阅读说明：本技术 喷洒头 (Sprinkler head ) 是由 小岩康明 于 2018-11-07 设计创作，主要内容包括：本发明提供一种喷洒头,能够防止喷洒头动作时的堆积,并且能够容易进行组装。喷洒头(S1)具有：主体(1),在内部具有与供水配管连接的喷嘴(12)；阀(3),在平时堵塞喷嘴(12)；一对框架(14),从主体(1)向喷嘴(12)的喷水方向延伸；导流板(2),设置于框架(14)的顶端；以及热敏分解部(4),设置在阀(3)和导流板(2)之间。弯曲成W字状的弹簧(5)的两端与一对框架(14)卡合,在弹簧(5)的两端(51、52)之间的弯曲部(53)的内侧容纳有热敏分解部(4)。(The invention provides a sprinkler head, which can prevent accumulation when the sprinkler head is operated and can be easily assembled. The sprinkler (S1) has: a main body (1) having a nozzle (12) connected to a water supply pipe therein; a valve (3) that normally closes the nozzle (12); a pair of frames (14) extending from the main body (1) in the water spraying direction of the nozzle (12); the guide plate (2) is arranged at the top end of the frame (14); and a thermosensitive decomposition part (4) arranged between the valve (3) and the guide plate (2). Both ends of a spring (5) bent in a W shape are engaged with a pair of frames (14), and a thermosensitive disassembly part (4) is accommodated inside a bent part (53) between both ends (51, 52) of the spring (5).)

1. A sprinkler head, characterized in that,

comprising:

a main body having a nozzle connected to a water supply pipe therein;

a valve that normally blocks the nozzle;

a pair of frames extending from the main body in a water spraying direction of the nozzle;

a guide plate disposed at a top end of the frame coupled to a central axis of the nozzle; and the number of the first and second groups,

a thermosensitive decomposing part disposed between the valve and the baffle,

both ends of the spring bent in a W shape are engaged with the pair of frames, and the thermosensitive disassembly portion is accommodated inside the bent portion between the both ends.

2. The sprinkler head according to claim 1, wherein,

the thermosensitive decomposing part uses a connecting rod which connects a plurality of thin plates through a low-melting-point alloy, and further comprises a support and a rod which are engaged with the connecting rod.

3. The sprinkler head according to claim 1 or 2, wherein,

a stay is accommodated inside the bent portion of the spring.

4. The sprinkler head according to claim 1, wherein,

a glass valve is used as the thermosensitive decomposition portion.

5. The sprinkler head according to any one of claims 1 to 4, wherein,

the valve is cylindrical with a bottom, the bottom surface side of the valve is accommodated in the nozzle, one end of the thermosensitive disassembly portion is engaged with the opening side of the valve, and the opening side of the valve is accommodated inside the bent portion of the spring.

6. The sprinkler head according to any one of claims 1 to 5, wherein,

the frame is provided with a groove engaged with the spring.

7. The sprinkler head according to any one of claims 1 to 6, wherein,

the post is provided with a groove for engaging with the spring.

Technical Field

The present invention relates to a sprinkler head for fire extinguishing.

Background

The sprinkler is installed in a building, senses heat of a fire and automatically operates to sprinkle water to extinguish the fire. The sprinkler head has a nozzle inside, the nozzle is connected to a pipe connected to a water supply source, and the nozzle is normally closed. When the sprinkler head is operated by heat in the event of a fire, the nozzle is opened to discharge water filled in the pipe from the nozzle. The sprinkler head has a guide plate for scattering water around on an extension line of an outlet of the nozzle, and the water colliding with the guide plate is dispersed in a predetermined range to suppress and extinguish a fire.

As an example of the structure of the sprinkler head, a frame type sprinkler head is provided. The frame type sprinkler head is provided with a horseshoe-shaped frame along a water spraying direction of a main body having a nozzle therein, and a guide plate which collides with water discharged from the nozzle to scatter the water around is provided at a tip of the frame.

A valve for normally closing the nozzle is provided between the nozzle and the deflector, and the valve is supported by the heat sensitive operating part. As is well known, a glass valve or a low melting point alloy is used for the heat sensitive operating portion. When the heat-sensitive operating portion is operated by the heat of a fire, a structure or a valve of the heat-sensitive operating portion is occasionally accumulated in the baffle by the water flow of the nozzle (deposition).

In order to prevent the accumulation, there is a sprinkler head provided with a spring for biasing the valve to a side deviated from the water flow direction. (see, for example, patent document 1).

Disclosure of Invention

Problems to be solved by the invention

The sprinkler head with the spring is configured such that both ends of the V-shaped spring are engaged with the frame, and the bent portion of the middle of the spring is engaged with the side surface of the valve. When the heat sensitive operation part is operated to open the valve, the valve is deviated from the water spraying direction of the nozzle by the action of the spring and is discharged to the outside.

In the case of installing the spring in the sprinkler head, both ends of the spring are caught and the both ends are closely displaced and the valve is engaged with the middle portion of the spring and installed in the body at a stage before the heat sensitive decomposition part is assembled to the body. However, since the spring biases the valve in a direction away from the axis of the nozzle, the operation of assembling the heat-sensitive decomposition portion to the valve is difficult.

Alternatively, in the case where the spring is provided after the valve and the thermosensitive disassembly portion are assembled to the main body, a delicate operation of passing the end portion of the spring between the valve and the frame is required. In this case, the heat-sensitive decomposition portion must be carefully manipulated so as not to be impacted.

Accordingly, the present invention has been made in view of the above problems, and it is an object of the present invention to provide a sprinkler head which can prevent deposition during operation of the sprinkler head and can be easily assembled.

Means for solving the problems

To achieve the above objects, the present invention provides the following sprinkler head.

That is, the sprinkler head of the present invention includes:

a main body having a nozzle connected to a water supply pipe therein;

a valve that normally blocks the nozzle;

a pair of frames extending from the main body in a water spraying direction of the nozzle;

a guide plate disposed at a top end of the frame coupled to a central axis of the nozzle; and the number of the first and second groups,

a thermosensitive decomposing part disposed between the valve and the baffle,

both ends of the spring bent in a W shape are engaged with the pair of frames, and the thermosensitive disassembly portion is accommodated inside the bent portion between the both ends.

When the nozzle is opened, the spring and the heat-sensitive separating portion accommodated in the bent portion of the spring are displaced from the axis of the nozzle and move in the direction of the biasing force of the spring. This prevents the heat-sensitive decomposition portion from being retained in the baffle by the water flow discharged from the nozzle.

As an example of the thermosensitive disassembly portion, when a link formed by joining a plurality of thin plates with a low-melting-point alloy is used, the thermosensitive disassembly portion may further include a post and a rod that engage with the link. When the support, which is a structural member of the thermosensitive disassembly portion, is accommodated in the bending portion of the spring, if both ends of the spring are biased in a direction in which they approach each other and the both ends of the spring are displaced, the interval of the opening portion of the bending portion is enlarged, and the support can be accommodated inside the bending portion. When the force applied to both ends of the spring is released, the spring returns to its original shape, and the interval between the openings of the bending portion is reduced, thereby holding the strut inside the bending portion.

When the spring is provided in the sprinkler head, the bent portion of the W-shaped spring is brought close to the support from a direction perpendicular to the center axis of the nozzle after the valve and the heat sensitive decomposition portion are assembled to the body. Then, both ends of the spring are in contact with the pair of frames. When the spring is brought close to the support in this state, both ends of the spring interfere with the pair of frames, and both ends of the spring are displaced in a direction in which they approach each other. The displacement expands the interval between the openings of the bending portion, and therefore the strut is accommodated inside the bending portion. When the spring is released at this point, both ends of the spring engage with the pair of frames in a state where the stay is accommodated inside the bent portion.

Further, a glass valve can be used as the thermosensitive decomposition portion. As an example of the structure in this case, a bottomed cylindrical valve is used. The bottom surface side of the valve can be accommodated in the nozzle, one end of the thermosensitive disassembly portion can be engaged with the opening side, and the opening side of the valve can be accommodated inside the bent portion of the spring.

Effects of the invention

As described above, according to the present invention, the sprinkler head can be easily assembled while preventing the deposition of the sprinkler head during the operation.

Drawings

Fig. 1 is a front view of the sprinkler head of the present invention.

Fig. 2 is a sectional view II-II of fig. 1.

Fig. 3 is an enlarged sectional view of the thermosensitive disassembled part of fig. 2.

Fig. 4 is a sectional view IV-IV of fig. 1.

Fig. 5 is a front view of the spring.

Fig. 6 is a sectional view taken along line VI-VI of fig. 1, where (a) is a state before the spring is set and (b) is a state after the spring is set.

Fig. 7 is a front view of a sprinkler head having a modified example of a spring.

Fig. 8 is a front view of the sprinkler head before the spring is installed in the modified example having the groove for locking the spring to the frame and the stay.

Fig. 9 is a cross-sectional view IX-IX before the spring of fig. 8 is disposed.

Detailed Description

The sprinkler head S1 of the present invention shown in fig. 1 and 2 is composed of a main body 1, a baffle 2, a valve 3, a heat sensitive decomposition part 4 and a spring 5.

The main body 1 is hollow, and has an external screw 11 for connection to a pipe disposed near the ceiling of a building and an internal nozzle 12. Regarding the size of the nozzle 12, the value of the K factor derived from the flow rate of the nozzle 12 and the water spray pressure is in the range of 3 to 5.8, and in the present embodiment, the value of the K factor is 5.6. The male screw 11 connected to the pipe has a size of NPT1/2 or R1/2.

A substantially rectangular base 13 is provided near the outlet of the nozzle 12, and a pair of frames 14 extending from the base 13 in the water spraying direction of the nozzle 12 are provided. The frame 14 includes a linear portion 14A extending substantially parallel to the central axis a of the nozzle, and an intersecting portion 14B connected from an end of the linear portion 14A to a boss 15 provided on the central axis a of the nozzle 12. As shown in fig. 3, the cross portion 14B is thinner than the linear portion 14A and has an elliptical cross-sectional shape.

The boss 15 is in a tapered cylindrical shape, the guide plate 2 is arranged at the top end of the boss, and the diameter D1 of the boss 15 on the side connected with the guide plate is 9-10 mm. The outer peripheral diameter of the nozzle 12 side end of the boss 15 is smaller than the diameter D1 of the baffle 2 side. The outer peripheral end 15A of the boss 15 on the nozzle 12 side has a curved surface shape, and the radius of the curved surface is in the range of 1mm to 3mm, 2mm in the present embodiment.

The boss 15 is internally provided with a female screw 15B into which a compression screw (インプレスネジ)16 is screwed, the tip 16A of the compression screw 16 is pointed and has a slope 16B, the tip 16A faces the nozzle 12, the angle α of the slope 16B is in the range of 80 DEG to 100 DEG, in the present embodiment 90 DEG, the apex of the tip 16A is spherical, preferably, the spherical radius is 2mm or less, in the present embodiment 1mm or less.

The pressure screw 16 has a function of pressing the valve 3 toward the nozzle 12 via the thermosensitive disassembly portion 4. In fig. 3, the extension 16C of the inclined surface 16B along the tip 16A of the compression screw 16 is close to or in contact with the curved surface of the outer peripheral end 15A of the boss 15, and when water flowing along the surface of the tip 16A passes through the outer peripheral end 15A, the water flow is not obstructed, thereby preventing the generation of turbulence. At this time, the distance a between the inclined surface 16B of the compression screw 16 and the end surface of the boss 15 on the nozzle 12 side is 2mm or less, and more preferably 1mm or less. If the interval is larger than the above range, the possibility of generating turbulence becomes high.

The baffle 2 shown in fig. 1 has a disk shape, and a plurality of claws 21 are provided on the periphery thereof.

The valve 3 normally blocks the outlet of the nozzle 12. The valve 3 is composed of a valve cover 31, a disk 32, and a belleville spring 33. The valve cover 31 has a bottomed cylindrical shape, and one end side thereof is a spherical bottom portion 31A. The other end side is expanded in diameter and provided with a step 31B.

A disk-shaped disk 32 is mounted on the inner peripheral side of the step 31B. The disc 32 has a recess 32A at the center, and one end of the support 42 of the thermosensitive decomposition unit 4 engages with the recess 32A.

A belleville spring 33 is locked to the outer peripheral side of the step 31B. The belleville spring 33 is inserted through the bottom 31A of the bonnet 31. The surface of the disc spring 33 is covered with a fluorine resin. The outer peripheral edge of the belleville spring 33 is disposed at the outlet end of the nozzle 12, and when the pressing screw 16 is screwed into the female screw 15B of the boss 15, the belleville spring 33 is pressed and elastically deformed by the heat sensitive decomposition portion 4, and becomes a squashed shape. At this time, the fluororesin functions as a sealing material to seal the nozzle 12.

The thermosensitive disassembly section 4 is composed of a link 41, a stay 42, and a lever 43. The tie rod 41 is a heat-sensitive body that operates by the heat of a fire, and is configured by joining two thin metal plates 44 with a low-melting-point alloy. The low-melting point alloy has a melting point of 60 to 200 ℃, and a low-melting point alloy having a melting point of 72 ℃ or 96 ℃ is generally used.

The two substantially rectangular metal plates 44 have a hole 45 at one end and an -shaped cutout 46 at the other end, and the two metal plates 44 are joined together by a low melting point alloy, and at this time, the cutout 46 of the other metal plate 44 is overlapped at the position of the hole 45 of one metal plate 44, and the support 42 and the lever 43 are inserted into the two holes 45 of the joined link 41, respectively (see fig. 4).

The support column 42 is elongated, and has one end engaged with the disk 32 of the valve 3 provided at the outlet of the nozzle 12 and the other end engaged with the tip end of the rod 43. As described above, the stay 42 is inserted through the hole 45 of the link 41. A projection 47 is provided in the middle of the strut 42, and the link 41 is locked to a groove 47A provided in the vicinity of the projection 47.

The lever 43 is formed by bending an elongated plate into a substantially L-shaped configuration, and as described above, one end side of the lever 43 is inserted through the hole 45 of the link 41, the other end side of the lever 43 is engaged with the support column 42, and the lever 43 is provided with the groove 48 engaged with the tip end of the support column 42.

A recess 49 is provided on the surface on the rear side of the surface provided with the groove 48. The recess 49 is provided at a position closer to the other end of the lever 43 than the groove 48. The compression screw 16 is in contact with the recess 49. When the tip end of the compression screw 16 presses the recess 49 of the lever 43, a force that rotates about the groove 48 of the locking stay 42 acts on the lever 43. However, one end side of the lever 43 is inserted through the hole 45 of the link 41, thereby preventing the rotation of the lever 43. Thereby, the link 41, the stay 42, and the lever 43 constituting the thermosensitive disassembly portion 4 maintain the engaged state. The pressure screw 16 presses and holds the valve 3 toward the nozzle 12 via the thermosensitive disassembly portion 4.

The spring 5 shown in fig. 5 is formed by forming a spring wire into a substantially W shape. As shown in fig. 6(b), both end portions 51, 52 of the spring 5 are locked to the frames 14, 14. The bent portion 53 between the both end portions 51, 52 of the spring 5 is formed by being curved in an arc shape, and the bent portion 53 has a C-shape. The stay 42 is accommodated inside the bent portion 53.

In the state before the spring 5 shown in fig. 6(a) is locked to the frame 14, the interval L1 of the opening 54 of the bent portion 53 is narrower than the width L2 of the stay 42, and the stay 42 cannot be accommodated inside the bent portion 53, when the spring 5 is locked to the frame 14, the spring 5 is elastically deformed by applying a force in a direction in which the end portions 51 and 52 approach each other, and the interval L1 of the opening 54 is increased, and at this time, when the force applied to the end portions 51 and 52 is released in a state in which the stay 42 is accommodated inside the bent portion 53, the stay 42 is held inside the bent portion 53, and the end portions 51 and 52 are locked to the frame 14 and 14 (see fig. 6 (b)).

In fig. 4, the ends 51, 52 of the spring 5 engage with the outer periphery of the frame 14 on the rod 43 side with respect to the central axis a of the nozzle and the line B passing through the frames 14, 14. The stay 42 housed inside the curved portion 53 is biased toward the rod 43 by the action of the spring 5, and when the sprinkler head S1 is operated, the spring 5 and the stay 42 move in the direction of the rod 43.

The sequence of assembling the spring 5 to the sprinkler head S1 will be explained.

First, the valve 3 and the thermosensitive disassembly portion 4 are assembled to the body 1 of the sprinkler head S1. Thereafter, the spring 5 is locked to the frame 14, and the stay 42 is accommodated inside the bent portion 53. The spring 5 is passed between the link 41 and the valve 3, and the spring 5 is moved in the direction indicated by the arrow C in fig. 6a (the direction perpendicular to the central axis a of the nozzle) so that the opening 54 of the spring 5 faces the support 42. Then, the end portions 51, 52 of the spring 5 interfere with the frame 14, and the end portions 51, 52 elastically deform so as to approach each other, and the opening 54 of the bent portion 53 expands.

When the spring 5 is further moved in the arrow C direction, the support 42 is accommodated in the curved portion 53 through the opening 54. When the spring 5 is released in this state, both end portions 51 and 52 of the spring 5 are locked to the frame 14, and the stay is held inside the bent portion 53, whereby the assembly of the spring 5 to the sprinkler head S1 is completed.

Next, the operation of the sprinkler head S1 in the case of a fire will be described.

The sprinkler head S1 has a baffle 2 facing upward, and the nozzle 12 is connected to a pipe not shown by the male screw 11 at ordinary times. The nozzle 12 is filled with pressurized water, but the nozzle 12 is closed by the valve 3 and the thermosensitive decomposition portion 4.

When the low melting point alloy of the link 41 melts in the event of a fire, the lever 43 rotates, and the metal plate 44 engaged with the lever 43 is separated from the metal plate 44 engaged with the strut 42. Thereby, the engagement state of the thermosensitive disassembly section 4 is released, the engagement of the link 41, the support 42, and the lever 43 is disengaged, and the valve 3 supported by the support 42 is separated from the nozzle 12 and is detached, so that the nozzle 12 is opened.

At this time, the spring 5 is locked to the frames 14 and 14, and the spring 5 is biased in the direction indicated by the arrow D in fig. 2, so that the spring 5 is displaced in the direction of the arrow D from the direction of the water flow discharged from the nozzle 12 while holding the stay 42 inside the curved portion 53, and is discharged to the outside of the sprinkler head S1.

The embodiments of the present invention have been described above, and the other configurations and operations will be described below.

In the above-described embodiment, the shape of the portion of the rod 43 that engages with the compression screw 16 is the concave portion 49, but the present invention is not limited thereto, and may be formed in a convex shape. At this time, the shape of the tip of the compression screw 16 can be changed to a recess or groove corresponding to the projection shape.

As a modification of the spring 5, as shown in the sprinkler head S2 shown in fig. 7, the valve cover 31 may be accommodated inside the curved portion 53 of the spring 5. More specifically, the bent portion 53 is engaged with the outer peripheral portion of the bonnet 31 disposed between the flange portion 31C formed on the edge on the other end side of the bonnet 31 and the base 13. With such a configuration, the spring 5 can be applied to a sprinkler head using a glass valve as a thermosensitive decomposition portion.

In the embodiment shown in fig. 1 to 7, the upward type sprinkler in which the deflector 2 is upwardly disposed is explained, but the spring 5 can be applied to a downward type sprinkler and a side wall type sprinkler.

In fig. 4 and 6, the spring 5 is attached from the direction in which the rod 43 is disposed toward the support 42, but may be provided from the opposite direction. The spring 5 is a member for preventing the structural member of the thermal decomposition portion 4 from being retained in the baffle 2 by the water flow from the nozzle 12 during the sprinkler operation, and therefore, the installation position of the spring 5 can be appropriately selected according to the shape of the baffle 2.

For example, in the case of a side wall type sprinkler head, an auxiliary baffle may be provided in the vicinity of a baffle arranged on an extension line of the nozzle, but the spring 5 may be configured to be biased in a direction away from the auxiliary baffle.

In the modification shown in fig. 8 and 9, the frame 14 is provided with a groove 14C for engaging with the spring 5. The groove 14C is provided on the face of the pair of frames 14, 14 opposed to each other. The same groove 42A is also provided in the support column 42. With this configuration, the positional deviation of the spring 5 in the vertical direction can be suppressed, and the spring 5 can be stably arranged at a predetermined position.

Description of the reference numerals:

s1 sprinkler head

1 main body

2 flow guiding plate

3 valve

4 thermosensitive decomposing part

5 spring

12 nozzle

13 base

14 frame

15 boss

16 compression screw

21 claw

31 valve cover

32 disc

33 belleville spring

41 connecting rod

42 support

43 rod

51. 52 end of spring

53 bending part

54 opening part