The present invention relates to a sprinkler head for firefighting.
A sprinkler head is installed on a ceiling or a wall. In the event of a fire, the sprinkle is activated to spray water to extinguish the fire. An example of a sprinkler head is one in which a deflector protrudes from the ceiling to the inside of the room when activated and sprays water.
The sprinkler head described above has a deflector suspended by a plurality of posts, which is normally housed in a cylindrical frame. In the event of a fire, a disassembled unit of the deflector is disassembled, and the deflector supported by the disassembled unit falls by a certain distance and, thereafter, stops falling. The water ejected from the sprinkler head hits the deflector so as to be sprayed in all directions.
In the United States, the National Fire Protection Association standards for sprinkler head installation and construction have been established as NFPA 13 to set down the design and installation of sprinkler systems based on the end-use application of a building. As the standards for residential sprinkler systems, NFPA 13D and 13R were provided. In addition, as the standard for residential sprinkler heads, UL 1626 was provided by Underwriters Laboratories (UL LLC).
The sprinkler head described in PTL 1 is one of the above-mentioned residential sprinkler heads, in which the pins for suspending the deflector are disposed outside of the main body of the sprinkler head. As illustrated in
A plurality of slits 5A are formed at the edge of the deflector 5, and the spray pattern is controlled by the shape of the slits 5A (for example, the lengths, widths, and angles). In general, in the directions of the slits 5A, the amount of water sprayed on the floor tends to be greater in an area directly below the sprinkler head and in the short distance area, while in the directions of the convex portions each formed between the two slits 5A and 5A, the amount of water sprayed on the floor tends to be greater in the long distance area away from the sprinkler head.
Residential sprinkler heads are required by UL 1626 to spray water on wall surfaces in addition to spraying water on the floor. One of the requirements for spraying water on walls is that the wall surface must be wetted less than a predetermined distance from the ceiling surface to the floor.
Accordingly, the shapes of the slits and convex portions are designed such that a certain amount of water is directed to the wall surface as well as the floor. However, since there is no obstacle to water sprinkling, such as a pin, in a direction from the center of the deflector to a position obtained by rotating the position of the pin around the center by 90 degrees, water tends to be sprayed too far.
In addition, the activation of a sprinkler head installed around a sprinkler head that is spraying water may be delayed if the heat-sensitive disassembly unit is cooled by the sprayed water. For this reason, the water must be dispersed downwardly below the horizontal to avoid wetting the sprinkler heads installed around. In addition, the above-mentioned wall wetting conditions must be satisfied.
PTL 1: Japanese Unexamined Patent Application Publication No. 2012-80961
In view of the above problem, the present invention provides a sprinkler head capable of moderately wetting a wall surface and obtaining a spray pattern that does not affect the operation performed by a surrounding sprinkler head.
To achieve the above objective, the present invention provides the following sprinkler head. That is, a sprinkler head includes a main body having, thereinside, a nozzle connected to a water supply pipe, a deflector having a disk shape with a plurality of slits in an edge portion, where the deflector is disposed so as to intersect with a central axis of the nozzle, and a support member configured to connect the main body to the deflector. A circular arc shaped first convex portion is formed in a direction from the center of the deflector to a position obtained by rotating the position of the support member by 90 degrees around the center, circular arc shaped first slits are disposed on either side of the convex portion, and the shape of a portion from one of the first slits to the other via the first convex portion is corrugated.
In the above sprinkler head, the water that is discharged from the nozzle and that collides with the deflector and flows onto the first convex portion is dispersed from the edge of the first convex portion in a radial direction in the form of atomized water. In contrast, the water flow dispersed from the first slit becomes a gathered water flow, which moves the surrounding air. Thus, an air flow is generated. The atomized water dispersed from the first convex portion reaches a distant area of the floor surface and a wall away from the sprinkler head under the influence of the airflow.
The first convex portion and a second convex portion adjacent to the first slit are disposed inside the outer diameter of the deflector, so that the water flow discharged from the nozzle passes through the first slit with its momentum intact. Thereafter, the water flow is evenly sprayed to the point immediately below the sprinkler head and the short-distance surrounding area. As a result, the required amount of sprayed water can be provided onto the short distance area and the long distance area of a floor and a wall surface.
As described above, according to the present invention, water dispersed from the first convex portion becomes atomized, and the atomized water can be made to reach a wall surface or a far away point by the airflow generated by the gathered water flow in the first slit. As a result, a sprinkler head can be achieved that prevents the surrounding sprinkler heads from being covered with water and does not affect the operation thereof.
The present invention is described with reference to
As illustrated in
The main body 1 has, in the middle portion thereof, a flat surface 13 extending outwardly. A cylindrical peripheral wall portion 14 is formed from the outer periphery of the flat surface 13 in the water discharge direction of the nozzle 11. The peripheral wall portion 14 has a stepped portion 15 disposed in the inner lower end portion thereof, and the stepped portion 15 has levers 31 and 31 of the heat-sensitive disassembly unit 3 engaged therewith. The stepped portion 15 has missing portions 16 and 16, which are formed facing each other. The levers 31 and 31 are passable through the missing portions 16 and 16 to enter inside of the peripheral wall portion 14.
Two protrusions 17 are formed on the outer periphery of the peripheral wall portion 14 to suspend the deflector 4. The protrusions 17 are formed away from the missing portion 16. In the drawing, the protrusions 17 are located at positions obtained by rotating the positions of the missing portions 16 by 90 degrees. Each of the protrusions 17 has a hole 18 drilled parallel to a central axis 10 of the nozzle 11. The hole 18 is a tapered hole, and the diameter of the hole at the end adjacent to the nozzle 11 is larger than that at the other end.
A support cup 19 having a cylindrical shape is disposed on the periphery of the peripheral wall portion 14, and the main body 1 is disposed inside the support cup 19. The upper end surface of the support cup 19 serves as an engagement surface with the flat surface 13, and the support cup 19 is attached to the main body 1. A cover plate 20 is disposed below the support cup 19, and the deflector 4 is placed on the cover plate 20, as illustrated in
The cover plate 20 is joined to the lower end of a cylindrical retainer 20a by using a low-melting-point alloy. If the low-melting-point alloy is melted by the heat of a fire, the cover plate 20 separates from the retainer 20a and falls off. The upper portion of the retainer 20a is inserted inside the support cup 19. The side surface of the support cup 19 and the side surface of the retainer 20a have a connecting structure that allows the retainer 20a to be engaged with the support cup 19.
The valve body 2 has a disk shape and closes the outlet end of the nozzle 11, as described above. A sealing member 21 is provided on the surface of the valve body 2 adjacent to nozzle 11. According to the present embodiment, a fluoroplastic sheet serving as the sealing member 21 is bonded to the valve body 2. The valve body 2 has a hemispherical protrusion at the center of the surface opposite to the surface having the sealing member 21 disposed thereon. The protrusion is in contact with an end of a compression screw 22, and the valve body 2 is urged in the direction of the nozzle 11 by the compression screw 22.
The compression screw 22 and a saddle 23 are disposed between the valve body 2 and the heat-sensitive disassembly unit 3. The compression screw 22 has a male screw 24 engraved on the outer circumference and is screwed to a female screw 25 formed on the saddle 23. The saddle 23 is made of metal and has a rectangular flat surface. The female screw 25 is disposed at the center of the flat surface. In the drawing, the lower surfaces of both ends of the flat surface of the saddle 23 are in contact with the levers 31 and 31 of the heat-sensitive disassembly unit 3. This provides a structure in which the valve body 2 is in contact with the outlet end of the nozzle 11 by the levers 31 and 31, which are engaged with the stepped portion 15, the saddle 23, and the compression screw 22. In this configuration, when the compression screw 22 is rotated and, thus, the top end of the compression screw 22 is moved in the direction toward the valve body 2, the valve body 2 is urged against the outlet end of the nozzle 11.
At this time, even if the compression screw 22 is rotated, the movement of the saddle 23 toward the nozzle 11 is prevented by the valve body 2. Accordingly, the saddle 23 moves downward in the drawing. However, since both ends of the saddle 23 are engaged with the levers 31 and 31 and, thus, the movement of the saddle 23 downward is prevented, the flat surface of the saddle 23 is bent into an arch and is elastically deformed, so that the substantial middle portion having the female screw 25 disposed therein is curved downward. As a result, a force caused by the elasticity of the saddle 23 is also exerted on the levers 31 and 31 which are in contact with both ends of the saddle 23.
The heat-sensitive disassembly unit 3 is engaged with the above-described stepped portion 15 and supports the valve body 2 in normal times. In the case of a fire, the heat-sensitive disassembly unit 3 is disassembled due to the heat of fire and operates to release the valve body 2. As illustrated in
The heat-sensitive disassembly unit 3 is configured as a unit part illustrated in
The deflector 4 has a disk shape and intersects perpendicularly with the central axis 10 of the nozzle 11. In
In
In
In the above configuration, the first convex portion 44 and the second convex portions 46 are formed shorter than the nearby convex portions, and the shape from one of the first slit 45 to the other is corrugated. Water discharged from the nozzle 11 collides with the button 43 and flows towards the outer periphery of the deflector 4, and part of the water flowing in the direction from the corrugated first convex portion 44 to the second convex portion 46 passes through the first slit 55 and is evenly distributed to the point immediately below the sprinkler head S and its short-distance surrounding area. At this time, a gathered water flow is generated in the direction of each of the first slits 45 and 45 (in the direction of arrow B).
In contrast, the water flow dispersed from the first convex portion 44 is dispersed in the radial direction from the edge of the first convex portion 44, as indicated by the arrows illustrated around the first convex portion 44 in
As illustrated in
The length b of the second convex portion 46 is shorter than the length of the neighboring convex portion 4a. A dimension c, which is the length obtained by subtracting the length of the convex portion 4a from the length b of the second convex portion 46, is set to be substantially the same as or slightly greater than the length of the second convex portion 46. By adjusting the length b of the second convex portion 46, the water flow from the center of the deflector 4 toward the second convex portion 46 (in the direction of arrow C) can be controlled. More specifically, if the length b of the second convex portion 46 is reduced, the water flow dispersed in the direction of arrow C tends to be attracted toward the water flow indicated by arrow B, and the amount of water sprayed in the direction of arrow C is reduced.
Third convex portions 48 are disposed on the straight line L1. Each of the third convex portions 48 has the pin 41 disposed thereon. The pin 41 is disposed outside the outer circumference circle C1 of the deflector 4. In addition, the top end of the third convex portion 48 extends outside the outer circumference circle C1 of the deflector 4. Fourth convex portions 49 are disposed along the straight line L1 on either side of the third convex portion 48, and the top end of the fourth convex portion 49 and the top end of the third convex portion 48 are on a straight line L2 that intersects perpendicularly with the straight line L1.
The top end of the third convex portion 48 is bent in a direction farther away from the nozzle 11 than the flat surface of the fourth convex portion 49 and, thus, a step 50 is formed. A hole is drilled in the step 50 so as to enable the lower end of the pins 41 to be inserted thereinto. After the pin 41 is inserted into the hole, the pin 41 is fixed to the step 50. The third convex portion 48 has a slope face 51 thereon in the vicinity of the step 50, and the slope face 51 is located outside the outer circumference circle C1 of the deflector 4.
A third slit 52 is formed between the third convex portion 48 and the fourth convex portion 49 so as to be slightly inclined with respect to the straight line L1. For this reason, the width of the third convex portion 48 decreases towards the top end.
The circular-arc ends of a fourth slit 53 adjacent to the fourth convex portion 49, the first slit 45, and the second slit 47 are in contact with a circle C2 which is concentric with the outer circumference circle C1 of the deflector 4. The circle C2 has a smaller diameter than the outer circumference circle C1 of the deflector 4.
In terms of the flying distance of water in the direction of the straight line L1 in which the pins 41 are disposed, the pins 41 obstruct the flow of water. Therefore, the top ends of the third convex portion 48 and the fourth convex portion 49 are located outside the outer circumference circle C1 of the deflector 4 to increase the takeoff distance of the water flowing from the button 43 in the direction of the pin 43.
The water that reaches the third slit 52 passes through the third slit and flows downward. In contrast, the water that flows on the surface of the third convex portion 48 maintains the momentum of the water flow until it reaches the slope face 51. Consequently, a flow rate that is sufficient to wet the wall surface on the extension in the L1 direction can be provided.
The configuration of the sprinkler head S according to the present invention is not limited to the above-described configuration. For example, a glass valve or a link can be used as the heat-sensitive disassembly unit 3. In addition, the support member that connects the main body to the deflector can be configured as a frame arm extending from the main body in the water discharge direction of the nozzle, and the deflector according to the present invention may be mounted on the top end of the frame arm.
Number | Date | Country | Kind |
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2018-128127 | Jul 2018 | JP | national |
Filing Document | Filing Date | Country | Kind |
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PCT/JP2019/016949 | 4/22/2019 | WO | 00 |