodiment of this invention. It is a top view which shows the spraying state of water in the nozzle for extinguishing a combustible material of the fire extinguishing equipment which concerns on embodiment of this invention. (A) is a perspective view of a combustible material fire extinguishing nozzle of the fire extinguishing equipment according to the embodiment of the present invention, and (b) is another perspective view of a combustible material fire extinguishing nozzle of the fire extinguishing equipment according to the embodiment of the present invention. be. (A) is a front view of a combustible fire extinguishing nozzle of the fire extinguishing equipment according to the embodiment of the present invention, (b) is an IVB arrow view in (a), and (c) is an IVC arrow in (a). It is a visual view, (d) is an IVD arrow view in (a), and (e) is an IV arrow view in (a). FIG. 4A is a diagram showing a VA-VA cross section in FIG. 4, and FIG. 4B is a diagram showing a VB-VB cross section in FIG. It is a figure which shows the amount of water ejected (emission amount), etc. by the nozzle for extinguishing a combustible material of the fire extinguishing equipment which concerns on embodiment of this invention. It is a figure which shows the spray pattern of the nozzle for extinguishing a combustible material of the fire extinguishing equipment which concerns on embodiment of this invention. It is a figure which shows the operation of the fire extinguishing equipment which concerns on embodiment of this invention. It is a figure which shows the operation of the fire extinguishing equipment which concerns on embodiment of this invention. It is a piping diagram of the fire extinguishing equipment which concerns on the modification. It is a top view which shows the spraying state of water in the nozzle for extinguishing a combustible material of the fire extinguishing equipment which concerns on the modification. It is a figure which shows the operation of the fire extinguishing equipment which concerns on the modification.

The fire extinguishing equipment (fire extinguishing equipment of a designated combustible material storage; water spray fire extinguishing equipment) 1 according to the embodiment of the present invention releases a fire extinguishing agent 8 toward the fire extinguishing object 3 as shown in FIGS. 1 and 2. It extinguishes the fire extinguishing object 3 by radiating; spraying), and is provided with a fire extinguishing agent supply unit 5, a pipe 7, and a combustible material fire extinguishing nozzle (water spray head; for example, a designated combustible material fire extinguishing nozzle) 9. It is configured.

The fire extinguishing object 3 is stored in, for example, a designated combustible material storage facility (designated combustible material storage tank) 11. As the fire extinguishing object 3, designated combustibles such as coal and renewable resource fuel used in coal power plants and biomass power plants, and more specifically, powdery fuels such as coal powder and wood powder are listed.

The fire extinguishing agent supply unit 5 supplies the fire extinguishing agent 8 in the form of a liquid or a fluid. Water is listed as the fire extinguishing agent 8. The pipe 7 extends from the fire extinguishing agent supply unit 5 in order to allow the water 8 to flow.

As shown in FIGS. 3 to 5, the combustible material fire extinguishing nozzle 9 is provided with a fire extinguishing agent discharging portion 13 formed in a spiral shape. The combustible material fire extinguishing nozzle 9 is provided in the pipe 7, and the water 8 supplied from the fire extinguishing agent supply unit 5 and flowing through the pipe 7 is discharged from the fire extinguishing agent discharging unit 13 toward the fire extinguishing object 3.

The combustible material fire extinguishing nozzle 9 has a cylindrical base end side portion (nozzle main body portion) 15 connected to the pipe 7 and a spiral tip end side portion (discharging portion constituent portion) protruding from the proximal end side portion 15. It is configured to include 17. A male screw for a pipe is formed on a part of the outer circumference of the base end side portion 15.

Further, the base end side portion 15 is provided with a first cavity portion 19 connected to the pipe 7, and the tip end side portion 17 is provided with a second cavity portion connected to the first cavity portion 19. 21 is provided. The fire extinguishing agent discharging portion 13 is provided in the tip side portion 17, and the water 8 flowing through the pipe 7, the first cavity portion 19 and the second cavity portion 21 in this order flows from the fire extinguishing agent discharging portion 13. It is configured to be discharged toward the fire extinguishing object 3.

Further explaining, the value of the inner diameter of the second cavity 21 (inner diameter of the proximal end portion 15) gradually decreases as the distance from the proximal end side portion 15 increases, and the outer diameter of the spiral distal end side portion 17 becomes smaller. The value of also gradually decreases as the distance from the proximal end side portion 15 increases.

Further, in the fire extinguishing equipment 1, the direction from the first cavity 19 to the second cavity 21 is from top to bottom. That is, the proximal end side portion 15 is located on the upper side, and the distal end side portion 17 is located on the lower side. The discharge direction of the water 8 discharged from the fire extinguishing agent discharge unit 13 is a direction intersecting with the direction from top to bottom. Further, the water 8 is discharged diagonally upward from a part of the fire extinguishing agent discharging portion 13 of the combustible material fire extinguishing nozzle 9.

More specifically, the tip end side portion 17 of the combustible material fire extinguishing nozzle 9 is provided with a first fire extinguishing agent guide surface 23, a second fire extinguishing agent guide surface 25, and a third fire extinguishing agent guide surface 27. ..

The first fire extinguishing agent guide surface 23 is arranged at a portion of the distal end side portion 17 on the proximal end side portion 15 side (provided at the proximal end portion of the distal end side portion 17). The second fire extinguishing agent guide surface 25 is arranged on the tip side portion 17 on the side opposite to the proximal end side portion 15 sandwiched between the first fire extinguishing agent guide surface 23 (intermediate portion of the tip end side portion 17). It is provided in). The third fire extinguishing agent guide surface 27 is arranged on the tip side portion 17 on the opposite side of the first fire extinguishing agent guide surface 23 with the second fire extinguishing agent guide surface 25 in between (tip side portion 17). It is provided at the tip of the fire extinguisher).

As a result, the first fire extinguishing agent guide surface 23, the second fire extinguishing agent guide surface 25, and the third fire extinguishing agent guide surface 27 are arranged in this order in the direction from top to bottom.

In the combustible material fire extinguishing nozzle 9 of the fire extinguishing equipment 1, the water 8 discharged from the fire extinguishing agent discharging unit 13 is configured to be discharged obliquely upward by the first fire extinguishing agent guide surface 23. Further, the third fire extinguishing agent guide surface 27 is configured so that the water 8 discharged from the fire extinguishing agent discharging unit 13 is discharged diagonally downward. Further, the water 8 discharged from the fire extinguishing agent discharge unit 13 by the second fire extinguishing agent guide surface 25 is obliquely upward by the first fire extinguishing agent guide surface 23 and diagonally downward by the third fire extinguishing agent guide surface 27. It is configured to be emitted in the direction between and (for example, almost horizontally).

That is, the water 8 flowing through the portion of the pipe 7 near the proximal end side portion 15 is the first of the combustible material fire extinguishing nozzle 9 without substantially changing its flow direction (for example, the direction from top to bottom). Flows through the cavity 19 and the second cavity 21 of the fire extinguishing agent, and then changes the direction of the flow (changes in the direction intersecting the direction from the upper side to the lower side) and is discharged from the fire extinguishing agent discharge part 13. NS.

The water immediately after being discharged from the fire extinguishing agent discharging unit 13 (water immediately after being discharged from the fire extinguishing agent discharging unit 13) 8 has a predetermined velocity in the intersecting and intersecting directions (roughly, the horizontal direction), but has gravity. Due to acceleration and air resistance, the direction of velocity is gradually changed downward to reach the fire extinguishing object 3.

Here, the fire extinguishing equipment 1 will be described in more detail with reference to FIGS. 1 and 2.

The fire extinguishing agent supply unit 5 includes a fire extinguishing water tank (ground type fire extinguishing water tank) 29, a fire extinguishing pump 31, a motor 33, a motor control panel 35, and a fire extinguishing equipment control panel 37. Water 8 is supplied from the water supply source 39 to the fire extinguishing water tank (water storage tank) 29, and the supplied water 8 is stored. The height position of the fire extinguishing water tank 29 from the ground or the floor is about 2 m to 10 m.

The fire extinguishing pump 31 is driven by a motor 33, and when the fire extinguishing pump 31 operates, water 8 is supplied to the combustible material fire extinguishing nozzle 9 through the pipe 7. In FIG. 1, the one indicated by reference numeral 41 is a sluice valve, the one indicated by reference numeral 43 is a ball tap, the one indicated by reference numeral 45 is a liquid level sensor of water 8, and the one indicated by reference numeral 47 is a sluice valve. Is a strainer, the one indicated by reference numeral 49 is a compound meter, and the one indicated by reference numeral 51 is a pressure gauge.

Further, what is indicated by reference numeral 53 in FIG. 1 is an automatic valve, what is indicated by reference numeral 55 is a drain valve, what is indicated by reference numeral 57 is a coupling joint, and what is indicated by reference numeral 58 is a reverse valve. The stop valve, which is indicated by reference numeral 62, is a flow meter, and the one indicated by reference numeral 60 is a relief valve. The flow meter 62 is used when inspecting whether or not the fire extinguishing pump 31 is operating normally, and the relief valve 60 is used when the discharge pressure of the fire extinguishing pump 31 exceeds a predetermined value. This is for returning the water 8 to the fire extinguishing water tank 29.

As shown in FIG. 2, the inside of the designated combustible material storage tank 11 is formed in a circular shape in a plan view, and the combustible material fire extinguishing nozzle 9 has a predetermined interval for one designated combustible material storage tank 11. Multiple (for example, nine) are arranged. The circle 59 shown by the alternate long and short dash line in FIG. 2 is the discharge range of water 8 in the combustible material fire extinguishing nozzle 9 in the fire extinguishing object 3. For example, water 8 is sprayed inside the circle 59A from the central combustible fire extinguishing nozzle 9A.

In the fire extinguishing equipment 1, the discharge pressure of the water 8 from the combustible material fire extinguishing nozzle 9 is set to about 0.1 MPa, and the fire extinguishing agent is discharged downward from the combustible material fire extinguishing nozzle 9. In this case, in the fire extinguishing equipment 1, one combustible material fire extinguishing nozzle 9 can sprinkle 10 L / min of water per ^{1 m 2 in a range of about 11 m in diameter centered on the combustible material fire extinguishing nozzle 9.} The range having a diameter of about 11 m (a range in a plan view) is a range in a plane developed in the horizontal direction separated downward by a predetermined distance (for example, 1 m) from the combustible material fire extinguishing nozzle 9.

Further explaining, in the fire extinguishing equipment 1, when the discharge pressure of the water 8 from the combustible material fire extinguishing nozzle 9 is set to 0.1 MPa or more and the fire extinguishing agent is discharged downward from the combustible material fire extinguishing nozzle 9, 1 With one combustible material fire extinguishing nozzle 9, 10 L / min of water can be sprinkled per ^{1 m 2 in} a range of 11 m or more in diameter centered on the combustible material fire extinguishing nozzle 9.

Further, as the discharge pressure of the water 8 from the combustible material fire extinguishing nozzle 9, a predetermined pressure between 0.1 MPa and 0.2 MPa can be set, preferably a predetermined pressure between 0.1 MPa and 0.15 MPa. The pressure can be raised, and more preferably, a predetermined pressure between 0.1 MPa and 0.12 MPa can be raised. As a range of about 11 m in diameter, a predetermined range between 9 m and 13 m in diameter can be set, preferably, a predetermined range between 10 m in diameter and 12 m in diameter can be set, and more preferably 10 in diameter. A predetermined range between .5 m and 11.5 m in diameter can be set.

Next, the operation of the fire extinguishing equipment 1 shown in FIGS. 1 and 2 will be described with reference to FIGS. 8 and 9.

First, manual start-up (on-site start-up operation) will be described with reference to FIG.

In the normal state (S5), the administrator is waiting at the manual position (position for manual operation) (S1), and the manual indicator light provided on the fire extinguishing equipment control panel (water spray fire extinguishing equipment control panel) 37. Is lit (S3).

When a fire breaks out in the designated combustible material storage tank 11 (S7), the administrator visually confirms the fire (S9). When it is confirmed that a fire has occurred, the start preparation push button provided on the fire extinguishing equipment control panel 37 is pressed to turn it on (S11), and the start push button provided on the fire extinguishing equipment control panel 37 is pressed to turn on the fire extinguishing equipment. 1 is activated (S13).

Subsequently, the fire extinguishing equipment control panel 37 issues a start command to the fire extinguishing pump 31 (S17), activates the fire extinguishing pump 31 (S19), and issues an electromagnetic valve opening command to the district selection valve (automatic valve) 53 (S15). .. The solenoid valve open command to the district selection valve 53 is, for example, three automatic in the event of a fire in one of the three designated combustibles storage tanks 11 (11A, 11B, 11C). It is directed at one of the valves 53 (53A, 53B, 53C), the solenoid valve (the solenoid valve connected to the designated combustibles storage tank 11A) 53A.

Subsequently, the district selection valve 53 is opened (S21), and water is discharged to the designated combustible material storage tank 11 (S23). For example, when a fire breaks out in the designated combustibles storage tank 11A, the automatic valve 53A is opened and water is discharged in the designated combustibles storage tank 11A.

The administrator may manually specify which of the plurality of district selection valves 53 is to be opened, or a fire detection sensor is provided for each of the designated combustibles storage tanks 11. May be provided and the operation may be performed automatically.

Subsequently, when the fire extinguishing is confirmed by the administrator (S25), the fire extinguishing equipment 1 is restored (S27).

Next, manual activation (remote activation operation) will be described with reference to FIG.

In the normal state (S55), the administrator is waiting at the manual position (S51), and the manual indicator lamp provided on the fire extinguishing equipment control panel (water spray fire extinguishing equipment control panel; central disaster prevention panel) 37 lights up. Yes (S53).

When a fire breaks out in the designated combustible material storage tank 11 (S57), the administrator visually confirms the fire (S59). When it is confirmed that a fire has occurred, the start preparation push button provided on the fire extinguishing equipment control panel 37 is pressed to turn it on (S61), and the start push button provided on the fire extinguishing equipment control panel 37 is pressed to turn on the fire extinguishing equipment. 1 is activated (S63).

Subsequently, the fire extinguishing equipment control panel 37 issues a start command to the fire extinguishing pump 31 (S69) to start the fire extinguishing pump 31 (S71), and at the same time, the district selection valve (automatic valve) is as in the case shown in FIG. A solenoid valve open command is issued to 53 (S67).

Subsequently, the district selection valve 53 is opened (S73), and water is discharged to the designated combustibles storage tank 11 (S75). Subsequently, when the fire extinguishing is confirmed by the administrator (S77), the fire extinguishing equipment 1 is restored (S79).

According to the fire extinguishing equipment 1, water 8 is discharged from the spiral fire extinguishing agent discharging portion 13 of the combustible material fire extinguishing nozzle 9 toward the fire extinguishing object 3, so that the fire extinguishing equipment 2 supplies the water 8 to the combustible material fire extinguishing nozzle 9. Even if the lift of the pump 31 is lowered and the output is lowered, the water 8 satisfying the above-mentioned conditions of the Fire Fighting Law can be discharged. Then, the initial cost and running cost of the fire extinguishing equipment 1 can be reduced.

Further explaining, by using the combustible material fire extinguishing nozzle 9 provided with the spiral fire extinguishing agent discharging unit 13 in the fire extinguishing equipment 1, the value of the flow path resistance of the water 8 in the combustible material fire extinguishing nozzle 9 can be lowered. can. And, one of the capacities of the fire extinguishing pump 31, which has a high ratio of the total construction cost, is the lift (total head of the pump = design pressure conversion head of spray nozzle + friction loss head of piping + head (from water source water tank to water spray nozzle). The height difference)) can be simply lowered by 25 m (35 m-10 m) with the pressure-converted head. As a result, the output of the motor 33 of the fire extinguishing pump 31 can also be reduced, the amount of electric power consumed for operating the fire extinguishing equipment 1 can be reduced, and the fire extinguishing pump 31 whose capacity is lowered by two ranks is used. It is possible to reduce the cost.

Further, in the designated combustible material storage tank 11 in which the combustible material fire extinguishing nozzle 9 is installed, coal / recycled resource fuel may fly up and adhere to the combustible material fire extinguishing nozzle 9, but the combustible material fire extinguishing nozzle 9 Then, since the water 8 is discharged from the fire extinguishing agent discharging portion 13 formed in a spiral shape, the discharged water 8 makes it easy to blow off the coal powder and wood powder adhering to the combustible material fire extinguishing nozzle 9.

Further, in the fire extinguishing equipment 1, the combustible material fire extinguishing nozzle 9 is configured to include a proximal end side portion 15 and a spiral distal end side portion 17 protruding from the proximal end side portion 15, and the proximal end side portion 15 Is provided with a first cavity 19 connected to the pipe 7, and a second cavity 21 connected to the first cavity 19 of 1 is provided at the tip end side portion 17. The fire extinguishing agent discharging portion 13 is provided in the tip side portion 17, and the water 8 flowing through the pipe 7, the first cavity portion 19 and the second cavity portion 21 in this order is discharged from the fire extinguishing agent discharging portion 13. It is configured to be. Thereby, the resistance value of the flow path of the water 8 in the combustible material fire extinguishing nozzle 9 can be surely lowered.

Further, in the fire extinguishing equipment 1, the direction from the first cavity 19 to the second cavity 21 is from top to bottom, and the discharge direction of the water 8 discharged from the fire extinguishing agent discharge portion 13 is The direction intersects the direction from top to bottom, and the water 8 is configured to be discharged diagonally upward from a part of the fire extinguishing agent discharging portion 13. As a result, the water 8 discharged from the fire extinguishing agent discharging unit 13 spreads over a wide range in the horizontal direction, and is between the fire extinguishing object 3 and the combustible material fire extinguishing nozzle 9 installed above the fire extinguishing object 3. Even if the value of the distance in the height direction is small, the water 8 can be sprayed over a wide range of the fire extinguishing object 3 over a wide range.

Further, in the fire extinguisher equipment 1, the water 8 discharged from the fire extinguishing agent discharging unit 13 is discharged obliquely upward by the first fire extinguishing agent guide surface 23, and the third fire extinguishing agent guide surface 27 The water 8 discharged from the fire extinguishing agent discharging unit 13 is configured to be discharged diagonally downward, and the water discharged from the fire extinguishing agent discharging unit 13 by the second fire extinguishing agent guide surface 25 is the first. It is configured to be discharged in a direction between the diagonally upward direction by the fire extinguishing agent guide surface 23 and the diagonally downward direction by the third fire extinguishing agent guide surface 27. As a result, the water 8 discharged from the fire extinguishing agent discharging unit 13 can be uniformly sprayed on the fire extinguishing object 3 over a wide range in the horizontal direction.

Next, here, the fire extinguishing equipment 1a according to the modified example will be described with reference to FIGS. 10 and 11.

In the fire extinguishing equipment 1a, the fire extinguishing agent supply unit 5 is installed in the fire extinguishing pump room 61 except for the fire extinguishing water tank (underground fire extinguishing water tank) 29. The underground fire extinguishing water tank 29 is located about 4 m underground. The fire extinguishing agent supply unit 5 includes a priming tank 63, a fire extinguishing water tank 29, a fire extinguishing pump 31, a motor 33, a motor control panel 35, and a fire extinguishing equipment control panel (not shown). The reference reference numerals shown in FIGS. 10 and 11 and the reference numerals shown in FIGS. 1 and 2 are the same. The priming tank 63 can pump up the water 8 of the fire extinguishing water tank 29 under the floor by putting the water 8 into the main body of the fire extinguishing pump 31.

The designated combustibles storage 11 is composed of a building, the inside of the designated combustibles storage 11 is formed in a rectangular parallelepiped shape as shown in FIG. 11, and the combustibles fire extinguishing nozzle 9 is one designated combustible. A plurality of storages 11 are arranged at predetermined intervals. The alternate long and short dash line 59 shown in FIG. 11 is the spray range of water 8 in the combustible material fire extinguishing nozzle 9. For example, in FIG. 11B, water 8 is sprayed below the alternate long and short dash line 59.

Next, the operation of the manual start (on-site start operation) of the fire extinguishing equipment 1 shown in FIGS. 10 and 11 will be described with reference to FIG.

When a fire breaks out in the designated combustibles storage 11 in the normal state (S101) (S103), the manager visually confirms the fire (S105). When it is confirmed that a fire has occurred, the start preparation push button provided on the fire extinguishing equipment control panel (pump control panel) 37 is pressed to turn it on (S107).

Subsequently, a start command is issued from the fire extinguishing equipment control panel 37 to the fire extinguishing pump 31 (S109), the fire extinguishing pump 31 is activated (S111), the district selection valve (manual valve) 53 is opened (S113), and the designated combustibles storage facility is used. Water is discharged to 11 (S115).

Subsequently, when the fire extinguishing is confirmed by the administrator (S117), the fire extinguishing equipment 1 is restored (S119).

Next, the combustible material fire extinguishing nozzle 9 will be described in more detail with reference to FIGS. 3 to 5.

The combustible material fire extinguishing nozzle 9 includes a cylindrical base end side portion 15 and a spiral tip end side portion 17. The base end side portion 15 is provided with a fire extinguishing agent supply port 65 to which water 8 is supplied, and a first cavity portion 19 extending in a predetermined direction from the fire extinguishing agent supply port 65.

The tip side portion 17 is for discharging the second cavity 21 connected to the first cavity 19 and the water 8 in the second cavity 21 connected to the second cavity 21. A spiral fire extinguishing agent discharging portion 13 is formed. Further, the tip end side portion 17 protrudes from the base end side portion 15 at a portion different from the fire extinguishing agent supply port 65 (for example, on the side opposite to the fire extinguishing agent supply port 65).

In the first cavity portion 19, the water 8 supplied by the fire extinguishing agent supply port 65 flows from the base end side on the fire extinguishing agent supply port 65 side toward the tip end side on the second cavity 21 side. It has become. In the second cavity portion 21, the fire extinguishing agent supply port 65 is supplied from the base end side, which is the side of the first cavity portion 19, to the tip end side, which is the side opposite to the first cavity portion 19. The structure is such that the water (fire extinguishing agent) 8 that has flowed through the cavity 19 of the above flows. The direction in which the water 8 flows in the first cavity 19 and the direction in which the water 8 flows in the second cavity 21 are substantially the same as each other.

A first fire extinguishing agent guide surface 23 is formed on the tip side portion 17 (fire extinguishing agent discharging portion 13). Then, the water 8 discharged from the fire extinguishing agent discharging unit 13 is configured to be discharged in the first oblique direction by the first fire extinguishing agent guide surface 23.

The first oblique direction by the first fire extinguishing agent guide surface 23 is a direction in which the proximal end side and the distal end side are connected to each other (for example, in the vertical direction), and the direction from the distal end side to the proximal end side (for example, from top to bottom). The direction in which the proximal end side and the distal end side are orthogonal to each other (for example, the horizontal direction), and the direction away from the distal end side portion 17 are combined.

Further, a second fire extinguishing agent guide surface 25 and a third fire extinguishing agent guide surface 27 are formed on the tip side portion 17.

The first fire extinguishing agent guide surface 23 is arranged at a portion of the distal end side portion 17 on the proximal end side portion 15 side (provided at the proximal end portion of the distal end side portion 17). The second fire extinguishing agent guide surface 25 is arranged on the tip side portion 17 on the side opposite to the proximal end side portion 15 sandwiched between the first fire extinguishing agent guide surface 23 (intermediate portion of the tip end side portion 17). It is provided in). The third fire extinguishing agent guide surface 27 is arranged on the tip side portion 17 on the opposite side of the first fire extinguishing agent guide surface 23 with the second fire extinguishing agent guide surface 25 in between (tip side portion 17). It is provided at the tip of the fire extinguisher).

Further, the water 8 discharged from the fire extinguishing agent discharging unit 13 is configured to be discharged in the second oblique direction by the third fire extinguishing agent guide surface 27.

The second oblique direction by the third fire extinguishing agent guide surface 27 is a direction in which the proximal end side and the distal end side are connected to each other, from the proximal end side to the distal end side (the first fire extinguishing agent guide surface 23). The direction opposite to the case) and the direction in which the proximal end side and the distal end side are orthogonal to each other and away from the distal end side portion 17 (same as in the case of the first fire extinguishing agent guide surface 23). Direction) is the combined direction.

Further, the water 8 discharged from the fire extinguishing agent discharge unit 13 by the second fire extinguishing agent guide surface 25 is in the first oblique direction by the first fire extinguishing agent guide surface 23 and by the third fire extinguishing agent guide surface 27. It is configured to be emitted in the direction between the two diagonal directions.

The direction between the first oblique direction and the second oblique direction on the second fire extinguishing agent guide surface 25 will be illustrated. Assuming that the first diagonal direction is the 1 o'clock direction and the second diagonal direction is the 5 o'clock direction, the directions between the first diagonal direction and the second diagonal direction are the 1 o'clock direction and the 5 o'clock direction. It means the direction of 2 o'clock, the direction of 3 o'clock, the direction of 4 o'clock, etc., which are the directions between and the direction of.

As described above, the diameter of the spiral tip-side portion 17 gradually decreases as the distance from the proximal end-side portion increases, and the tip-side portion 17 has a first fire extinguishing agent guide surface 23 and a second fire extinguishing agent guide surface 23. A fire extinguishing agent guide surface 25 and a third fire extinguishing agent guide surface 27 are formed.

Then, when the direction of the normal vector of the first fire extinguishing agent guide surface 23 (the normal vector facing away from the meat portion of the tip end side portion 17) is the direction in which the base end side and the tip end side are connected to each other. The direction is from the tip end side to the base end side, and in the direction orthogonal to the direction in which the base end side and the tip end side are connected to each other, the direction is toward the center of the tip end side portion 17.

Further, when the direction of the normal vector of the second fire extinguishing agent guide surface 25 (the normal vector facing away from the meat portion of the tip side portion 17) is the direction in which the base end side and the tip end side are connected to each other. The direction is from the tip side to the base end side. The value of the component of the normal vector of the second fire extinguishing agent guide surface 25 in the direction orthogonal to the direction in which the base end side and the tip end side are connected to each other is approximately "0".

The direction of the normal vector of the third fire extinguishing agent guide surface 27 (the normal vector facing away from the meat portion of the tip side portion 17) is the tip side in the direction in which the base end side and the tip end side are connected to each other. In the direction perpendicular to the direction in which the proximal end side and the distal end side are connected to each other, the direction is away from the center of the distal end side portion 17.

More specifically, the proximal end side portion 15 is formed in a tubular shape (for example, a cylindrical shape). The first cavity portion 19 is formed of a hollowed-out portion inside the tubular base end side portion 15, and is formed, for example, in a cylindrical shape. The central axis of the cylinder of the first cavity 19 and the central axis of the cylinder of the proximal end side portion 15 coincide with each other. The fire extinguishing agent supply port 65 is formed by an opening (one end of the first cavity 19) on one side of the central axis of the cylinder forming the first cavity 19 in the extending direction.

The distal end side portion 17 protrudes from the proximal end side portion 15 on the side opposite to the fire extinguishing agent supply port 65. The central axis of the spiral tip-side portion 17 and the central axis of the cylinder of the first cavity 19 (the central axis of the proximal end-side portion 15) coincide with each other.

The diameter (inner diameter and outer diameter) of the spiral of the distal end side portion 17 gradually decreases from the proximal end side, which is the proximal end side portion 15 side, toward the distal end side. The second cavity 21 is formed in a truncated cone shape. The diameter of the bottom surface of the truncated cone-shaped second cavity 21 is equal to the diameter of the cylindrical first cavity 19 and is equal to the central axis of the truncated cone-shaped second cavity 21. The central axis of the columnar first cavity 19 coincides with each other.

The spiral fire extinguishing agent discharging portion 13 is formed in the spiral gap of the tip side portion 17. As shown in FIG. 5A, the shape of the cross section of the tip side portion 17 (the shape of the cross section in a plane including the central axis of the tip side portion 17) is, for example, parallel four sides at the first fire extinguishing agent guide surface 23. It is formed in a rectangular shape. The cross-sectional shape of the tip end side portion 17 is formed in a rectangular shape close to a trapezoid at the second fire extinguishing agent guide surface 25 and the third fire extinguishing agent guide surface 27.

One side (first side) 23A of the four sides of the cross section of the tip end side portion 17 at the first fire extinguishing agent guide surface 23 is the first fire extinguishing agent guide surface 23. The first side (fire extinguishing agent guide surface constituent side) 23A, which is the first fire extinguishing agent guide surface 23, is a side facing the base end side portion 15 side (base end side). The fire extinguishing agent guide surface constituent side 23A is a wall surface forming the fire extinguishing agent discharging portion 13.

The second side 23B of the four sides of the cross section of the tip side portion 17 at the first fire extinguishing agent guide surface 23 is the wall surface of the second cavity portion 21 (inner surface of the tip side portion 17). The third side 23C of the four sides is the outer surface of the tip side portion 17. The fourth side 23D of the four sides is a side facing the side opposite to the base end side portion 15 and located on the side opposite to the first fire extinguishing agent guide surface 23. be. The fourth side 23D is also a wall surface forming the fire extinguishing agent discharging portion 13.

Further, as shown in FIG. 5A, the intersection angle θ1 between the fire extinguishing agent guide surface constituent side 23A and the central axis of the tip side portion 17 is preferably a predetermined angle between 60 ° and 75 °, and is 65 °. A predetermined angle between 1 and 70 ° is even more preferred.

One side (first side) 25A of the four sides of the cross section of the tip end side portion 17 at the second fire extinguishing agent guide surface 25 is the second fire extinguishing agent guide surface 25. The first side (fire extinguishing agent guide surface constituent side) 25A is a side facing the base end side portion 15 side (base end side). The fire extinguishing agent guide surface constituent side 25A is a wall surface forming the fire extinguishing agent discharging portion 13. Further, the fire extinguishing agent guide surface constituent side 25A is orthogonal to or intersects with the central axis of the second cavity 21 at an angle close to a right angle. That is, as shown in FIG. 5A, the intersection angle θ2 between the fire extinguishing agent guide surface constituent side 25A and the central axis of the tip side portion 17 is preferably a predetermined angle between 75 ° and 95 °, and is 80 °. A predetermined angle between 1 and 90 ° is even more preferred.

The second side 25B of the four sides of the cross section of the tip side portion 17 at the second fire extinguishing agent guide surface 25 becomes the wall surface (inner surface of the tip side portion) of the second cavity portion 21. The third side 25C of the four sides is the outer surface of the tip side portion 17. The fourth side 25D of the four sides is a side facing the side opposite to the base end side portion 15 and located on the side opposite to the second fire extinguishing agent guide surface 25. be. The fourth side 25D is also a wall surface constituting the fire extinguishing agent discharging portion 13.

One side (first side) 27 of the four sides of the cross section of the tip end side portion 17 at the third fire extinguishing agent guide surface 27 is the third fire extinguishing agent guide surface 27. The first side (fire extinguishing agent guide surface constituent side) 27A is a side facing the base end side portion 15 side (base end side). The fire extinguishing agent guide surface-to-constituent side 27A is a wall surface constituting the fire extinguishing agent discharging portion 13.

The second side 27B of the four sides of the cross section of the tip side portion 17 at the third fire extinguishing agent guide surface 27 becomes the wall surface (inner surface of the tip side portion) of the second cavity portion 21. The third side 27C of the four sides is the outer surface of the tip side portion 17. The fourth side 27D of the four sides is a side facing the side opposite to the base end side portion 15 and located on the side opposite to the third fire extinguishing agent guide surface 27. be.

Further, as shown in FIG. 5A, the intersection angle θ3 between the fire extinguishing agent guide surface constituent side 27A and the central axis of the tip side portion 17 is preferably a predetermined angle between 45 ° and 70 °, and is 55 °. A predetermined angle between 1 and 65 ° is even more preferred.

Further, as shown in FIG. 3B, between the first extinguishing agent guide surface 23 and the second extinguishing agent guide surface 25, the first extinguishing agent guide surface 23 and the second extinguishing agent guide surface 23 A surface 67 for smoothly connecting the surface 25 is formed, and a second fire extinguishing agent guide surface 25 and a second fire extinguishing agent guide surface 25 and a second fire extinguishing agent guide surface 25 are formed between the second fire extinguishing agent guide surface 25 and the third fire extinguishing agent guide surface 27. A surface 69 for smoothly connecting the fire extinguishing agent guide surface 27 of No. 3 is formed. The surface 67 and the surface 69 are formed in a triangular shape, but may be formed in a rectangular shape such as a trapezoid. Further, the fire extinguishing agent guide surface 23 to the fire extinguishing agent guide surface 25 (the surface 67) may be formed smoothly and continuously, and the fire extinguishing agent guide surface 25 to the fire extinguishing agent guide surface 27 (also the surface 69). It may be formed smoothly and continuously.

The spiral tip side portion 17 (fire extinguishing agent discharging portion 13) is formed in a triple spiral shape, and the first fire extinguishing agent guide surface 23 is located at the first winding portion on the proximal end side portion 15 side. The second fire extinguishing agent guide surface 25 is formed at the second winding portion on the side opposite to the proximal end side portion 15 side sandwiching the first fire extinguishing agent guide surface 23. The fire extinguishing agent guide surface 27 of No. 3 is formed at a third winding portion on the opposite side of the second fire extinguishing agent guide surface 25 with the second fire extinguishing agent guide surface 25 in between.

The discharge mode (spray mode) of water 8 in the next combustible material fire extinguishing nozzle 9 will be described with reference to FIGS. 6 and 7.

FIG. 6A shows the relationship between the discharge amount (injection amount) of water 8 in the combustible material fire extinguishing nozzle 9 and the discharge pressure (pressure) of water 8 in the combustible material fire extinguishing nozzle 9. The horizontal axis of FIG. 6A shows the discharge amount of water 8 in the combustible material fire extinguishing nozzle 9, and the vertical axis of FIG. 6A shows the discharge pressure of water 8 in the combustible material fire extinguishing nozzle 9. Shown. The diagram L1 shows the relationship between the discharge amount of water 8 in the combustible material fire extinguishing nozzle 9 and the discharge pressure of water 8 in the combustible material fire extinguishing nozzle 9. From FIG. 6A, it can be seen that if the pressure is 0.1 MPa, an injection amount of 570 L / min can be obtained.

FIG. 6B shows the relationship between the injection angle of water 8 in the combustible material fire extinguishing nozzle 9 and the discharge pressure (pressure) of water 8 in the combustible material fire extinguishing nozzle 9. The horizontal axis of FIG. 6B shows the injection angle of water 8 in the combustible material fire extinguishing nozzle 9, and the vertical axis of FIG. 6B shows the discharge pressure of water 8 in the combustible material fire extinguishing nozzle 9. Shown. When water 8 is discharged from the combustible material fire extinguishing nozzle 9 with the base end side portion 15 of the combustible material fire extinguishing nozzle 9 on the upper side and the tip end side portion 17 on the lower side, the injection angle is from 180 °. Is also large, so that a part of the water 8 is discharged diagonally upward.

The diagram L2 shows the relationship between the injection angle of water 8 in the combustible material fire extinguishing nozzle 9 and the discharge pressure of water 8 in the combustible material fire extinguishing nozzle 9. From FIG. 6B, it can be seen that the injection angle is 220 ° when the pressure is 0.1 MPa.

FIG. 7 shows the discharge direction of the water 8 from the combustible material fire extinguishing nozzle 9. The horizontal axis of FIG. 7 indicates the horizontal distance from the combustible material fire extinguishing nozzle 9, and the vertical axis of FIG. 7 indicates the vertical (downward) distance from the combustible material fire extinguishing nozzle 9. ing. A combustible material fire extinguishing nozzle 9 is installed at point P1 in FIG.

The diagram L3 shows the discharge region of the water 8 in the combustible material fire extinguishing nozzle 9 installed at the point P1, and the water 8 is discharged below the diagram L3. A combustible material fire extinguishing nozzle 9 is shown in the upper left corner of FIG. 7.

Referring to FIG. 7, the diagram L3 passes through a horizontal radius of 5.5 m at a position 1 m below the combustible material fire extinguishing nozzle 9. Further, at a distance of 2 m to 3 m in the horizontal direction from the combustible material fire extinguishing nozzle 9, a water flow exists 0.6 m above the combustible material fire extinguishing nozzle 9.

1 Fire extinguishing equipment 3 Fire extinguishing object (designated combustible material)
5 Fire extinguishing agent supply part 7 Piping 8 Fire extinguishing agent (water)
9 Combustibles fire extinguishing nozzle 13 Fire extinguishing agent discharge part 15 Base end side part 17 Tip side part 19 First cavity part 21 Second cavity part 23 First fire extinguishing agent guide surface 25 Second fire extinguishing agent guide surface 27 Fire extinguishing agent guide surface of 3 65 Fire extinguishing agent supply port

Claims (4)

The fire extinguishing agent supply unit that supplies the fire extinguishing agent and
The piping extending from the fire extinguishing agent supply unit and
A combustible fire extinguishing nozzle provided in the pipe and supplied from the fire extinguishing agent supply unit and flowing through the pipe is discharged from the spirally formed fire extinguishing agent discharging unit toward the fire extinguishing object. , it possesses,
The combustible material fire extinguishing nozzle is configured to include a proximal end side portion connected to the pipe and a spiral distal end side portion protruding from the proximal end side portion.
A first cavity connected to the pipe is provided at the base end side portion.
A second cavity connected to the first cavity is provided in the tip side portion.
The fire extinguishing agent discharging portion is provided at the tip side portion, and is provided.
The fire extinguishing agent flowing through the pipe, the first cavity portion, and the second cavity portion is configured to be discharged from the fire extinguishing agent discharging portion.
The direction from the first cavity to the second cavity is from top to bottom.
The discharge direction of the fire extinguishing agent discharged from the fire extinguishing agent discharging portion is a direction intersecting with the direction from the top to the bottom.
A first fire extinguishing agent guide surface, a second fire extinguishing agent guide surface, and a third fire extinguishing agent guide surface are provided on the tip side portion.
The first fire extinguishing agent guide surface is arranged at a portion of the tip end side portion on the proximal end side portion side, and the second fire extinguishing agent guide surface is sandwiched between the first fire extinguishing agent guide surface. The third fire extinguishing agent guide surface is arranged on the tip side portion on the side opposite to the base end side portion, and the first fire extinguishing agent guide surface is sandwiched between the second fire extinguishing agent guide surface. It is located on the tip side portion on the side opposite to the agent guide surface.
The first fire extinguishing agent guide surface is configured so that the fire extinguishing agent discharged from the fire extinguishing agent discharging portion is discharged in an obliquely upward direction.
The third fire extinguishing agent guide surface is configured so that the fire extinguishing agent discharged from the fire extinguishing agent discharging portion is discharged diagonally downward.
The fire extinguishing agent released from the extinguishing agent discharging portion by the second extinguishing agent guide surface is obliquely upward by the first extinguishing agent guide surface and diagonally downward by the third extinguishing agent guide surface. A fire extinguishing facility characterized in that it is configured to be emitted in the direction between them. The fire extinguishing equipment according to claim 1.
The direction from the first cavity to the second cavity is from top to bottom.
The discharge direction of the fire extinguishing agent discharged from the fire extinguishing agent discharging portion is a direction intersecting with the direction from the top to the bottom.
A fire extinguishing system characterized in that the fire extinguishing agent is discharged diagonally upward from a part of the fire extinguishing agent discharging portion. The fire extinguishing equipment according to claim 1.
When the discharge pressure of the fire extinguishing agent from the combustible material fire extinguishing nozzle is set to about 0.1 MPa and the fire extinguishing agent is discharged downward from the combustible material fire extinguishing nozzle, the combustible material fire extinguishing nozzle causes the above. A fire extinguishing facility characterized in that a fire extinguishing agent of 10 L / min per 1 m2 can be sprayed in a range of about 11 m in diameter centered on a combustible fire extinguishing nozzle. A base end side portion provided with a fire extinguishing agent supply port to which a fire extinguishing agent is supplied and a first cavity portion extending in a predetermined direction from the fire extinguishing agent supply port.
A second cavity connected to the first cavity and a spiral fire extinguishing agent discharging portion for discharging the fire extinguishing agent in the second cavity are formed, and the base end side portion is formed. The spiral tip side part protruding from
In the second cavity portion, the fire extinguishing agent is configured to flow from the base end side, which is the first cavity portion side, to the tip end side, which is the opposite side to the first cavity portion. And
A first fire extinguishing agent guide surface is formed on the tip side portion.
The first fire extinguishing agent guide surface is configured so that the fire extinguishing agent discharged from the fire extinguishing agent discharging portion is discharged in the first oblique direction.
The first oblique direction is a direction in which the base end side and the tip end side are connected to each other from the tip end side to the base end side, and the base end side and the tip end side are connected to each other. It is a direction that is a combination of the direction orthogonal to the direction and the direction away from the tip side portion.
A second fire extinguishing agent guide surface and a third fire extinguishing agent guide surface are formed on the tip side portion.
The first fire extinguishing agent guide surface is arranged at a portion of the tip end side portion on the proximal end side portion side, and the second fire extinguishing agent guide surface is sandwiched between the first fire extinguishing agent guide surface. The third fire extinguishing agent guide surface is arranged on the tip side portion on the side opposite to the base end side portion, and the first fire extinguishing agent guide surface is sandwiched between the second fire extinguishing agent guide surface. It is located on the tip side portion on the side opposite to the agent guide surface.
The third fire extinguishing agent guide surface is configured so that the fire extinguishing agent discharged from the fire extinguishing agent discharging portion is discharged in the second oblique direction.
The second oblique direction is a direction in which the base end side and the tip end side are connected to each other from the base end side to the tip end side, and the base end side and the tip end side are connected to each other. It is a direction that is a combination of the direction orthogonal to the direction and the direction away from the tip side portion.
The fire extinguishing agent released from the extinguishing agent discharging portion by the second extinguishing agent guide surface is a second diagonal direction by the first extinguishing agent guide surface and a second by the third extinguishing agent guide surface. A combustible fire extinguishing nozzle characterized in that it is configured to be emitted in a direction between and diagonally.

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