JP2023035579A - Fire-extinguishing nozzle and fire-extinguishing equipment - Google Patents

Abstract

To provide a fire-extinguishing nozzle that can reduce initial cost and running cost of equipment by reducing a lift of a fire-extinguishing pump for supplying water to a fire-extinguishing nozzle and reducing output power.SOLUTION: A fire-extinguishing nozzle 9 includes: a proximal side part 15 connected and fixed to piping 5; a fire-extinguishing agent supply port 14 formed in a part of a first hollow part 19 connected to the piping 5, and supplied with a fire-extinguishing agent 7; and a fire-extinguishing agent discharge part 13 formed into a spiral shape continuously from the fire-extinguishing agent supply port 14 and discharging the fire-extinguishing agent 7 supplied to the fire-extinguishing agent supply port 14.SELECTED DRAWING: Figure 2

Description

The present invention relates to fire extinguishing nozzles and fire extinguishing equipment.

Conventionally, there has been known a multi-type water discharge head (fire extinguishing nozzle) in which a bowl-shaped deflector is provided with water holes arranged in a plurality of annular stages, and water holes in a plurality of upper and lower stages are alternately drilled vertically. (see Patent Document 1). By using a conventional multi-type water discharge head, it is possible to spray water evenly over a wide area. Conventionally, fire extinguishing equipment for large spaces in commercial facilities extinguishes fires by spraying water from high ceilings of buildings using water fire extinguishing nozzles (water discharge type heads).

JP-A-10-179788

By the way, in the fire extinguishing equipment using the fire extinguishing nozzle or the like described in Patent Literature 1, water is sprinkled at a rate of 1,000 L/min in a required water sprinkling area of 10 m in diameter. It is assumed that the discharge pressure of the water discharge type head at this time is increased from 0.25 MPa to 0.5 MPa.

However, in the conventional fire extinguishing equipment, the pressure of the extinguishing agent such as water supplied to the extinguishing nozzle must be increased. Therefore, there is a demand to reduce the initial cost and running cost of the equipment by lowering the lift and output of the fire pump that supplies water to the fire extinguishing nozzle of the fire extinguishing equipment.

The present invention provides a fire extinguishing equipment and a fire extinguishing nozzle used in this fire extinguishing equipment that can reduce the initial cost and running cost of the equipment by lowering the lift of the fire pump that supplies water to the fire extinguishing nozzle and lowering the output. intended to In addition, compared to the conventional bowl-shaped water discharge head, the spiral water discharge head is designed to enhance the design, and the spiral shape reminiscent of ice cream has a design that does not feel uncomfortable in commercial relocation. The purpose is to provide a nozzle for

A first invention is formed by a base end portion fixedly connected to a pipe, and a first cavity portion connected to the pipe, and an extinguishing agent supply port to which the extinguishing agent is supplied. and a fire-extinguishing agent discharge part that is formed in a spiral shape continuously from the fire-extinguishing agent supply port and that discharges the fire-extinguishing agent supplied to the fire-extinguishing agent supply port. .

A second aspect of the invention comprises a base end portion connected to a pipe, and a spiral tip end portion protruding from the base end portion, and the base end portion includes the A first cavity connected to a pipe is provided, a second cavity connected to the first cavity is provided at the tip side portion, and the extinguishing agent supply port is , the first cavity portion connected to the pipe, the fire extinguishing agent discharge portion is provided in the tip side portion, the pipe, the first cavity portion and the second and the extinguishing agent flowing through the cavity is discharged from the extinguishing agent discharge portion, and the direction from the first cavity to the second cavity is from top to bottom The discharge direction of the extinguishing agent discharged from the extinguishing agent discharging portion is a direction that intersects the direction from top to bottom, and the tip side portion includes a first extinguishing agent An extinguishing agent guide surface, a second extinguishing agent guide surface, and a third extinguishing agent guide surface are provided, and the first extinguishing agent guide surface is a portion of the distal side portion on the proximal side portion side. The second extinguishing agent guide surface is arranged on the distal side portion on the side opposite to the proximal portion with the first extinguishing agent guide surface therebetween, and The third extinguishing agent guide surface is arranged at the tip side portion on the side opposite to the first extinguishing agent guide surface with the second extinguishing agent guide surface therebetween, and the first extinguishing agent guide surface The extinguishing agent discharged from the extinguishing agent discharging portion is configured to be discharged in a first direction by the extinguishing agent guide surface, and is discharged from the extinguishing agent discharging portion by the third extinguishing agent guide surface. The extinguishing agent discharged from the extinguishing agent discharging portion is configured to be discharged in a second direction, and the extinguishing agent discharged from the extinguishing agent discharge portion is configured to be discharged in a second direction by the extinguishing agent guide surface. The fire extinguishing nozzle according to the first invention, which is configured to discharge in a third direction between the first direction by the guide surface and the second direction by the third extinguishing agent guide surface. be.

In a third invention, the first direction is an obliquely upward direction, the second direction is an obliquely downward direction, and the third direction is a direction between the obliquely upward direction and the obliquely downward direction. It is a fire extinguishing nozzle according to the second invention configured to be.

In a fourth aspect of the invention, a surface 6 m away from the extinguishing agent discharge part is a floor surface of a building of a commercial facility, the extinguishing agent discharge part is provided on the ceiling of the building, and the extinguishing agent discharge The fire extinguishing nozzle according to any one of the first to third inventions, wherein the distance between the part and the floor is 6 m or more from the floor.

A fifth aspect of the present invention includes an extinguishing agent supply unit that supplies an extinguishing agent, the pipe extending from the extinguishing agent supply unit, and the pipe provided in the pipe and supplied from the extinguishing agent supply unit and flowing through the pipe. A fire extinguishing equipment comprising: the fire extinguishing nozzle according to any one of the first to fourth inventions, which emits a fire extinguishing agent.

In the sixth aspect of the present invention, an automatic water discharge valve is provided in the middle of the pipe to open the extinguishing agent into the pipe or close the extinguishing agent to block the flow of the extinguishing agent in the pipe. It is a fire extinguishing equipment according to the fifth invention.

A seventh invention is the fire extinguishing equipment according to the fifth or sixth invention, wherein the fire extinguishing nozzle is configured to change the discharge direction of the extinguishing agent in a predetermined pattern.

According to the present invention, the fire extinguishing equipment and the fire extinguishing nozzle used in this fire extinguishing equipment can reduce the initial cost and running cost of the equipment by lowering the lift of the fire extinguishing pump that supplies water to the fire extinguishing nozzle and lowering the output. There is an effect that it is possible to provide In addition, it is possible to improve the design of the fire extinguishing nozzle and provide a fire extinguishing nozzle for fire extinguishing equipment that does not cause a sense of discomfort even when exposed to a commercial space.

BRIEF DESCRIPTION OF THE DRAWINGS It is a figure which shows the outline|summary of the fire extinguishing equipment which concerns on embodiment of this invention. (a) is a perspective view of the fire extinguishing nozzle used in the fire extinguishing equipment according to the embodiment of the present invention, and (b) is another perspective view of the fire extinguishing nozzle used in the fire extinguishing equipment according to the embodiment of the present invention. It is a diagram. (a) is a front view of a fire extinguishing nozzle used in a fire extinguishing equipment according to an embodiment of the present invention, and (b) is a IIIB arrow view in (a). (c) is a IIIC arrow view in (a), (d) is a IIID arrow view in (a), and (e) is a IIIE arrow view in (a). 4(a) is a view showing the IVA-IVA section in FIG. 3, and FIG. 4(b) is a view showing the IVB-IVB section in FIG. It is a figure which shows the ejection amount (release amount) of the water etc. with the fire extinguishing nozzle used for the fire extinguishing equipment which concerns on embodiment of this invention. It is a figure which shows the water-discharge curve of the fire-fighting nozzle used for the fire-extinguishing equipment which concerns on embodiment of this invention. It is a figure which shows another fire-extinguishing nozzle used for the fire-extinguishing equipment which concerns on embodiment of this invention, Comprising: It is a figure corresponding to FIG.3(b). FIG. 6 is a diagram corresponding to FIG. 5 and showing the jetting amount (ejection amount) of water from another fire extinguishing nozzle used in the fire extinguishing equipment according to the embodiment of the present invention; FIG. 7 is a diagram showing a water discharge curve of another fire extinguishing nozzle used in the fire extinguishing equipment according to the embodiment of the present invention, and is a diagram corresponding to FIG. 6 ; FIG. 2 is a diagram (plan view) showing an installation mode of a fire sensor for identifying a fire breakout location and an area where water is discharged from a fire extinguishing nozzle in the fire extinguishing equipment according to the embodiment of the present invention. It is a figure (top view) which shows the arrangement|positioning aspect of the fire extinguishing nozzle (water discharge type head) in the fire extinguishing equipment which concerns on embodiment of this invention. Fig. 2 is a diagram (side view) showing the arrangement of the fire extinguishing nozzle (water discharge type head) in the fire extinguishing equipment according to the embodiment of the present invention and the closed type head of the closed sprinkler system installed in a portion other than the high ceiling. It is a flowchart which shows the operation|movement of automatic starting (only automatic starting mode) of the fire extinguishing equipment which concerns on embodiment of this invention. It is a flowchart which shows the operation|movement of automatic starting (only automatic starting mode) of the fire extinguishing equipment which concerns on embodiment of this invention. It is a flowchart which shows the operation|movement of automatic starting (only automatic starting mode) of the fire extinguishing equipment which concerns on embodiment of this invention. It is a flowchart which shows the operation|movement of manual starting (it can be operated by both automatic starting mode and manual starting mode) of the fire extinguishing equipment which concerns on embodiment of this invention. It is a flowchart which shows the operation|movement of manual starting (it can be operated by both automatic starting mode and manual starting mode) of the fire extinguishing equipment which concerns on embodiment of this invention. It is a flowchart which shows the operation|movement of manual starting (it can be operated by both automatic starting mode and manual starting mode) of the fire extinguishing equipment which concerns on embodiment of this invention.

A fire extinguishing equipment 1 according to an embodiment of the present invention is used, for example, in a high ceiling portion of a commercial facility or the like. As shown in FIG. It is also equipped with a type sprinkler head) 9. The fire extinguishing agent supply unit 3 supplies the extinguishing agent 7 in liquid form or on a fluid basis. Water is listed as extinguishing agent 7.

The pipe 5 extends from the fire extinguishing agent supply unit 3 , and water 7 flows through the inside of the pipe 5 . The fire extinguishing nozzle 9 is provided in the pipe 5 and discharges the water 7 supplied from the extinguishing agent supply unit 3 and flowing through the pipe 5 toward the fire extinguishing target.

In the fire extinguishing equipment 1, an automatic water discharge valve 11 is provided in the middle of the pipe 5 to open the water 7 into the pipe 5 or close the water 7 to block the flow of the water 7 in the pipe 5. It is Since the automatic water discharge valve 11 is provided, the secondary side of the automatic water discharge valve 11 serves as the fire extinguishing equipment 1 that is open to the atmosphere.

As shown in FIGS. 2 to 4, the fire-extinguishing nozzle 9 includes a fire-extinguishing agent discharge portion 13 and a fire-extinguishing agent supply port 14 . Water 7 having a pressure of 0.1 MPa or more is supplied to the extinguishing agent supply port 14 . To explain further, the pressure of the water 7 supplied to the extinguishing agent supply port 14 can be a predetermined pressure between 0.1 MPa and 0.2 MPa. Preferably, a predetermined pressure between 0.1 MPa and 0.15 MPa can be mentioned. More preferably, a predetermined pressure between 0.1 MPa and 0.12 MPa can be listed.

The extinguishing agent discharge part 13 is spirally formed and discharges the water 7 supplied to the extinguishing agent supply port 14 . Fire extinguishing nozzle 9 emits water 7 in an amount of 5 L / min or more (for example, 5 L / min to 7 L / min) per 1 m ² in a circle with a diameter of 11 m on a surface 6 m away from extinguishing agent discharge part 13 ( to reach). For example, a plane 6 m away from the fire extinguishing agent discharge section 13 is the plane 10 . The extinguishing agent discharge part 13 is located 6 m above the plane 10 and discharges the water 7 toward the plane 10 . In plan view, the extinguishing agent discharge part 13 is located at the center of the circle with a diameter of 11 m.

The fire extinguishing nozzle 9 includes a base end portion 15 connected to the pipe 5 and a spiral tip end portion 17 protruding from the base end portion 15 . A part of the outer periphery of the base end portion 15 is formed with a male screw for a pipe for connecting and fixing to the pipe 5 .

The proximal side portion 15 is provided with a first cavity portion 19 that is connected to the pipe 5, and the distal side portion 17 is provided with a second cavity portion 21 that is connected to the first cavity portion 19. is provided. The extinguishing agent supply port 14 is formed at a portion of the first hollow portion 19 connected to the pipe 5 (the end of the base end portion 15 opposite to the tip end portion 17; upper end portion). The extinguishing agent discharge part 13 is provided at the tip side part 17 .

The water 7 flowing through the pipe 5 , the first cavity 19 and the second cavity 21 is discharged from the extinguishing agent discharge part 13 . The direction from the first cavity portion 19 to the second cavity portion 21 is the direction from top to bottom. The discharge direction of the water 7 discharged from the extinguishing agent discharge portion 13 is a direction that intersects the direction from top to bottom. Water 7 is discharged obliquely upward from a part of the fire extinguishing agent discharging portion 13 of the fire extinguishing nozzle 9 shown in FIGS.

More specifically, the tip end portion 17 is provided with a first extinguishing agent guide surface 23 , a second extinguishing agent guide surface 25 and a third extinguishing agent guide surface 27 .

The first extinguishing agent guide surface 23 is arranged at a portion (upper portion) of the distal portion 17 on the proximal side portion 15 side. The second extinguishing agent guide surface 25 is arranged on the distal side portion 17 on the side opposite to the proximal portion 15 with the first extinguishing agent guide surface 23 interposed therebetween. The third extinguishing agent guide surface 27 is arranged at the tip side portion 17 on the side opposite to the first extinguishing agent guide surface 23 with the second extinguishing agent guide surface 25 therebetween. As a result, the first extinguishing agent guide surface 23, the second extinguishing agent guide surface 25, and the third extinguishing agent guide surface 27 are aligned in this order from top to bottom.

The first extinguishing agent guide surface 23 is configured such that the water 7 discharged from the extinguishing agent discharging portion 13 is discharged obliquely upward. The third extinguishing agent guide surface 27 is configured such that the water 7 discharged from the extinguishing agent discharging portion 13 is discharged obliquely downward. The second extinguishing agent guide surface 25 allows the water 7 discharged from the extinguishing agent discharge portion 13 to be directed diagonally upward by the first extinguishing agent guide surface 23 and obliquely downward by the third extinguishing agent guide surface 27 . configured to be emitted in the direction in between.

To explain further, the water 7 that has flowed through the portion of the pipe 5 near the base end portion 15 does not substantially change its flow direction (for example, the direction from top to bottom) until it reaches the first end of the fire extinguishing nozzle 9 . flows through the cavity 19 and the second cavity 21 . After that, the flow direction is changed (changed to a direction crossing the direction from the top to the bottom) and discharged from the extinguishing agent discharge part 13 .

The water 7 immediately after being discharged from the extinguishing agent discharging portion 13 (water immediately after being discharged from the extinguishing agent discharging portion 13) has a predetermined speed in the intersecting direction (roughly speaking, the horizontal direction). However, due to gravitational acceleration and air resistance, the direction of the velocity is gradually changed downward and reaches the extinguishing target existing on the plane 10 .

A floor 10 of a building 8 of a commercial facility (for example, a large-scale commercial facility) is shown as a plane 10 6 m away from the extinguishing agent discharge section 13 . The extinguishing agent discharge part 13 is provided at the ceiling 12 of the building 8 . The distance between the extinguishing agent discharge part 13 and the floor surface 10 is 6 m or more (6 m or more and 20 m or less; further 6 m or more and 12 m or less) from the floor surface 10 in the vertical direction.

The fire extinguishing nozzle 9 is installed on the ceiling 12 at substantially the same height as the ceiling 12 of the building 8 in the vertical direction. Therefore, the height from the floor surface 10 to the ceiling 12 and the height from the floor surface 10 to the extinguishing agent discharging part 13 are substantially the same. Further, the height from the floor surface 10 to the fire extinguishing agent discharging part 13 and the height from the floor surface 10 to the fire extinguishing nozzle 9 are substantially the same. The fire extinguishing nozzle 9 is fixed to the ceiling 12, and its position and attitude with respect to the ceiling do not change, and the distance between the extinguishing agent discharging part 13 and the floor surface 10 is constant. In addition, the fire extinguishing nozzle 9 (extinguishing agent discharging portion 13) may be installed below the ceiling 12 by a predetermined distance.

Further explaining the fire extinguishing nozzle 9, as described above, the water 7 flowing through the pipe 5, the first cavity 19 and the second cavity 21 in this order flows from the fire extinguishing agent discharge part 13 to the floor surface 10. It is configured to be discharged toward the extinguishing target above.

In addition, the value of the inner diameter of the second hollow portion 21 (the inner diameter of the proximal side portion 15) gradually decreases with increasing distance from the proximal side portion 15, and the value of the outer diameter of the spiral distal portion 17 also gradually becomes smaller with distance from the base end portion 15 .

The fire extinguishing nozzle 9 is configured to include a cylindrical base end portion 15 and a spiral tip end portion 17 . The base end portion 15 is provided with an extinguishing agent supply port 14 to which water 7 is supplied, and a first hollow portion 19 extending from the extinguishing agent supply port 14 in a predetermined direction.

The distal end portion 17 includes a second cavity 21 connected to the first cavity 19 and a second cavity 21 connected to the second cavity 21 for discharging the water 7 in the second cavity 21. A spiral extinguishing agent discharge portion 13 is formed. Further, the distal side portion 17 protrudes from the proximal side portion 15 at a location different from the fire extinguishing agent supply port 14 (for example, on the side opposite to the fire extinguishing agent supply port 14).

In the first cavity 19, the water 7 supplied from the fire extinguishing agent supply port 14 flows from the proximal side, which is the fire extinguishing agent supply port 14 side, toward the distal end side, which is the second cavity portion 21 side. It's becoming In the second cavity portion 21, from the base end side which is the side of the first cavity portion 19 toward the tip side which is the side opposite to the first cavity portion 19, the extinguishing agent supply port 14 supplies the first extinguishing agent. The water 7 that has flowed through the inside of the cavity 19 flows. The direction in which the water 7 flows in the first cavity 19 and the direction in which the water 7 flows in the second cavity 21 are substantially the same.

A first extinguishing agent guide surface 23 is formed in the tip side portion 17 (extinguishing agent discharging portion 13). The first extinguishing agent guide surface 23 is configured such that the water 7 discharged from the extinguishing agent discharging portion 13 is discharged in the oblique first direction.

The oblique first direction by the first extinguishing agent guide surface 23 is the direction from the distal side to the proximal side in the direction connecting the proximal side and the distal side, and the direction from the distal side to the distal side. , and the direction away from the tip side portion 17 in the direction perpendicular to the direction in which they are connected to each other.

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

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

Further, the third extinguishing agent guide surface 27 is configured such that the water 7 discharged from the extinguishing agent discharging portion 13 is discharged in the oblique second direction.

The oblique second direction by the third extinguishing agent guide surface 27 is the direction from the proximal side to the distal side in the direction connecting the proximal side and the distal side, and the direction from the proximal side to the distal side. , and the direction away from the tip side portion 17 in the direction perpendicular to the direction in which they are connected to each other.

In addition, the second extinguishing agent guide surface 25 allows the water 7 discharged from the extinguishing agent discharge portion 13 to flow in the first oblique direction due to the first extinguishing agent guide surface 23 and the third extinguishing agent guide surface 27. It is configured to emit in a third direction between the oblique second direction.

The directions between the oblique first direction and the oblique second direction on the second extinguishing agent guide surface 25 are 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 direction between the first diagonal direction and the second diagonal direction is the 1 o'clock direction. The 2 o'clock direction, the 3 o'clock direction, the 4 o'clock direction, etc., which are the directions between the direction and the 5 o'clock direction.

As described above, the diameter of the spiral distal end portion 17 gradually decreases with increasing distance from the proximal end portion. An extinguishing agent guide surface 25 and a third extinguishing agent guide surface 27 are formed.

When the direction of the normal vector of the first extinguishing agent guide surface 23 (the normal vector pointing in the direction away from the meat portion of the distal end portion 17) is in the direction connecting the proximal end side and the distal end side to each other, The direction is from the distal side to the proximal side. Further, the direction perpendicular to the direction connecting the proximal side and the distal side is the direction toward the center of the distal side portion 17 .

In addition, if the direction of the normal vector of the second extinguishing agent guide surface 25 (the normal vector facing the direction away from the meat portion of the tip side portion 17) is the direction that connects the base end side and the tip side with each other, The direction is from the distal side to the proximal side. The value of the component of the normal vector of the second extinguishing agent guide surface 25 in the direction orthogonal to the direction connecting the base end side and the tip end side is approximately "0".

The direction of the normal vector of the third extinguishing agent guide surface 27 (the normal vector pointing in the direction away from the meat portion of the tip side portion 17) is the tip side in the direction connecting the base end side and the tip side. It is in the direction from to the proximal side. Further, the direction perpendicular to the direction connecting the proximal end side and the distal end side is the direction away from the center of the distal side portion 17 .

More specifically, the base end portion 15 is formed in a cylindrical shape (for example, a cylindrical shape). The first hollow portion 19 is formed by hollowing out the inner portion of the tubular proximal end portion 15, and has a columnar shape, for example. The central axis of the cylinder of the first hollow portion 19 and the central axis of the cylinder of the base end portion 15 are aligned with each other. The fire extinguishing agent supply port 14 is formed by an opening (one end of the first cavity 19 ) on one side in the extending direction of the central axis of the cylinder forming the first cavity 19 .

The distal side portion 17 protrudes from the proximal side portion 15 on the side opposite to the extinguishing agent supply port 14 . The central axis of the helical distal side portion 17 and the central axis of the cylinder of the first hollow portion 19 (the central axis of the proximal side portion 15) coincide with each other.

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

The spiral fire-extinguishing agent discharge part 13 is formed in the spiral gap of the distal end portion 17 . As shown in FIG. 4( a ), the shape of the cross section of the tip side portion 17 (the shape of the cross section of the plane including the central axis of the tip side portion 17 ) is, for example, a parallelogram at the first extinguishing agent guide surface 23 . It is formed in a rectangular shape. The cross-sectional shape of the tip side portion 17 is formed in a rectangular shape close to a trapezoid at the second extinguishing agent guide surface 25 and the third extinguishing agent guide surface 27 .

One side (first side) 23 A of the four sides of the cross section of the distal end portion 17 at the first extinguishing agent guide surface 23 is the first extinguishing agent guide surface 23 . A first side (extinguishing agent guide surface-constituting side) 23A forming the first extinguishing agent guide surface 23 is a side facing the base end portion 15 (base end side). In addition, the fire extinguishing agent guide surface forming side 23A is a wall surface constituting the 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 extinguishing agent guide surface 23 is the wall surface of the second cavity portion 21 (the inner surface of the tip side portion 17). The third side 23C of the four sides is the outer surface of the distal end portion 17. As shown in FIG. A fourth side 23D of the four sides is a side facing away from the base end portion 15 and located on the side opposite to the first extinguishing agent guide surface 23. be. The fourth side 23D is also a wall surface forming the fire extinguishing agent discharge section 13. As shown in FIG.

Furthermore, as shown in FIG. 4(a), the crossing angle θ1 between the side 23A forming the extinguishing agent guide surface and the central axis of the tip side portion 17 is preferably a predetermined angle between 45° and less than 75°. A predetermined angle of between 0° and less than 75° is more preferred, and a predetermined angle of between 65° and 70° is particularly preferred.

One side (first side) 25</b>A of the four sides of the cross section of the distal end portion 17 at the second extinguishing agent guide surface 25 is the second extinguishing agent guide surface 25 . The first side (extinguishing agent guide surface-constituting side) 25A is a side facing the base end portion 15 side (base end side). In addition, the fire extinguishing agent guide surface forming side 25A is a wall surface constituting the extinguishing agent discharging portion 13 . In addition, the extinguishing agent guide surface-constituting side 25A is orthogonal to the central axis of the second hollow portion 21 or intersects it at an angle close to a right angle. That is, as shown in FIG. 5A, the crossing angle θ2 between the extinguishing agent guide surface forming side 25A and the central axis of the tip side portion 17 is preferably a predetermined angle between 75° and less than 110°. A pre-determined angle between ° and 95° is more preferred, and a pre-defined angle between 80° and 90° is particularly preferred.

The second side 25B of the four sides of the cross section of the tip side portion 17 at the second extinguishing agent guide surface 25 is the wall surface of the second cavity portion 21 (the inner surface of the tip side portion). A third side 25</b>C of the four sides is the outer surface of the distal end portion 17 . A fourth side 25D of the four sides is a side facing away from the base end portion 15 and located on the side opposite to the second extinguishing agent guide surface 25. be. The fourth side 25</b>D is also a wall surface forming the extinguishing agent discharge section 13 .

One side (first side) 27 of the four sides of the cross section of the distal end portion 17 at the third extinguishing agent guide surface 27 is the third extinguishing agent guide surface 27 . The first side (extinguishing agent guide surface configuration side) 27A is a side facing the base end portion 15 side (base end side). In addition, the fire extinguisher guide face pair configuration side 27A is a wall surface constituting the fire extinguisher discharge portion 13 .

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

Further, as shown in FIG. 4(a), the crossing angle θ3 between the fire extinguishing agent guide surface forming side 27A and the central axis of the tip side portion 17 is preferably a predetermined angle between 20° and 70°, and preferably 45°. to 70° is more preferred, and a given angle of between 55° and 65° is particularly 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 25 are provided. A surface 24 is formed to smoothly connect with the surface 25 . Between the second extinguishing agent guide surface 25 and the third extinguishing agent guide surface 27, a surface for smoothly connecting the second extinguishing agent guide surface 25 and the third extinguishing agent guide surface 27 is provided. 26 are formed. Although the surfaces 24 and 26 are formed in a triangular shape, they may be formed in a rectangular shape such as a trapezoid. Furthermore, from the extinguishing agent guide surface 23 to the extinguishing agent guide surface 25 (the surface 24) may be formed smoothly and continuously, and from the extinguishing agent guide surface 25 to the extinguishant guide surface 27 (also the surface 26). It may be formed smoothly and continuously.

The spiral tip side portion 17 (extinguishing agent discharge portion 13) is formed in a triple spiral shape. The first extinguishing agent guide surface 23 is formed at the first turn on the base end portion 15 side. The second fire extinguishing agent guide surface 25 is formed at the second winding portion on the side opposite to the base end side portion 15 with the first extinguishing agent guide surface 23 interposed therebetween. The third fire-extinguishing agent guide surface 27 is formed at the third turn on the side opposite to the second fire-extinguishing agent guide surface 25 with the second fire-extinguishing agent guide surface 25 interposed therebetween.

Next, the discharge mode (spray mode) of the water 7 from the fire extinguishing nozzle 9 will be described with reference to FIGS. 5 and 6. FIG.

FIG. 5( a ) shows the relationship between the discharge amount (jetting amount) of the water 7 from the fire-extinguishing nozzle 9 and the discharge pressure (pressure) of the water 7 from the fire-extinguishing nozzle 9 . The horizontal axis of FIG. 5A indicates the amount of water 7 discharged from the fire extinguishing nozzle 9, and the vertical axis of FIG. A diagram L1 shows the relationship between the discharge amount of the water 7 from the fire-extinguishing nozzle 9 and the discharge pressure of the water 7 from the fire-extinguishing nozzle 9 . It can be seen from FIG. 5(a) that an injection amount of 570 L/min can be obtained at a pressure of 0.1 MPa.

FIG. 5B shows the relationship between the ejection angle of the water 7 from the fire extinguishing nozzle 9 and the discharge pressure (pressure) of the water 7 from the fire extinguishing nozzle 9 . The horizontal axis of FIG. 5B indicates the injection angle of the water 7 from the fire extinguishing nozzle 9, and the vertical axis of FIG. When the water 7 is discharged from the fire extinguishing nozzle 9 with the base end portion 15 of the fire extinguishing nozzle 9 arranged upward and the distal end portion 17 downward, the injection angle is greater than 180°. , part of the water 7 is discharged obliquely upward.

A diagram L2 shows the relationship between the ejection angle of the water 7 from the fire-extinguishing nozzle 9 and the discharge pressure of the water 7 from the fire-extinguishing nozzle 9 . It can be seen from FIG. 5(b) that the injection angle is 220° when the pressure is 0.1 MPa.

FIG. 6 shows the direction of discharge of water 7 from fire extinguishing nozzles 9 . The horizontal axis in FIG. 6 indicates the horizontal distance from the fire-extinguishing nozzle 9 , and the vertical axis in FIG. 6 indicates the vertical (downward) distance from the fire-extinguishing nozzle 9 . A fire extinguishing nozzle 9 is installed at a point P1 in FIG.

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

Referring to FIG. 6, the line L3 passes through a horizontal radius of 5.5 m at a point 1 m below the fire extinguishing nozzle 9 . Further, a water stream exists 0.6 m above the fire extinguishing nozzle 9 at a distance of 2 m to 3 m in the horizontal direction from the fire extinguishing nozzle 9 .

Here, the fire extinguishing equipment 1 will be further described with reference to FIG.

The fire extinguisher supply unit 3 includes a fire water tank (underground type) 29 , a fire pump (including a motor) 31 , a pump control panel 35 and a pressure tank 37 .

Water 7 is appropriately supplied from a water supply source by a make-up water supply unit 39 to the fire extinguishing water tank (water storage tank) 29, and the supplied water 7 is stored. The height position of the fire extinguishing water tank 29 from the ground or floor is not particularly defined.

The fire pump 31 is driven by a motor, and the water 7 is supplied to the fire extinguishing nozzle 9 through the pipe 5 by operating the fire pump 31 . Compressed air is injected into the pressure tank 37 . A pressure switch 41 is provided at the pressure tank 37 to detect a drop in air pressure inside the pressure tank 37 due to a drop in pressure inside the pipe 5 after the water is discharged. A pressure drop is detected by the pressure switch 41 and the fire pump 31 is automatically started.

In addition, the fire extinguishing equipment 1 is provided with an auxiliary elevated water tank 45, a fire sensor 57, a water discharge type sprinkler equipment control field (water discharge type sprinkler equipment control panel) 61, an on-site operation panel 63, and an alarm receiving panel 59. . The automatic water discharge valve 11 is provided with a pressure switch capable of detecting water pressure on the secondary side, and detects the flow of water 7 in the pipe 5 on the secondary side of the automatic water discharge valve 11 .

When the automatic water discharge valve 11 is in a closed state and the pressurized water 7 is filled from the extinguishing agent supply unit 3 to the automatic water discharge valve 11, the water discharge type sprinkler equipment control panel 61 or the field operation is performed. An open signal is output from the board 63 to the electromagnetic valve in the automatic water discharge valve 11 . As a result, the automatic water discharge valve 11 is opened and the water 7 is discharged from the fire extinguishing nozzle 9 .

When the automatic water discharge valve 11 is in the open state, the automatic water discharge valve 11 is closed by outputting a closing signal to the electromagnetic valve in the automatic water discharge valve 11 from the water discharge type sprinkler equipment control panel 61 or the field operation panel 63. become.

While the fire pump 31 is stopped, the water 7 is discharged from the fire extinguishing nozzle 9, and the pressure switch 41 detects that the pressure of the water 7 in the pipe 5 (pressure tank 37) has decreased. This detection activates the fire pump 31 .

By the way, the one shown in FIG. 7 may be employed as the fire extinguishing nozzle 9a. The fire extinguishing nozzle 9a shown in FIG. 7 differs from the fire extinguishing nozzle 9 shown in FIG. 4 in that the first extinguishing agent guide surface 23 is not provided as the extinguishing agent guide surface.

That is, the fire extinguishing nozzle 9a shown in FIG. 7 has a guide surface on the side of the base end portion 15 that is similar to the second guide surface 25 shown in FIG. The guide surface on the opposite side is a guide surface similar to the third guide surface 27 shown in FIG.

Furthermore, even in the fire extinguishing nozzle 9a shown in FIG. 7, a fourth An extinguishing agent guide surface 28 may be provided. At this time, the normal vector of the fourth extinguishing agent guide surface 28 is the normal vector of the extinguishing agent guide surface 25 and the normal vector of the extinguishant guide surface 27 in the direction connecting the proximal end side and the distal end side. is the normal vector in the direction between is the normal vector in the direction between

Next, the discharge mode (spray mode) of the water 7 from the fire extinguishing nozzle 9a shown in FIG. 7 will be described with reference to FIGS. 8 and 9. FIG.

FIG. 8(a) shows the relationship between the discharge amount (jetting amount) of the water 7 from the fire extinguishing nozzle 9a shown in FIG. 7 and the discharge pressure (pressure) of the water 7 from the fire extinguishing nozzle 9a shown in FIG. . The horizontal axis of FIG. 8(a) indicates the discharge amount of the water 7 from the fire extinguishing nozzle 9a shown in FIG. 7, and the vertical axis of FIG. shows the discharge pressure of A diagram L4 shows the relationship between the amount of water 7 discharged from the fire-extinguishing nozzle 9a shown in FIG. 7 and the discharge pressure of the water 7 from the fire-extinguishing nozzle 9a. It can be seen from FIG. 8(a) that an injection amount of 220 L/min can be obtained at a pressure of 0.1 MPa.

FIG. 8(b) shows the relationship between the injection angle of the water 7 in the fire extinguishing nozzle 9a shown in FIG. 7 and the discharge pressure (pressure) of the water 7 in the fire extinguishing nozzle 9a shown in FIG. The horizontal axis of FIG. 8(b) indicates the injection angle of the water 7 in the fire extinguishing nozzle 9a shown in FIG. 7, and the vertical axis of FIG. shows the discharge pressure of When water 7 is discharged from the fire extinguishing nozzle 9a shown in FIG. 7 with the base end portion 15 of the fire extinguishing nozzle 9a shown in FIG. is about 170°.

A diagram L5 shows the relationship between the ejection angle of the water 7 from the fire-extinguishing nozzle 9a shown in FIG. 7 and the discharge pressure of the water 7 from the fire-extinguishing nozzle 9a. It can be seen from FIG. 8(b) that the injection angle is 170° when the pressure is 0.1 MPa.

FIG. 9 shows the discharge direction of the water 7 from the fire extinguishing nozzle 9a shown in FIG. The horizontal axis in FIG. 9 indicates the horizontal distance from the fire extinguishing nozzle 9a shown in FIG. 7, and the vertical axis in FIG. 9 indicates the vertical (downward) direction from the fire extinguishing nozzle 9a shown in FIG. distance. A fire extinguishing nozzle 9a is installed at a point P2 in FIG.

A diagram (broken line) L6 indicates the discharge area of the water 7 in the fire extinguishing nozzle 9a installed at the point P2, and the water 7 is discharged below the diagram L6. . A fire extinguishing nozzle 9a is shown in the upper left corner of FIG.

Here, the nozzles 9 (including the nozzles 9a) and the extinguishing target area 53 by the nozzles 9 will be described with reference to FIGS. 11 and 12. FIG.

FIG. 11 is a plan view, and the extinguishing target area 53 is formed in a rectangular shape in plan view. The plurality of fire-extinguishing nozzles 9 (9a) are arranged at regular intervals within the fire-extinguishing target area 53 . A plurality of fire-extinguishing nozzles 9 (9a) indicate ranges 55 in which water 7 is discharged respectively by a plurality of circles. A plurality of circles 55 are partially overlapped with each other as appropriate. By discharging the fire extinguishing agent from the plurality of fire extinguishing nozzles 9 (9a), a region where the water 7 is not discharged is not formed in the fire extinguishing target area 53 .

Figure 12 is a side view, and even if the height of the ceiling is different, the boundary between the floor surface of the high ceiling part protected by the water discharge sprinkler system and the floor surface of the part other than the high ceiling protected by the closed sprinkler system By providing areas where the water 7 is discharged so as to overlap with each other, areas where the water 7 is not discharged are prevented from being formed.

Here, the floor surface of the high ceiling portion protected by the water discharge type sprinkler equipment using the fire extinguishing nozzle 9 (9a) is the portion where the vertical distance between the floor surface 10 and the ceiling 12 exceeds 10 m, and , In areas where a large amount of combustibles exist and extinguishing is difficult, the vertical distance between the floor surface 10 and the ceiling 12 exceeds 6 m. The floor surface of the part other than the high ceiling protected by the closed sprinkler equipment using the fire extinguishing nozzle 9 (9b) is the part where the vertical distance between the floor surface 10 and the ceiling 12 is 10 m or less, and In areas where a large amount of combustibles exist and it is difficult to extinguish the fire, the vertical distance between the floor surface 10 and the ceiling 12 is 6 m or less.

Next, operation|movement of the fire extinguishing equipment 1 is demonstrated. First, the automatic activation operation in the automatic activation mode will be described with reference to FIGS. 13 to 15. FIG.

A fire occurs in step S1. At step S2, the zone fire detector senses a fire. In step S3, the area fire display is performed. An alarm sounds in step S4. In step S2a, the AND fire sensor senses a fire. In step S3a, AND fire display is performed. An alarm sounds in step S4a. An AND condition is satisfied in step S5. A delay timer is started in step S6. In step S7, it is determined whether an emergency stop has been made.

At step S8, the alarm stop switch is turned on. At step S9, the switch caution light flashes. The alarm is stopped in step S10. In step S11, the area is automatically selected. In step S12, the fire area is reported. At step S13, the zone selection switch light is turned on. In step S14, the start lamp is flashed.

In step S15, an emergency stop (manual stop) switch is turned on. The delay timer is stopped in step S16. In step S17, the automatic area selection, the automatic release of the operation door, and the flashing of the area selection switch are performed. In step S18, the start lamp is flashed. In step S19, an emergency stop (manual stop) switch is turned on.

A delay timer is typed up in step S20. At step S21, the automatic water discharge valve is opened. In step S22, the pressure in the primary side pipe is reduced. In step S23, the pressure tank is depressurized (the pressure switch is activated). The fire pump is activated in step S24. Water discharge is started in step S25.

At step S26, the automatic water discharge valve water discharge signal (pressure SW signal) is turned ON. In step S27, water discharge is continued to extinguish the fire. At step S28, the starting light is turned on. At step S29, the auxiliary pressurizing pump is operated. In step S30, the pump operation is reported. At step S31, the auxiliary pressurizing pump is stopped. The water discharge lamp is turned on in step S32. In step S33, the water discharge area is transferred. In step S34, the start lamp is turned on. In step S35, the water discharge lamp is turned on.

In step S36, the primary side control valve is closed. In step S37, an emergency stop (manual stop) switch is turned on. At step S38, the automatic water discharge valve is closed. At step S39, the recovery switch is turned on. In step S40, various indicator lamps are restored. In step S41, the sensor is restored and the signal transfer is restored. At step S42, the alarm stop switch is turned off. In step S43, the switch caution light is turned off.

In step S44, the pump stop switch is turned on. Restoration work is performed in step S45. In step S46, an emergency stop (manual stop) switch is turned on. In step S47, various indicator lamps are restored and the operation door is automatically locked. The fire pump is stopped in step S48.

The operation of manual activation by manual operation after the flame detector has been activated or when the fire is confirmed by the discovery of the fire by a person will be described with reference to FIGS. 16 to 18. FIG. Manual startup can be operated in either automatic startup mode or manual startup mode.

In step S51, the detector senses the occurrence of fire. At step S52, the zone detector senses a fire. In step S53, the area fire display is performed. An alarm sounds in step S54. At step S55, the alarm stop switch is turned on. At step S56, the switch indicator flashes. At step S57, the alarm is stopped.

The AND condition is established in step S58. In step S59, the fire zone is transferred. In step S60, the AND fire sensor senses a fire. In step S61, AND fire display is performed. An alarm sounds in step S62.

In step S63, a person discovers the occurrence of fire. In step S64, the communication device issues a cancellation instruction. At step S65, the zone selection switch is turned on. In step S66, the area selection switch light is turned on. At step S67, the release switch is turned on. In step S68, the release lamp is turned on. At step S69, the area selection switch light flashes.

At step S70, the operation door is automatically released. In step S71, the fire is confirmed by a person. At step S72, the zone selection switch is turned on. At step S73, the zone selection switch light is flashed. In step S74, the operation door is unlocked. In step S75, the area selection switch light is turned on.

At step S76, the manual start switch is turned on. At step S77, the manual start switch is turned on. At step S78, the automatic water discharge valve is opened. In step S79, the pressure in the temporary side pipe is reduced. In step S80, the working pressure tank is decompressed (the pressure switch is activated). In step S81, the fire pump is activated. At step 82, water discharge is started.

At step S83, the automatic water discharge valve water discharge signal (pressure SW signal) is turned ON. In step S84, water discharge is continued to extinguish the fire. In step S85, the start lamp is turned on. At step S86, the auxiliary pressurizing pump is operated. In step S87, the operation of the pump is reported. At step S88, the auxiliary pressurizing pump is stopped. At step S89, the water discharge lamp is turned on. In step S90, the water discharge area is transferred. In step S91, the start lamp is turned on. In step S92, the water discharge lamp is turned on.

In step S93, the primary side control valve is closed. In step S94, an emergency stop (manual stop) switch is turned on. At step S95, the automatic water discharge valve is closed. At step S96, the recovery switch is turned on. In step S97, various indicator lamps are restored. In step S98, the sensor is restored and the signal transfer is restored. At step S99, the alarm stop switch is turned off.

In step S100, the switch caution light is turned off. In step S101, an emergency stop (manual stop) switch is turned on. In step S102, various indicator lamps are restored and the electric lock is locked. In step S103, the pump stop switch is turned on. In step S104, recovery work is performed. In step S105, the fire pump is stopped.

In the fire extinguishing equipment 1, the water 7 with a pressure of about 0.1 MPa is supplied to the fire extinguishing nozzle 9 (9a), so that 1 m ² It is configured to release water 7 in an amount of 5 L/min or more.

As a result, the initial cost and running cost of the equipment can be reduced by lowering the pumping height and output of the fire pump 31 that supplies water to the fire extinguishing nozzle 9 (9a) while satisfying the conditions of the Fire Service Act.

To explain further, by using the fire extinguishing nozzle 9 (9a) provided with the spiral fire extinguishing agent discharge part 13 in the fire extinguishing equipment 1, the value of the flow resistance of the water 7 in the fire extinguishing nozzle 9 (9a) is reduced. be able to. Then, the head, which is one of the capabilities of the fire pump 31, which has a high proportion of the total construction cost, is the total head of the pump = the design pressure conversion head of the fire extinguishing nozzle + the friction loss head of the pipe + the head (from the water source tank to the fire extinguishing nozzle )) can be simply reduced by 25m (35m-10m) in terms of pressure equivalent water head. As a result, the output of the motor of the fire pump 31 can also be lowered, the power consumption for operating the fire extinguishing equipment 1 can be lowered, and the fire pump 31 whose capacity is lowered by two ranks can be used. can be achieved and the cost can be reduced.

Further, the fire extinguishing equipment 1 is configured such that the water 7 discharged from the extinguishing agent discharge portion 13 is discharged obliquely upward by the first extinguishing agent guide surface 23 . The third extinguishing agent guide surface 27 is configured such that the water 7 discharged from the extinguishing agent discharging portion 13 is discharged obliquely downward. Also, the water discharged from the extinguishing agent discharge portion 13 by the second extinguishing agent guide surface 25 is positioned between the obliquely upward direction by the first extinguishing agent guide surface 23 and the obliquely downward direction by the third extinguishing agent guide surface 27. is configured to be emitted in the direction of As a result, the water 7 discharged from the extinguishing agent discharging part 13 can be uniformly sprayed over a wide horizontal range over the object to be extinguished.

In addition, the fire extinguishing nozzle 9 (9a) is configured to include a helical tip end portion (discharging portion forming portion) 17. As shown in FIG. The helical tip side portion 17 has a helical diameter that gradually decreases from the proximal end to the distal end. As a result, the fire extinguishing nozzle 9 (9a) has a design (beautiful appearance is generated through visual observation), and can be suitably used in commercial facilities where many people come and go.

Furthermore, by appropriately coloring the spiral tip side portion 17, it looks like a spiral soft serve ice cream piled up in a cone cup, further enhancing the design.

Further, since the fire extinguishing equipment 1 is of an open type, the fire extinguishing nozzle 9 (9a) itself always passes the extinguishing agent 7. As shown in FIG. As a result, when the fire extinguishing agent 7 flows through the fire extinguishing nozzle 9 (9a), the pipe line resistance of the fire extinguishing nozzle 9 (9a) hardly varies, and the extinguishing agent 7 can be discharged in a stable state.

In the fire extinguishing system 1, an automatic activation mode in which the water 7 is automatically discharged and a manual activation mode in which the water 7 is discharged by a human operation can be selected by a predetermined operation of the water discharge sprinkler equipment control panel 61. In automatic mode, water 7 is sprayed upon activation of fire detectors 57 (both zone and AND) that detect the occurrence of fire. In either the automatic activation mode or the manual activation mode, after confirming the occurrence of a fire, the water 7 can be discharged by a predetermined operation on the water discharge type sprinkler equipment control panel or on-site operation panel.

In the fire extinguishing equipment 1, as shown in FIG. 10, a fire sensor 57 for detecting the occurrence of fire is arranged. FIG. 10 is a plan view similar to FIG. 11, and FIG. 10 shows, as an example, a water discharge area of NO. 1 to NO. It is divided into 4 parts.

In the configuration for automatically releasing water 7 when a fire breaks out, as already understood, when both the zone and AND fire detectors 57 detect a fire breakout, the water discharge zone where the fire broke out is selected, Water 7 is discharged from fire extinguishing nozzles 9 (9a) arranged in the selected water discharge area.

1 fire extinguishing equipment 3 extinguishing agent supply unit 5 piping 7 extinguishing agent (water)
8 building 9, 9a fire extinguishing nozzle 10 surface (floor surface)
REFERENCE SIGNS LIST 11 automatic water discharge valve 12 ceiling 13 fire extinguishing agent discharge portion 14 fire extinguishing agent supply port 15 proximal end portion 17 tip end portion 19 first cavity portion 21 second cavity portion 23 first extinguishing agent guide surface 25 second fire extinguishing agent agent guide surface 27 third extinguishing agent guide surface

Claims (7)

a proximal portion fixedly connected to the pipe;
a fire extinguishing agent supply port formed at a portion of a first hollow portion connected to the pipe and supplied with the extinguishing agent;
a fire extinguishing agent discharge unit that is formed in a spiral shape continuously from the fire extinguishing agent supply port and that discharges the fire extinguishing agent supplied to the fire extinguishing agent supply port;
A fire extinguishing nozzle configured with a a base end portion connected to the pipe;
a helical distal portion protruding from the proximal portion;
is configured with
A first hollow portion connected to the pipe is provided at the proximal end portion,
A second hollow portion connected to the first hollow portion is provided in the distal end portion,
The extinguishing agent supply port is formed at a first cavity portion connected to the pipe,
The fire extinguishing agent discharge part is provided at the tip side portion,
The extinguishing agent that has flowed through the pipe, the first cavity, and the second cavity is configured to be discharged from the extinguishing agent discharge part,
The direction from the first cavity to the second cavity is the direction from top to bottom,
The discharge direction of the extinguishing agent discharged from the extinguishing agent discharging part is a direction that intersects the direction from top to bottom,
A first extinguishing agent guide surface, a second extinguishing agent guide surface, and a third extinguishing agent guide surface are provided at the tip side portion,
The first extinguishing agent guide surface is arranged at a portion on the proximal side portion side of the distal portion,
The second extinguishing agent guide surface is arranged at the distal side portion on the side opposite to the proximal side portion with the first extinguishing agent guide surface therebetween,
The third extinguishing agent guide surface is arranged at the tip side portion on the side opposite to the first extinguishing agent guide surface with the second extinguishing agent guide surface therebetween,
The extinguishing agent discharged from the extinguishing agent discharge portion is configured to be discharged in a first direction by the first extinguishing agent guide surface,
The third extinguishing agent guide surface is configured to release the extinguishing agent discharged from the extinguishing agent discharge portion in a second direction,
The second extinguishing agent guide surface directs the extinguishing agent discharged from the extinguishing agent discharge portion in a first direction by the first extinguishing agent guide surface and in a second direction by the third extinguishing agent guide surface. 2. A fire-fighting nozzle according to claim 1, configured to discharge in a third direction between and. The first direction is a diagonally upward direction, the second direction is a diagonally downward direction, and the third direction is a direction between the diagonally upward direction and the diagonally downward direction. The fire extinguishing nozzle according to claim 2. The surface 6 m away from the extinguishing agent discharge part is the floor surface of the building of the commercial facility,
The extinguishing agent discharge unit is provided on the ceiling of the building,
The fire extinguishing nozzle according to any one of claims 1 to 3, wherein the distance between the fire extinguishing agent discharge portion and the floor is 6 m or more from the floor. a fire extinguishing agent supplying unit for supplying a fire extinguishing agent;
the pipe extending from the extinguishing agent supply unit;
The fire extinguishing nozzle according to any one of claims 1 to 4, which is provided in the pipe and discharges the extinguishing agent supplied from the extinguishing agent supply unit and flowing through the pipe;
Fire extinguishing equipment with An automatic water discharge valve is provided in the middle of the pipe, which can be in either an open state for allowing the extinguishing agent to flow into the pipe or a closed state for blocking the flow of the extinguishing agent in the pipe. Fire extinguishing equipment according to 5. The fire extinguishing equipment according to claim 5 or 6, wherein the fire extinguishing nozzle is configured to change the discharge direction of the extinguishing agent in a predetermined pattern.

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