KR19990010327A - sprinkler head - Google Patents

Abstract

Conventional sprinkler heads are susceptible to leakage or explosion due to decomposition or destruction of the thermal decomposition parts when subjected to external shocks. An object of the present invention is to provide a sprinkler head resistant to external impacts.

When no load is applied, the leaf spring 80 whose outer circumference is applied inwardly is made flat between the valve body 4 and the clamper 20, and the widened outer circumference is connected to the engaging groove 14 of the guide post 13. Combine.

Description

sprinkler head

The present invention relates to a sprinkler head to extinguish a fire by spraying water when a fire occurs.

(Prior art)

The sprinkler head has a valve body in a watertight state in the valve seat of the main body, and the valve body is held in the thermal decomposition part. When a fire occurs, the thermal decomposition part is decomposed at an abnormal high temperature of the fire. When the valve body held in the thermal decomposition portion falls, the valve seat is opened and water is sprayed. The thermally decomposed portion is precisely assembled to completely decompose when the fire occurs due to the melting of the low-melting alloy in the thermally decomposed portion and the constituent members of the thermally decomposed portion held in the low-melting alloy slightly moving. .

However, the sprinkler head is attached to the ceiling when the building is built, and remains attached until the building is old and torn down, unless a fire occurs. Therefore, the valve seat of the sprinkler head is pressurized to maintain the watertight state in the valve body for a long time. In addition, since the pipe to which the sprinkler head is attached is always filled with high pressure water of 10 kgf / cm 2, the valve body of the sprinkler head does not pressurize the valve seat with a strong force so as not to leak due to the water pressure. You must. In this way, when a strong force is applied to the valve seat, a strong force is also applied to the thermally decomposed portion holding the valve body. However, the thermally decomposed portion is precisely assembled as described above, and when a strong force is continuously applied for a long time, the valve suppresses the valve seat by deforming the component or disassembling the assembled portion due to the creep phenomenon. The pressure in the sieve is weakened and it leaks.

Therefore, in the sprinkler head, a means for reducing the large force for suppressing the valve body is devised so that the small force is applied by thermal decomposition part. The means for reducing the force is an application of the principle of lever. In other words, the lever is multiplied by the distance between the point of action and the point of action and the force applied to the point of action is equal to the distance between the point of action and the point of the other times the force applied to the point of action. The force exerted is small enough.

In the conventional sprinkler head, the application part of the lever was a pair of levers which bent the flat plate, such as Special Publication 58-36985. The lever is a flat plate having a cross section of a fishing needle, the top of which the lever is bent, and a large force for suppressing the valve body is applied thereto, and the tip of the short leg that becomes the needle side of the fishing needle is applied. This is the point. And the tip of the long leg which becomes the side which binds the thread of a fishing needle becomes another action point, and the distance of a point and the action point becomes longer than the action point and the point of the short leg mentioned above. Therefore, the force applied to the tip of the long leg, that is, the force applied to the thermally decomposed portion, is sufficient with a small force.

In a conventional sprinkler head, by using a pair of these levers, a strong force for suppressing the valve element is equally applied to both lever top portions.

If you walk in a room or corridor with a sprinkler head, or walk with a long object or a child throws an object, the long object or thrown object may come in contact with the sprinkler head. When an object comes into contact with the sprinkler head (called an external impact), the assembly part of the thermally decomposed part, which has been precisely assembled, may be disassembled or destroyed. In this way, when an external shock causes an abnormality in the thermal decomposition part, the force of the valve body that suppresses the valve seat is weakened, and if the water leaks, the valve body completely falls out, causing an explosion accident in which water is sprayed.

When the fire occurs, the valve body is opened and the fire is sprayed to extinguish the fire. The office equipment, the main documents, the furniture, the rug, etc. placed in the room cannot get wet, but the sprinkler head It is a great loss for objects placed indoors to get wet due to leakage or explosion.

Conventional sprinkler heads are susceptible to abnormalities in the thermally decomposed portion even by a slight external impact, causing an accident of water spilling. In addition, the conventional sprinkler head completely decomposes the thermal decomposition part by moving the lever with the melting of the low melting point alloy during operation, so that the number of parts of the thermal decomposition part is large and the material cost is not only high, but also the thermal decomposition part is assembled. It took a lot of time.

(Means to solve the task)

The present inventors have diligently examined that a conventional sprinkler head is weak in external impact and has a large number of parts in the thermal decomposition part. As a result, the weakness in external impact is due to the use of a pair of independent levers. When this is applied, one of the levers is unbalanced and easily disassembled or dislodged. Also, the large number of parts in the thermal decomposition part is found to be due to the need for two levers and a large number of parts for holding the levers.

Here, the present inventors have completed the present invention by noting that the levers are not independent of each other, but are integral with each other, so that the whole becomes strong and requires fewer parts to hold them.

The present invention is a sprinkler head in which the extinguishing fluid is discharged, which normally maintains a closed state and releases the closed state of the nozzle during a fire, and is a means for maintaining and releasing the closed state of the nozzle. Sprinkler head characterized by using a leaf spring that is deformed in both directions in the direction orthogonal to the axial direction when the load is applied, and is restored to its original shape when the load in the axial direction is released. to be.

(Example)

The leaf springs used in the present invention are illustrated as shown in Figs. The leaf spring 80 shown in FIG. 10 is formed in the center of the bottom surface 81 with a hole 82 formed therein, and a plurality of joining pieces 83... Are radially formed around the bottom surface. . The spring force is applied in the direction in which the pressing force of the spring, ie, the outer diameter of the leaf spring, is reduced so that the outer sides of all the engaging pieces 83 are narrowed inward. When the leaf spring 80 is deformed by applying a load in the axial direction to resist the spring pressing force, a deformed portion in a direction orthogonal to the axial direction engages with the components of the sprinkler head to close the nozzle. It is supposed to maintain. In other words, when the leaf spring 80 is brought into a flat state by resisting the pressing force of the spring, the outer side of the engaging piece is sized to be able to engage with the components of the sprinkler head, and when the outer side is narrowed inward by the spring pressing force, It is to be a small diameter.

The leaf spring 90 shown in FIG. 11 has a hole 91 in the center thereof, and is alternately cut as a plurality of U-shaped grooves 93... The outlines form a conical shape. The outside of the leaf spring is exerted with the force of the spring narrowing inward. When the leaf spring 90 is made flat by resisting the spring pressing force, the outside is widened in diameter and the inside hole is narrowed in diameter.

In the leaf spring 100 shown in Fig. 12, the center is the bottom surface 101, and the engaging pieces 103 and 103 are formed on both sides as a quadrangle formed by opening a hole 102 in the center thereof. Normally, the leaf spring is bent inwardly with the engaging pieces on both sides, and when the flat spring is attached to the sprinkler head, the spring force is applied inward.

In the leaf spring 110 shown in Fig. 13, a hole 112 is formed in the center of the bottom surface 111, and a plurality of engaging pieces 113 are formed radially around the bottom surface. The leaf spring is a slit between the joining piece and the adjacent joining piece. The slit is narrower in the vicinity of the bottom surface 111 and gradually widens in the outer part near the end. Therefore, the width | variety (a) of the near side part 114 of the engaging piece 113 is narrow, and the width | variety b of the outer side part 115 is wider than that. Accordingly, when the plate thicknesses of the leaf springs 110 are all the same, the mechanical strength of the outer portion 115 is stronger than that near the bottom surface 114, and the force of the spring of the portion near the bottom surface 114 is equal to the outer portion ( It is weaker than the force of the spring of 115).

In the leaf spring 120 shown in Fig. 14, a hole 122 is formed in the center of the bottom surface 121, and a plurality of coupling pieces 123 are formed radially around the bottom surface. The shape of the engaging piece is the same width as the leaf spring 80 shown in Fig. 10 described above, that is, approximately the same width as the vicinity and the outer portion of the bottom surface, but the reinforcing material 124 on the outer portion of the leaf spring 120. ), The plate thickness of this part is thicker than the other parts. As a result, the leaf spring 120 is stronger than the other parts the mechanical strength of the outer portion.

As in the leaf springs shown in Figs. 13 and 14, when the mechanical strength of the outer portion is strengthened, the reliability can be further improved when the outer portion of the coupling piece is coupled to the constituent portion of the sprinkler head. As a result, in the sprinkler head, the valve body must increase the force suppressing the valve seat to prevent leakage, but the structure in which the valve body force is directly applied to the engaging portion other than the sprinkler head, for example, the outer side of the leaf spring In the structure in contact with the engaging portion of the sprinkler head, a large force is applied to the outer portion of the leaf spring. In order to withstand the force sufficiently, as shown in Figs. 13 and 14, the mechanical strength of the outer portion may be strengthened.

In addition, in the sprinkler head having a structure in which the spring force is directly applied to the thermally decomposed portion in the leaf spring, it is more reliable not only to strengthen the mechanical strength outside the leaf spring but also to weaken the force of the spring applied to the thermally decomposed portion. It will be possible to improve. The reason for this is that heat-sensitive materials such as low melting point alloys and glass valves used in the thermally decomposed portion may be deformed or dug when a large force is applied over a long period of time. As shown in Fig. 13, when the width of the portion near the bottom surface is narrowed, the force of the spring in the portion near the bottom surface can be weakened.

In the leaf springs shown in Figs. 10 to 14, when the load is not applied, the coupling piece is bent inward as shown, and when the load is applied from the vertical direction to the axial direction, that is, the bottom surface, the whole is flat and the outer side of the coupling piece is inward. With the spring pressing force back up. However, in the leaf spring used for the sprinkler head of the present invention, the spring pressing force is in the opposite state to that described above, i.e., substantially flat when no load is applied, and when the load is applied in the axial direction, the outer side of the coupling piece is directed outward. The spring force may be applied.

In the sprinkler head of the present invention, a single leaf spring for maintaining and releasing the closed state of the nozzle is usually sufficient, but a plurality of leaf springs may be used for strength and structural problems.

In the present invention, any component that couples the leaf spring to the sprinkler head may be any portion to which the leaf spring holding the valve body such as a nozzle, a guide post, a frame, and a cover can be coupled.

In the sprinkler head of the present invention, as a means for restraining the restoring force of the leaf spring, a heat-sensitive body such as a low melting point alloy melted at a predetermined temperature, a shape memory alloy deformed at a predetermined temperature, or a glass valve destroyed at a predetermined temperature is used. Can be.

The present invention is a spherical sprinkler head is installed in a watertight state in the valve seat, for example, a multi-type formed by a plurality of holes in the bowl-shaped cover, a frame yoke type or a deflector is usually formed by hanging a deflector (deflector) in the lower part of the main body It is housed inside the head and can be adapted to a flash type that falls by a certain distance in the event of a fire.

EMBODIMENT OF THE INVENTION Hereinafter, this invention is demonstrated based on drawing. 1 is a front sectional view of a multi-type sprinkler head according to the first embodiment, FIG. 2 is a front sectional view during operation of the multi-type sprinkler head according to the first embodiment, and FIG. 4 is a front sectional view for explaining the state after the operation of the multi-type sprinkler head, FIG. 4 is a front sectional view of a frame yoke type springkler head according to the second embodiment, and FIG. 5 is a frame yoke according to the second embodiment. Fig. 6 is a front sectional view of the frame sprinkler head during operation, Fig. 6 is a front sectional view of the frame yoke sprinkler head after the end of operation according to the second embodiment, and Fig. 7 is a front sectional view of the frame yoke sprinkler head according to the third embodiment. 8 is a front sectional view of the frame yoke type sprinkler head during operation according to the third embodiment, and FIG. 9 is an operation type of the frame yoke type sprinkler head according to the third embodiment. A front sectional view for explaining the state after.

First, a multi-type sprinkler head according to the first embodiment shown in Figs. 1 to 3 will be described.

The multi-type sprinkler head 1 is comprised from the main body 2, the cover 3, the valve body 4, and the thermal decomposition part 5. As shown in FIG.

The main body 2 has a nozzle 6 formed in the center thereof, and a male screw 7 for attaching to a pipe (not shown) is formed outside the main body 2. In addition, a large diameter flange 8 is formed in the lower part of the main body 2, and a female screw 9 is formed in the inner side of which the flange is long extended downward.

The cover 3 is a bowl shape, and a male screw 10 is formed on the outer top, and the male screw is coupled to the female screw 9 of the main body flange 8 described above. A central hole 11 is formed in the center of the cover 3, and a plurality of sprinkling holes 12 are formed around the center hole 11. A cylindrical guide post 13 is coupled to the central hole 11 of the cover 3. The guide post 13 has a large diameter at the upper end and a two-stage shape at the lower end, and the coupling groove 14 is formed in the small diameter portion.

The valve body 4 has a cylindrical shape in which an upper portion of the valve body 4 is inserted into the lower portion of the nozzle 6 and an engaging portion 16 larger than the nozzle is formed thereunder. The dovetail groove is formed in the insertion part 15 so that the O-ring 17 is coupled to the dovetail groove. The O-ring 17 is capable of sliding the valve body 4 in the nozzle and maintaining watertightness. The valve body 4 inserts the insert 15 into the nozzle 6 and engages the coupling portion ( When 16) is applied to the lower part of a nozzle part, the lower part of a valve body becomes a length which can be inserted in the small diameter part of the guide post 13 a little. The lower part of the coupling part 16 is a diameter which can slide easily inside the guide post 13 mentioned above, and the female screw 18 is formed in the center of the lower surface of the valve body.

The thermal decomposition part 5 is comprised from the leaf spring 80, the clamper 20, the cylinder 21, the plunger 22, the low melting point alloy 23, the coil spring 24, etc.

The leaf springs used in the sprinkler head of the first embodiment are dish-shaped as shown in Fig. 10, and when the load is not applied, the coupling piece 83 is bent inward, and is substantially flat when the load is applied in the axial direction. Thus, the force of the spring is applied so that the outer side of the engagement piece faces inward.

The clamper 20 is a columnar shape having a flange 28 formed at the bottom and a hole formed at the center thereof, and the outer diameter of the clamper 20 is approximately equal to the lower outer diameter of the valve body 4 described above. Usually, the leaf spring 80 is suppressed in a flat state between the upper surface of the clamper 20 and the lower surface of the valve body 4. Thus, when the leaf spring 80 is suppressed between the valve body 4 and the cool ramp 20, the outer diameter of the leaf spring is larger than the outer diameter of the valve Chen 4 or the clamp 20, the valve body 4 and The state slightly protrudes from the clamper. This protruding portion is placed to engage in the engaging groove 14 of the guide post 13.

The cylinder 21 is cup-shaped, and the bottom surface is formed with the hole of the diameter substantially the same as the center hole of the clamper 20. The cylinder 21 is provided in the lower surface of the clamper so that the hole in the bottom surface coincides with the hole in the clamper 20.

The plunger 22 is a bolt shape in which a male screw 29 is formed at one end and a head 30 is formed at the other end. The male screw 29 of the plunger 22 is coupled to the female screw 18 of the valve body 4, and the head 30 at the other end is located in the cylinder 21 through the hole of the cylinder 21.

The low melting point alloy 23 is filled in the cylinder 21 and placed between the head 30 of the plunger 22 and the bottom surface of the cylinder 21.

The coil spring 24 is installed in a compressed state between the flange 28 of the clamper 20 and the cover 3, and normally applies a force of the spring downward to the clamper 20. In this state, the coil spring 24 applies the clamper 20 downward, and the leaf spring 80 also applies the clamper 20 downward, so that the plunger fixed to the valve body 4 The low melting point alloy 23 placed between the head 30 of the 22 and the cylinder 21 is pressurized by the head 30.

Subsequently, the operation state in the multi-type sprinkler head of the first embodiment will be described. When a fire occurs, the low melting point alloy 23 in the cylinder 21 is heated up at a higher temperature. The low melting point alloy melts at the melting temperature (generally 72 ° C or 96 ° C), but is under pressure by the head 30 of the plunger 22, so that the molten low melting point alloy 23 is shown in FIG. As it flows out from the gap between the cylinder 21 and the head 30. Then, the head 30 enters the cylinder 21, and the clamper 20 is lowered by the force of the coil spring 24 and the leaf spring 80, so that the gap between the valve body 4 and the clamper 20 opens. When the gap between the valve body 4 and the clamper 20 opens, the leaf spring 80 is narrowed on the outer side of the coupling piece 83 by the pressing force of the spring, so that the coupling piece 83 is the coupling groove of the guide post 13. Falls from (14).

Since the valve body 4 is always under pressure from the water in the pipe and the clamper 20 is under pressure due to the coil spring 24, the coupling of the leaf spring 80 coupled with the valve body 4 By this loosening, the valve body 4 has the insertion part 15 removed from the nozzle 6, and the valve body 4, the leaf spring 80, the clamper 20, the cylinder 21, and the plunger 22 The coil spring 24 and the like fall downward. However, since the coupling part 16 is formed in the valve body 4, as shown in FIG. 3, the coupling part 16 is engaged with the large diameter part of the guide post 13, and dropping is stopped.

When the valve body 4 is pulled out of the nozzle 6, water in the pipe is ejected from the nozzle and touches the upper surface of the valve body 4 coupled to the guide post 13 to fill the cover 3. Water filled in the cover is discharged from the plurality of water holes (12…) formed through the cover and sprayed in all directions to extinguish fire.

Next, the sprinkler head of the frame yoke type which is a 2nd Example is demonstrated based on FIGS.

The sprinkler head 31 of the frame yoke type is comprised from the main body 32, the deflector 33, the valve body 34, and the thermal decomposition part 35.

The main body 32 has a nozzle 36 formed in the center thereof, and an external thread 37 is formed on the upper outer side of the nozzle to attach to a pipe (not shown). From the lower part of the male screw 37, one frame yoke 38 bent in a bow shape protrudes. The conventional frame yoke type sprinkler head is a structure for maintaining a thermally decomposed portion subjected to a strong force between the lower part of the nozzle and the lower part of the frame yoke, and two thick frame yokes are required to improve mechanical strength. However, frame yokes affect the watering condition during watering, so it is desirable to use as little or as thin as possible. Since the frame yoke type sprinkler head of the present invention does not have to hold the thermal decomposition portion between the lower part of the nozzle and the frame yoke, the frame yoke can be made thinner than the conventional one. A coupling groove 39 is formed in the lower inner side of the nozzle 36.

The deflector 33 is a disk having a plurality of wings at its edges, and is attached to the lower part of the frame yoke 38 described above.

The valve body 34 is a cylindrical shape having an outer diameter of a diameter slightly smaller than that of the nozzle 36, and a flange 40 is formed at the lower portion thereof, and a female screw 41 is formed at the center of the lower surface thereof. Moreover, the dovetail groove is dug in the substantially center part of the valve body, and the O-ring 42 is couple | bonded with the dovetail groove. The O-ring 42 is capable of sliding the valve element in the nozzle and maintaining watertightness.

The thermal decomposition, part 35 is comprised from the leaf spring 80, the clamper 44, the cylinder 45, the plunger 46, the low melting point alloy 47, and the coil spring 48. As shown in FIG.

The leaf spring used for the frame yoke type sprinkler head of the second embodiment is the same as that used for the multi type sprinkler head of the first embodiment described above. The leaf spring 80 is sized such that the outer side of the coupling piece can be inserted into the coupling groove 39 when the flat spring resists the joining force of the spring and is narrowed inward by the pressing force of the spring. It is made smaller than 39). Normally, the leaf spring 80 receives a pressure in a flat state between the valve body 34 and the clamper 44, and the outside thereof is coupled to the coupling groove 39 of the nozzle 36.

The clamper 44 is a cylinder having a smaller diameter than the valve body 34, and is formed with a hole formed in the center thereof. The clamper 44 presses the leaf spring 80 between the valve body 34 to maintain a flat state.

The cylinder 45 is formed in the shape of a cup with a hole formed in the center of the bottom surface thereof, and the hole is formed in the lower surface of the clamper 44 by matching the hole with the hole of the clamper 44.

The plunger 46 is a bolt type in which a male screw 50 is formed at one end and a head 49 is formed at the other end. The male screw of the plunger 46 is coupled to the female screw 41 of the valve body 34, and the head 49 at the other end is located in the cylinder 45.

The low melting point alloy 47 is filled in the cylinder 45 and is under pressure from the head 49 of the plunger 46.

The coil spring 48 is installed in a compressed state between the lower end of the nozzle 36 and the cylinder 45, and always applies the force of the spring downward to the cylinder. Therefore, the valve body 34 is applied with a force falling downward due to the pressure of the water in the pipe and the force of the coil spring 48, the leaf spring 80 is coupled to the coupling groove 39 of the nozzle 36 It stays in the nozzle without falling.

Next, the operation state in the frame yoke type sprinkler head of the second embodiment will be described.

When a fire occurs, as shown in Fig. 5, the low melting point alloy 47 in the cylinder 45 melts and flows out between the head 49 of the cylinder 45 and the plunger 46. Then, the valve body 34 and the clamper 44 are opened by the force of the spring which is raised back to the inside of the leaf spring 80, and the outer side of the leaf spring 80 is narrowed to fall from the engaging groove 39 of the nozzle 36. . When the leaf spring 80 is separated from the engaging groove 39, the valve body 34 is kept in the nozzle 36, so that the valve body 34 and the valve body are controlled by the hydraulic pressure in the pipe and the force of the coil spring 48. The leaf spring 80, the clamper 44, the cylinder 45, the plunger 46, and the coil spring 48, which are integrated with each other, fall as shown in FIG. When the valve body 34 falls, water in the pipe is ejected from the nozzle 36, collides with the deflector 33, and water is sprayed in all directions to extinguish fire.

Subsequently, the frame yoke type sprinkler head of the third embodiment will be described with reference to Figs.

In the frame yoke type sprinkler head 51 of the third embodiment, the same parts as in the frame yoke type sprinkler head of the second embodiment will be denoted by the same reference numerals and the description thereof will be omitted.

In the middle portion of the nozzle 36, a female thread 52 is formed at the center thereof, and a retaining ring 54 having a plurality of flow passages 53 formed around the nozzle 36 is provided. A female bar 52 of the retaining ring 54 is coupled with a sliding bar 56 having a coupling groove 55 formed therein.

The valve body 57 has a hole 58 formed in the center thereof, and a male screw 59 is formed at the outer lower portion thereof. The dovetail grooves are formed in the outer side of the valve body 57 and the lower part of the center hole, respectively, and the O-ring 60 and the O-ring 61 are coupled to these dovetail grooves.

The thermal decomposition portion 62 includes a retainer 63, a cylinder 64, a low melting point alloy 65, a plunger 66, a spring bearing 67, a compression spring 68, and a leaf spring 90. ) And the like.

The leaf spring used for the sprinkler head of the third embodiment has a conical shape as shown in FIG. This leaf spring has a large hole 91 when no load is applied, but narrows the hole 91 when it is flattened by applying a load.

The holding body 63 is a bottomed cylinder, and a flange 69 is formed outside the bottom surface, and a hole 70 is formed in the center of the bottom surface. The cylinder 64 is a bottomed cylinder, and is filled with a low melting point alloy 65 therein, and a flange is formed outside the opening. The plunger 66 is a cylinder formed by digging a conical groove 71 in the upper center. The spring bearing 67 is a bottomed cylindrical shape with a low height, the upper part being a step part 72, and the hemispherical protrusion 73 is formed in the lower surface.

In the frame yoke type sprinkler head of the third embodiment, the structure of the valve body 57 and the thermally decomposed portion 62 is such that the valve body 57 is inserted into the nozzle 36 and the hole 58 of the valve body slides. It is inserted into the bar 56. At this time, the compression spring 68 is compressed between the flange 69 and the lower part of the nozzle to apply the force of the spring to push the retainer 63 downward. And the compression spring is arrange | positioned in the flange 69 of the holding body 63, the cylinder 64 is inserted in the hole 70 of the holding body, and the flange of the cylinder is couple | bonded with the hole 70. The plunger 66 is disposed on the low melting point alloy 65 filled in the cylinder 64, and the projection 73 of the spring bearing 67 is disposed in the groove 71 of the plunger. And the holding body 63 is couple | bonded with the male screw 59 of the valve body 57 in the state which the leaf spring 90 shown in FIG. 11 is arrange | positioned at the step part 72 of the spring bearing 67. As shown in FIG. When the holding body 63 is coupled to the valve body 57, the leaf spring 90 becomes flat as shown in Fig. 7 against the pressing force of the spring. When the leaf spring 90 becomes flat, the outer circumference becomes wider but the diameter of the hole 91 becomes smaller. Therefore, the hole 91 of the flattened leaf spring 90 is engaged with the engaging groove 55 of the sliding bar 56.

In the frame yoke-type sprinkler head thus assembled, the pressing force of the leaf spring 90 suppresses the low melting point alloy 65 through the spring bearing 67 and the plunger 66.

In the operation of the frame yoke type sprinkler head of the third embodiment, when the fire occurs and the low melting alloy melts, as shown in FIG. 8, the plunger 66 is pressed by the force of the leaf spring 90 and the low melting alloy The plunger 66 enters the cylinder 64 simultaneously with the outflow of 65. Then, the leaf spring 90 is restored to its original shape, and consequently, as shown in Fig. 11, and the diameter of the hole 91 is widened. When the diameter of the hole 91 becomes wider, it will fall from the engaging groove 55 of the sliding bar 56 to which the hole was couple | bonded. The holding body 63 is pushed downward by the compression spring 68, so that the valve body 57 slides down from the sliding bar 56, and the holding body 63 is coupled to the valve body 57, The cylinder 64 arranged in the holding body, the cylindrical plunger 66, the spring bearing 67, the leaf spring 90, and the like are united and fall downward as shown in FIG.

In this way, when the valve body 57 falls from the nozzle 36, extinguishing liquid is ejected from the nozzle and sprayed in all directions by the deflector 33, and extinguishing is performed.

In the case where the present invention is applied to a flash type sprinkler head, the thermally decomposed portion may have the same shape as in any of the above-described embodiments, and thus the description of the flash type sprinkler head will be omitted.

In the embodiment, the leaf spring is shown to be coupled to the guide post, nozzle, sliding bar, etc. of the cover, which is a component of the sprinkler head, but in the sprinkler head of the present invention, the engagement of the leaf spring is not limited to these coupling portions. Needless to say, any component can be combined as long as it can be combined.

1 is a front sectional view of a multi-type sprinkler head according to a first embodiment;

2 is a front sectional view during operation of the multi-type sprinkler head according to the first embodiment;

3 is a front sectional view of the multi-sprinkler head according to the first embodiment after the end of operation;

Fig. 4 is a front sectional view of the sprinkler head of the frame yoke type according to the second embodiment;

5 is a front sectional view of the sprinkler head of the frame yoke type according to the second embodiment during operation;

6 is a front sectional view after the operation of the head of the sprinkler of the frame yoke type according to the second embodiment,

7 is a front sectional view of the sprinkler head of the frame yoke type according to the third embodiment;

Fig. 8 is a front sectional view of the sprinkler head of the frame yoke type in the third embodiment during operation;

9 is a front sectional view of the frame yoke type sprinkler head after the end of operation according to the third embodiment;

10 is a perspective view of a leaf spring used in the sprinkler head of the present invention,

11 is a perspective view of a leaf spring of another shape used in the sprinkler head of the present invention;

12 is a perspective view of a leaf spring of another shape used in the sprinkler head of the present invention,

13 is a perspective view of a leaf spring of another shape used in the sprinkler head of the present invention,

Figure 14 is a perspective view of a leaf spring of another shape for use in the sprinkler head of the present invention.

Explanation of symbols for main parts of the drawings

1: Multi type springkler head

2: main body 3: cover

4: valve body 5: thermal decomposition portion (感 (分解 部分)

13: guide post 14: coupling groove

80: leaf spring 20: clamper

21: cylinder 22: plunger

23: low melting point alloy 24: coiled spring

As described above, the sprinkler head of the present invention uses a leaf spring to the portion receiving the force of the valve body to couple the leaf spring to the circumference of the sprinkler head, so that even if an external shock is applied to the thermal decomposition portion, Since the assembly is not disassembled or destroyed and the number of parts of the thermal decomposition part is at least possible, it is possible to exert an excellent effect that the conventional sprinkler head has in terms of reliability and economy.

Claims (11)

The nozzle for discharging the extinguishing fluid has a sprinkler head which normally maintains a closed state and releases the closed state of the nozzle during a fire. As a means, when the load is applied in the axial direction of the sprinkler head, the leaf spring deforms in both directions in the direction perpendicular to the axial direction and the axial direction, and is restored to its original shape when the axial load is released. Sprinkler head, characterized in that used. The sprinkler according to claim 1, wherein when the leaf spring is deformed by the load in the axial direction, the deformed portion in the direction orthogonal to the axial direction is combined with the components of the sprinkler head to maintain the closed state of the nozzle. head. The sprinkler according to claim 1, wherein the leaf spring releases the closed state of the nozzle away from the components of the sprinkler head when the axial load applied thereto is released and restored to its original shape by its elasticity. head. The sprinkler head according to claim 1, wherein a heat-sensitive member that melts, deforms, or breaks down at a predetermined temperature is used as a means for restraining the restoring force of the leaf spring. 2. The leaf spring of claim 1, wherein a plurality of engaging pieces are formed on an outer circumference or an inner circumference of the bottom surface, and the engaging pieces have a spring force applied inward or outward. Sprinkler head. According to claim 1, The leaf spring has a conical shape of the outer shape, the outer side and the inner side is formed with the engaging pieces are cut alternately with the V-shaped or U-shaped grooves, the engaging piece is in the axial direction Sprinkler head characterized in that the force of the spring is applied inward or outward. 2. The sprinkler head according to claim 1, wherein the leaf springs have coupling pieces formed on both sides of the quadrangle, and the coupling pieces have a spring force applied in an axial direction and inward direction. The sprinkler head according to claim 1, wherein the leaf spring is used for at least one sheet. The sprinkler head according to claim 1, wherein the leaf spring has a stronger outer portion than other portions. The sprinkler head according to any one of claims 1 to 9, wherein the leaf spring has a width at an outer portion wider than a width near the bottom surface. The sprinkler head according to any one of claims 1 to 9, wherein the leaf spring has a thicker outer portion than the other portions.