JP2011152322A - Sprinkler head - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a sprinkler head for reducing a moving distance of a stopper ring, so as to enhance reliability in falling operation. <P>SOLUTION: The sprinkler head 1 comprises a head body 10 and a frame 20 connected to the head body, while a sprinkling part 40 comprising a deflector 41, a guide rod 42, and the stopper ring 43 is provided in the frame. The stopper ring arranged on the deflector is mounted to be movable relative to the guide rod by providing an insertion hole to insert the guide rod in the stopper ring and by providing a step part for the stopper larger than the insertion hole at an upper end of the guide rod. <P>COPYRIGHT: (C)2011,JPO&amp;INPIT

Description

  The present invention relates to a sprinkler head.

  In a conventional flash-type sprinkler head, a water sprinkling part is constituted by a deflector, a guide rod, and a stopper ring. Normally, the stopper ring is fixed to the upper end of the guide rod, and the deflector is fixed to the lower end of the guide rod, so that the watering part is integrated. In addition, as another watering part, there is a thing which does not fix a deflector but slides the deflector itself from the upper end to the lower end of the guide rod at the time of water discharge.

  The stopper ring is provided at the upper end portion of the frame constituting the sprinkler head, and is configured to drop to a locking step portion provided at the lower end of the inner periphery of the frame during the water discharge operation. That is, at the time of water discharge operation, the stopper ring is locked to the locking step portion of the frame, and the deflector is supported via the guide rod to discharge water (see, for example, Patent Document 1).

Japanese Patent Laid-Open No. 10-179789 (Claims, FIG. 1)

  In sprinkler heads, the sprinkler moves during the water discharge operation, but the smaller the amount of movement, the more stable the operation will be. The amount of movement during operation was large.

In order to ensure the sliding movement of the stopper ring, there is one in which a coil spring is installed on the upper part of the stopper ring. However, in this case, there is a problem that the height of the sprinkler head becomes large.
In addition, there is a guide member that more reliably slides and lowers the water spray part, but there is a problem that the guide member may cause a water spray failure during water discharge.

  The present invention has been made to solve the above-described problems, and it is an object of the present invention to provide a sprinkler head that is highly reliable in a descent operation by a stopper ring of a sprinkler.

  A sprinkler head according to the present invention includes a frame having a locking step formed inside, a head main body connected to an upper portion of the frame and having a water discharge tube inside, and a watering portion provided in the frame. The sprinkler head includes a stopper ring, a guide rod, and a deflector provided below the water discharge tube. The sprinkler head includes an insertion hole through which the guide rod is inserted, and the guide rod. A stopper step larger than the insertion hole is provided at the upper end of the stopper, and the stopper ring installed on the deflector slides on the guide rod and moves to the locking step during water discharge operation. It is characterized by doing.

Since the sprinkler head according to the present invention has an insertion hole through which the guide rod is inserted into the stopper ring, at the time of water discharge operation, the deflector including the valve body first descends together with the guide rod, and subsequently, the stopper ring It is lowered by the coil spring.
In a normal state, the deflector is provided below the water discharge cylinder of the head body, and a stopper ring is provided on the deflector. For this reason, during the water discharge operation, the stopper ring moves only from the vicinity of the lower end of the water discharge tube to the locking step at the lower end of the frame. Therefore, since the amount of movement of the stopper ring itself is reduced, this stabilizes the operation during operation.

Further, since the guide member bent upward is provided on the inner peripheral side of the stopper ring, the guide ring is guided and lowered by the guide member, so that the operation is stabilized. In particular, since the guide member is bent upward, it is possible to prevent water from being obstructed during water discharge.
In addition, the coil spring that presses down the stopper ring is installed between the outer periphery of the stopper ring and the lower part of the outer periphery of the head body. Therefore, the coil spring can be provided in the sprinkler head using the dead space. Easy to miniaturize the head.

  The deflector is fixed to the lower end of the guide rod, and in a normal state, the guide rod is accommodated in a space formed between the inner peripheral portion of the head body and the water discharge tube. In other words, the stopper ring is not installed in the space as in the conventional example, but only a thin guide rod is installed, so that the space between the inner periphery of the head body and the water canister can be reduced. Become.

It is a longitudinal cross-sectional view of the sprinkler head which concerns on Embodiment 1 of this invention. It is sectional drawing which shows the operation state of a sprinkler head. It is sectional drawing which showed the detail of the plunger of FIG. It is sectional drawing which showed the modification (the 1) of a plunger. It is sectional drawing which showed the modification (the 2) of a plunger. It is sectional drawing which showed the modification (the 3) of a plunger. It is sectional drawing which showed the modification (the 1) of a slider. It is sectional drawing which showed the modification (the 2) of a slider. It is a top view of a disc spring, a front view, a side view, a perspective view, and an EE sectional view. It is a perspective view of a stopper ring.

FIG. 1 is a longitudinal sectional view of a sprinkler head according to Embodiment 1 of the present invention.
The sprinkler head 1 includes a head body 10, a frame 20, a valve body 30, a water sprinkling unit 40, and a valve body support mechanism 50 (ball holding mechanism 60).

The head body 10 has an opening at the center. The opening 11 forms a water discharge port 12 together with a water discharge tube 16 described later. A flange 13 is formed on the outer peripheral portion of the head main body 10, and a screw portion 14 connected to the water supply pipe is formed on the outer peripheral portion of the head main body 10 on the upper side of the flange 13. A screw portion 15 for attaching a frame 20 to be described later is formed on the outer peripheral portion on the side.
A cylindrical water discharge cylinder 16 is formed on the inner side of the head body 10 so as to protrude downward. Further, for example, a flat valve seat 17 is formed at the lower end of the water discharge cylinder 16 and is closed by the valve body 30. You may make it provide the step part which the outer periphery of the valve body 30 fits in the lower end part of this water discharge pipe | tube 16. As shown in FIG. In the head body 10, a substantially hole-shaped or ring-shaped space 18 is formed between the lower inner peripheral portion of the flange 13 and the water discharge cylinder 16, and a guide rod 42 described later is formed in the space 18. Is stored.

  The frame 20 is formed in a cylindrical shape. A screw portion 21 is formed on the inner peripheral portion of the upper portion of the frame 20 and is attached to the screw portion 15 formed on the lower side of the head body 10. A locking step portion 22 protruding inward is provided at the lower portion of the frame 20, and a ball 61 described later is locked to the locking step portion 22.

  The valve body 30 is formed in a convex shape, and has a flange portion 31 at the lower portion. The flange portion 31 closes the valve seat 17 of the head body 10. The valve seat 17 is provided with a Teflon (registered trademark) sheet or a Teflon (registered trademark) coating. A recess 32 is formed in the lower center of the valve body 30 and a head of a set screw 65 described later is inserted. The valve body 30 is supported by a valve body support mechanism 50 described later.

  The water sprinkling unit 40 includes a deflector 41, a guide rod 42, and a stopper ring 43 (and the valve body 30), and is provided in the frame. In addition, since the deflector 41 may be provided below the frame 20, a part of the water sprinkling unit 40 is provided at least in the frame 20.

The deflector 41 is configured by a disc having an opening at the center, and is attached (fixed) to the lower surface of the flange portion 31 of the valve body 30 with the lower portion of the valve body 30 inserted into the opening. ing). The deflector 41 is provided with insertion holes 41a (for example, three) into which guide rods 42 (for example, three) are inserted, and the lower end of the guide rod 42 protrudes from the insertion hole 41a. 41 is fixed. Therefore, the valve body 30, the deflector 41, and the guide rod 42 are integrally formed.
In addition, the attachment state of the deflector 41 to the valve body 30 will be described in detail. The valve body 30 is in contact with the valve seat 17 and has a flange portion 31 for maintaining water stop, and a cylindrical leg portion protruding below the flange portion 31. The upper part is a groove part slightly smaller in diameter than the central opening (hole) of the deflector 41, and the lower side of the groove part is a cylindrical shape slightly larger in diameter than the hole diameter of the central opening part of the deflector 41. For this reason, the deflector 41 is in a rotatable state at a connection location (groove portion) to the valve body 30.

A stepped portion 42a having an enlarged diameter for a stopper is formed at the upper end of the guide rod 42, and a stopper ring 43 formed in a donut shape is attached to the guide rod 42 so as to be movable up and down (see FIG. 10). ).
The stopper ring 43 is provided with insertion holes (for example, three) through which the guide rod 42 is inserted. By the insertion holes, the stopper ring 43 slides on the guide rod 42 during the water discharge operation. The guide rod 42 is attached so as to be movable to the stop portion 22. In other words, the guide rod 43 is attached to the stopper ring 43 so as to be movable downward along the insertion hole of the stopper ring 43 during the water discharge operation. In addition, this insertion hole is formed smaller than the step part 42a. The stopper ring 43 is normally installed on the deflector 41 and is provided at a position that is substantially in the middle of the frame 20 in the height direction and that faces a slit provided in the frame 20. The slit does not necessarily have to be provided at a position facing the stopper ring 43.
Under normal conditions, the lower surface of the stopper ring 43 is pressed by the coil spring 44 and substantially overlaps the upper surface of the deflector 41. However, during the water discharge operation, the deflector 41 and the guide rod 42 are lowered, and the upper end of the guide rod 42 is lowered. The stepped portion 42a descends until it hits the stopper ring 43 (see FIG. 2C). The outer diameter of the stopper ring 43 is formed to be larger than the inner diameter of the locking step portion 22 of the frame 20, and when the valve body support mechanism 50 is dropped during the water discharge operation, the stopper ring 43 is pushed by the coil spring 44. The locking step 22 is lowered.
The coil spring 44 has a size (outer diameter) so as to contact the inner peripheral surface of the frame 20, and is provided between the lower part of the outer peripheral part of the head body 10 and the outer peripheral part of the stopper ring 43. Thus, a large space is not required for installation of the coil spring 44.

  The inner diameter of the hole provided in the center of the stopper ring 43 is slightly larger than the outer diameter of the water discharge cylinder 16. The stopper ring 43 is provided with guide members 43a having an L-shaped cross section at, for example, three locations on the inner peripheral side by bending a part of the inner periphery upward through a notch groove. When the stopper ring 43 is lowered, the stopper ring 43 is guided by the guide member 43a to the outer periphery of the water discharge cylinder 16 formed in the lower portion of the head body 10. The number and pitch of the guide members 43 are set as appropriate so that the stopper ring 43 can be lowered in a balanced manner.

  The valve body support mechanism 50 includes a heat sensitive part 51, a ball holding mechanism 60, a disc spring 64, and a set screw 65.

The heat sensitive unit 51 includes a plunger 52, a heat sensitive plate 53, and a heat insulating material 54.
The plunger 52 is formed in a cylindrical shape, and a flange portion 52a is formed in the lower portion. Further, the lower surface of the flange portion 52 a is formed so as to protrude from the lower surface of the heat sensitive plate 53. Inside the plunger 52, a female screw 52b is formed, and a male screw on a leg portion of the set screw 65 is screwed to couple them together. A donut-shaped heat sensitive body (for example, solder) 55 is inserted from the upper part of the plunger 52, and is placed on the flange 52 a of the plunger 52. A heat sensitive plate 53 having a disc shape and having a crank section is provided on the heat sensitive member 55. That is, the heat sensitive plate 53 includes a protrusion 53 a that covers the heat sensitive body 55 provided on the flange portion 52 a of the plunger 52, and a direction that is continuous with the protrusion 53 a and perpendicular to the axis of the head body 10. And an extended disc portion 53b. A force is applied to the heat sensitive plate 53 so as to compress the heat sensitive member 55 by a ball holding mechanism 60 described later.

  A donut-shaped heat insulating material 54 is provided on the top of the heat sensitive plate 53 so that heat received by the heat sensitive plate 53 does not escape to the balancer 63 side described later. In addition, as shown in FIG. 1, you may make it provide another heat sensitive board with a large diameter between the heat insulating material 54 and the heat sensitive board 53 as needed.

The ball holding mechanism 60 includes a ball 61, a slider 62, a balancer 63, and a disc spring 64. The balancer 63 corresponds to a piston because it has a function of compressing the heat sensitive body 55.
The lower outer periphery of the ball 61 is locked to the locking step 22 of the frame 20. In this state, it is the slider 62 that presses the ball 61 from above, and when a force is applied from the slider 62 to the ball 61, a force acts on the ball 61 in the direction of entering the inside.
The balancer 63 is provided inside the ball 61, and regulates the movement of the ball 61 trying to enter the inside of the ball 61. Both the slider 62 and the balancer 63 are formed in a disk shape, and there is a through hole in the center, and a plunger 52 passes through the through hole of the balancer 63. The outer diameter of the plunger 52 is slightly smaller than the inner diameter of the through hole of the balancer 63, and the two are not coupled. The inner diameter of the through hole of the slider 62 is slightly larger than the outer diameter of the leg portion of the set screw 65, and the two are not coupled.

  The balancer 63 has a shape in which a cylindrical portion having a through hole and a disk portion provided above the cylindrical portion are combined. A step portion is formed at the lower outer periphery of the balancer 63. The outer peripheral lower step portion is configured to abut on the inner lower portion of the locking step portion 22 of the frame 20. When an external force is applied from below the balancer 63, Absorb the shock at the part. Further, a stepped portion 63a into which the heat insulating material 54 is fitted protrudes from the lower portion of the cylindrical portion of the balancer 63 around the central through hole, and the ball 61 hits the ball 61 at the upper portion of the disc portion of the balancer 63. The step 63b is formed so as to protrude.

  A concave portion 62a is formed in the lower part on the outer peripheral side of the slider 62, and the surface of the concave portion 62a with which the ball 61 contacts is formed in a tapered shape (inclined portion) so as to be inclined inwardly downward.

  As described above, since force is applied to the ball 61 so as to always move inward, the force acts to move the balancer 63 downward and the slider 62 upward. Therefore, if the solder which is the heat sensitive body 55 melts and flows out, the balancer 63 moves downward, and accordingly, the ball 61 enters inside, and the locked state with the locking step portion 22 of the frame 20 is released. Therefore, the ball holding mechanism 60 falls together with the heat sensitive part 51. If the ball holding mechanism 60 falls, the valve body 30, the stopper ring 43, etc. which comprise the water sprinkling part 40 will fall in connection with it, and water discharge will be performed.

  The set screw 65 is a bolt composed of an enlarged head portion and a narrow leg portion, and the lower portion of the leg portion is coupled to the upper portion of the plunger 52, whereby the balancer 63 as the ball holding mechanism 60. The slider 62 and the heat sensitive part 51 are integrated.

As shown in FIG. 9, a disc spring 64 having a through hole 64a at the center is used. In addition, slits 64b are provided radially from the central through hole 64a at equal intervals of 60 °. A through hole 64c is provided between the slits 64b. For example, three disc springs 64 are combined in the vertical direction, and are arranged between the valve body 30 and the slider 62. The details of the disc spring 64 will be described later.
The disc spring 64 is provided between the valve body 30 and the slider 62 by inserting the set screw 65 into the through hole 64 a. That is, the through hole 64a of the disc spring 64 is formed to be approximately the same as or slightly larger than the outer diameter of the head of the set screw 65. Moreover, the height of the head of the set screw 65 is formed to be larger than the free height of the plurality of stacked disc springs 64, and serves as a guide when the disc springs 64 are overlapped. If the height of the head of the set screw 65 is low, it will not function if the disc spring 64 is crushed more than necessary at the time of assembly. By doing so, the disc spring 64 can be held in a stable state.

  In the sprinkler head 1 as described above, in the state of FIG. 1, the water pressure of the fire extinguishing water at the outlet 12 and the assembly load of the parts act on the ball 61, and the ball 61 tends to move inward (center side). However, the movement of the ball 61 is blocked by the balancer 63, and the ball holding mechanism 60 holds the ball. In this state, the disc spring 64 presses the valve body 30 upward, and the valve body 30 seals the water outlet 12 of the head body 10. For this reason, although the fire extinguishing water pressurized is supplied to the sprinkler head 1, the fire extinguishing water does not leak. Further, in the water sprinkling unit 40, the deflector 41 is fixed to the valve body 30, and the guide rod 42 is fixed to the deflector 41. When the valve body 30 seals the water outlet 12, the guide rod 42 is the head. The main body 10 is housed in the space 18.

FIGS. 2A to 2D are views showing an operation process of the sprinkler head 1.
In the monitoring state of the sprinkler head 1, pressurized fire extinguishing water is supplied to the water outlet 12 of the head main body 10, and the pressure of the fire extinguishing water is applied to the valve body 30 (see FIG. 1). When a fire occurs and the hot airflow hits the heat sensitive plate 53, the heat is heated, and the heat of the heat sensitive plate 53 propagates to the heat sensitive body 55. When the heat sensitive body 55 is heated from the surroundings and starts to melt, the melted heat sensitive body 55 flows out from the gap formed between the plunger 52 and the heat sensitive plate 53 (projection 53a) and the volume thereof decreases. (FIG. 2A).
At this time, the ball 61 pushed from above by the balancer 63 moves inward, but even if the ball 61 moves, the valve body 30 is pressed against the valve seat 17 and maintains the state where the water outlet 12 is blocked. To do. This is due to the action of the disc spring 64, and by stacking a plurality of disc springs 64, the disc spring 64 has a predetermined stroke enough to maintain the seal by the valve body 30. In this way, the valve body 30 is prevented from being separated from the valve seat 17 until the ball holding mechanism 60 is completely dropped, so that it can operate reliably.

  When the heat sensitive body 55 melts and flows out, the heat sensitive plate 53 descends in accordance with the amount of heat sensitive body 55 flowing out. When the heat sensitive plate 53 is lowered, the heat insulating material 54 and the balancer 63 attached on the heat sensitive plate 53 are lowered. When the balancer 63 is lowered, a gap between the balancer 63 and the slider 62 is widened, and the ball 61 biased inward moves inward beyond the stepped portion 63b of the balancer 63, and the locking stepped portion of the frame 20 is moved. The engagement between the ball 22 and the ball 61 is released. Thereby, the valve body 30 and the valve body support mechanism 50 are lowered (FIG. 2B).

When the valve body support mechanism 50 including the disc spring 64 disposed under the valve body 30 is dropped, the valve body 30 is lowered. As the valve body 30 is lowered, the deflector 41 attached to the valve body 30, the guide rod 42 attached to the deflector 41, and the stopper ring 43 are lowered. When the guide rod 42 is lowered, the step portion 42a at the top thereof is locked to the stopper ring 43, the stopper ring 43 is locked to the locking step portion 22 of the frame 20, and the valve body 30 and the deflector 41 are connected to the guide rod 42. Thus, it is suspended from the frame 20 (FIG. 2C). In this operation, the stopper ring 43 may be lowered together with the guide rod 42 until the stopper ring 43 is locked, and after the stopper ring 43 is locked, only the guide rod 43 may be further lowered. is there.
In the present embodiment, during the water discharge operation, the deflector 41 descends together with the guide rod 42 while being guided by the guide member 43a, so that the deflector 41 is smoothly lowered. Further, by providing the stopper ring 43 substantially in the middle of the frame 20 in the height direction, the amount of lowering of the stopper ring 43 itself can be reduced, so that the operation at the time of water discharge becomes smooth.
By the way, the guide member 43a of the stopper ring 43 is bent upward, so that it is unlikely to cause a watering trouble at the time of water discharge. Explaining this point, some of the conventional guide members are bent downward. In this case, if the length of the guide member is long or thick, the water hitting the valve body is reflected when the water is discharged. For example, when the guide member is exposed to water, the guide member becomes an obstacle to watering. That is, by bending the guide member 43a upward and separating the distance from the valve body 30 at the time of water discharge, the guide member 43a can be prevented from becoming a watering obstacle.

  When the valve body 30 is lowered as described above, the water discharge port 12 is opened, and the pressurized fire extinguishing water is sprayed from the deflector 41 to extinguish the fire (FIG. 2 (d)).

  Next, the characteristic parts of the plunger 52, the slider 62, and the disc spring 64, which are parts constituting the sprinkler head of the present invention, will be described in detail.

(Plunger 52)
As described above, the plunger 52 of FIG. 1 is provided such that its tip protrudes downward from the heat sensitive plate 53. When the corresponding part is extracted from FIG. 1, it becomes as shown in FIG. 3, but when something hits the sprinkler head 1 (particularly from below), the plunger 52 protrudes in this way. The object hits the plunger 52, and it is avoided that the object hits the heat sensitive plate 53. Since the plunger 52 is composed of a member whose rigidity is higher than that of the heat sensitive plate 53, there is no risk of deformation. For this reason, there is no possibility that the plunger 52 bites into the heat sensitive plate 53, and malfunction does not occur.

  Further, the plunger 52 has an upper end portion extending to the upper end of the balancer 63 (see FIG. 1), and the set screw 65 is coupled to the plunger 52, so that rigidity is high. For this reason, even if an external force is applied to the sprinkler head 1 from the lateral direction, there is no possibility that the plunger 52 or the set screw 65 is deformed, and no malfunction occurs. In particular, the stepped portion at the lower outer periphery of the balancer 63 is locked to the stepped portion at the lower inner peripheral portion of the locking stepped portion 22, so that the external force received from the lateral direction and the downward direction is strong against the frame. It is transmitted to 2.

  Next, a configuration example of the plunger 52 that copes with an external force obliquely below the sprinkler head 1 will be described with reference to FIGS.

FIG. 4 shows an example in which a step 52c having an enlarged diameter is provided on the upper portion of the flange portion 52a at the lower end of the plunger 52. As shown in FIG. In other words, this is an example in which a step having a reduced diameter is provided at the lower portion of the flange portion 52a.
By providing such a step 52c on the flange 52a of the plunger 52, the external force first hits the corner (point B), so that the corner (point A) is deformed by the downward and obliquely downward external force. Can be prevented. Further, even if the corner portion (point B) is deformed, a stepped portion 52c is formed on the upper side of the deformed portion, so that the deformed portion includes the plunger 52 and the heat sensitive plate 53. The plunger 52 and the heat sensitive plate 53 are engaged with each other due to the deformation, and the plunger 52 and the heat sensitive plate 53 are not coupled with each other by deformation, and the operability is not affected.

5A and 5B are examples in which an R surface 52e or a taper (chamfered C surface) 52f with rounded corners is provided at the lower end of the flange portion 52a of the plunger 52. FIG.
The plunger 52 has a lower end of the flange portion 52a having a smaller diameter than the upper portion of the flange portion 52a, so that even if the lower end portion is deformed by an external force from below and obliquely below, There is no possibility that the deformed portion closes the gap 52d, and the plunger 52 and the heat sensitive plate 53 are engaged with each other due to the deformation, and the operability is not affected.

FIG. 6 shows an example in which a step is provided at the upper portion of the flange portion 52a of the plunger 52, and a taper 52g is provided at the lower portion thereof. The shape is a combination of the shapes of FIG. 4 and FIG. Since the plunger 52 has such a shape of the flange portion 52a, even if the lower end portion of the flange portion 52a is temporarily deformed by an external force from below and obliquely below, the deformed portion blocks the gap 52d. The plunger 52 and the heat sensitive plate 53 are engaged with each other due to the deformation, and there is no fear that they are combined, and the operability is not affected.
As described above, the plunger 52 of the present invention is provided with a step, a tapered surface, or an R surface at the lower end of the flange portion 52a, so that even if the lower end portion is temporarily deformed by an external force from below and obliquely below, Since the lower side and the protrusion 53a of the heat sensitive plate 53 are arranged with a predetermined gap therebetween, in other words, the lower side of the flange portion 52a is inscribed with the protrusion 53a of the heat sensitive plate 53 with a predetermined gap. Since the positional relationship is maintained, the operability is not affected even when the heat sensitive plate 53 is deformed by an external force. Note that the gap may be filled with solder.

(Slider 62)
First, a configuration required for the sprinkler head 1 having the ball holding mechanism 60 including the slider 62 and the ball 61 will be described. If the valve body 30 is separated from the valve seat 17 before the ball 61 is completely removed from the locking step portion 22 of the frame 20, there is a possibility of inactivation due to water leakage during operation. A residual load that supports the valve body is required. Further, in order to ensure the remaining load, it is necessary to suppress the descending amount of the slider 62 (referred to as an operation stroke). For this reason, conventionally, by using a spring having a large displacement amount such as a coil spring, the displacement amount of the coil spring is made larger than the operation stroke of the slider 62, thereby preventing water leakage during operation.
In the present invention, by changing the shape of the slider 62, the operating stroke of the slider 62 is reduced, and the shape of the disc spring 64 is devised to increase the amount of displacement of the disc spring itself, thereby increasing the volume of the coil spring. I didn't use it.
Here, returning to FIG. 1, focusing on the shape of the slider 62, the surface of the recess 62 a on the outer peripheral side of the slider 62 that contacts the ball 61 is tapered, and this tapered surface is in contact with the ball 61. .
By adopting such a shape for the slider 62, when the ball 61 enters the inside of the slider 62 and rides on the balancer 63, the amount of movement (operation stroke) in the axial direction of the slider 62 is on the inside of the slider 62. The amount of displacement required for the disc spring 64, that is, the ball 61 is completely removed from the locking step 22, as compared with the case where the recess is not provided and is flat (conventional example). The stroke required to keep the body 30 in pressure contact with the valve seat 17 can be reduced. A modification of the slider 62 will be described with reference to FIGS.

  FIG. 7 shows an example in which a ball escape portion 62 b is formed on the slider 62. The escape portion 62 b is composed of a recess formed on the lower surface of the slider 62. In this figure, the position of the point (A point) at which the stepped surface is started on the contact surface of the ball 61 is on the head axis side within the range of the ball radius from the center position of the ball (within the range of B). In FIG. 7, when the sprinkler head is operated, when the ball 61 enters the inside of the slider 62, the ball 61 moves so as to enter the upper escape portion 62b. The operation stroke is reduced by speeding up the operation of moving away, thereby reducing the amount of movement of the ball 61 in the axial direction.

  FIG. 8 shows an example in which a taper is formed on the contact surface of the ball of the slider 62 in FIG. The slider 62 is an example in which the tapered surface of FIG. 1 and the relief portion 62b of FIG. 7 are combined.

(Belleville spring 64)
Next, the disc spring 64 of FIG. 1 will be described.
9A, 9B, 9C, 9D and 9E are a plan view, a front view, a side view, a perspective view, and an EE cross-sectional view of a disc spring.
The disc spring 64 is provided with a through hole 64a in the center, and six radial slits 64b are provided so as to be continuous with the through hole. Between the slits, a fan-shaped (triangular and circular arc-shaped) through hole 64c is provided.
The disc spring 64 is provided with the six slits 64b as described above. However, if the number of the slits 64b is as small as four (conventional example), the stress increases and the disc spring breaks. There is a problem that buckling is likely to occur over time. Further, when there are 10 or more slits 64b (conventional example), there are problems that the load is insufficient, the bending amount is insufficient, and the disc spring does not return to its original shape. For this reason, in the present embodiment, the number of slits 64b is set to six, for example.

Further, the through hole 64c is provided between the slits 64b, in order to reduce the stress applied to the disc spring 64. If there is no through hole 64c between the slits 64b, there is a problem that a high stress is generated, the disc spring is broken, and a crack is generated.
The through hole 64c between the slits has a triangular shape and a circular arc shape (fan shape). This is to disperse the stress applied to each part. If the shape of the through hole is a long hole or a square as in the conventional case, the stress is not dispersed, and the disc spring is broken when a large load is applied.

The advantages of the disc spring 64 will be described from another point of view.
The disc spring 64 is divided into a portion that receives a load and a bent portion that is formed on the inner peripheral portion (center side). The portion receiving the load corresponds to the outer peripheral portion (peripheral portion) of the disc spring, and the bent portion corresponds to the shape of the slit portion. By changing these two portions in a well-balanced manner, the disc spring can be set to an arbitrary load and deflection amount. Further, since the stress is dispersed, no cracking or buckling occurs. For this reason, both high load and high displacement, which cannot be achieved by the conventional disc spring, are achieved.
In this embodiment, a disc spring is used that has a lotus root cross-sectional shape composed of radial slits and through-holes provided between the slits to ensure an assembly load and a stroke required for water stoppage. However, the shape of the disc spring used for the sprinkler head is not limited to this shape. For example, one having a plurality of similar disc springs may be used in combination in a timely manner as long as it has a stroke necessary for assembly load and water stoppage and takes corrosion resistance into consideration.

In the present embodiment, the embodiment has been described with the sprinkler head that supports the valve body by the valve body support mechanism provided with the ball holding mechanism by the ball, the slider, and the balancer. For example, the present invention may be applied to a flash-type sprinkler head including a lever-type sprinkler head in which a valve body support mechanism is constituted by a pair of arms.
Moreover, although the valve body was press-contacted to the valve seat in the lower end of a water discharge cylinder, you may make it provide a valve body inside a water discharge cylinder.
Although only the stopper ring is attached to the guide rod in a slidable state, the deflector may be attached to be slidable with respect to the guide rod.

  DESCRIPTION OF SYMBOLS 1 Sprinkler head, 10 Head main body, 11 Opening part, 12 Water discharge port, 13 Flange, 14, 15 Screw part, 16 Water discharge part, 17 Valve seat, 18 Space, 20 Frame, 21 Screw part, 22 Locking step part, 30 Valve body, 31 flange portion, 32 concave portion, 40 water spray portion, 41 deflector, 41a insertion hole, 42 guide rod, 42a stepped portion, 43 stopper ring, 43a guide member, 44 coil spring, 50 valve body support mechanism, 51 heat sensitive portion , 52 Plunger, 52a Flange, 52b Female thread, 53 Heat sensitive plate, 54 Thermal insulation, 55 Heat sensitive body, 60 Ball holding mechanism, 61 Ball, 62 Slider, 62a Recess, 63 Balancer, 64 Disc spring, 65 Set screw

Claims (4)

A frame having a locking step formed inside, a head body connected to an upper portion of the frame and having a water discharge cylinder inside, and a watering portion at least part of which is provided in the frame, In the sprinkler head, wherein the water sprinkling part is composed of a stopper ring, a guide rod, and a deflector provided below the water discharge cylinder,
In addition to providing an insertion hole through which the guide rod is inserted into the stopper ring, a stopper step larger than the insertion hole is provided at the upper end of the guide rod,
The sprinkler head, wherein the stopper ring installed on the deflector slides on the guide rod and moves to the locking step during a water discharge operation.   The sprinkler head according to claim 1, wherein a guide member formed by bending a part of the inner periphery upward is provided on the inner periphery side of the stopper ring.   2. The stopper ring is provided substantially in the middle of the frame in the height direction, and a coil spring is installed between an outer peripheral portion of the stopper ring and a lower portion of the outer peripheral portion of the head body. Or the sprinkler head of 2.   The deflector is fixed to the lower end of the guide rod, and in a normal state, the guide rod is housed in a space formed between the inner peripheral portion of the head body and the water discharge tube. The sprinkler head according to any one of claims 1 to 3, wherein

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