KR101930061B1 - Fog spraying sprinkler for fire suppression and fire suppression system including the sam - Google Patents

Abstract

The present invention relates to a fog spraying sprinkler for fire suppression, and more specifically relates to the fog spraying sprinkler for fire suppression installed at the ceiling of a building (in a household) for fire suppression. To this end, a fire suppression system including the sprinkler for fire suppression of the present invention comprises: a water tank storing water supplied from a water pipe; a pump supplying water stored in the water tank; a connection pipe connected to the pump and supplied with the water from the pump; the sprinkler installed in the household by being connected to the connection pipe, and fog spraying the supplied water; and a control module controlling driving of the pump.

Description

FIELD OF THE INVENTION [0001] The present invention relates to a fog spraying sprinkler for fire suppression and a fire suppression system including the fire suppression system,

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a mist sprayer for fire suppression, and more particularly, to a fire mist sprayer for a fire fighting fire installed on a ceiling of a building.

In recent years, when most of the buildings have become high-rise and large-sized, and a fire occurs in the center of a high-rise building, fire suppression using a fire truck is not smooth and rapid fire evolution has not been achieved.

Accordingly, a fire suppression sprinkler was installed on the ceiling of each floor of the high-rise building so that the fire truck could be extinguished even before it arrived at the scene. The sprinkler installed inside the building is automatically operated when a high temperature due to the fire is detected by a temperature sensor installed at a predetermined position of the ceiling panel, and water is sprinkled at high pressure to evolve the fire.

FIG. 1 shows a prior art fire suppression sprinkler. The sprinkler for fire suppression according to the prior art is connected to the branch pipe 1 and the branch pipe 1 which are fixed to the bottom surface of the slab 9 and branch-connected to a fire supply pipe (not shown) And an elbow (4) to which the sprinkler (3) supported by the panel (2) is screwed.

As described above, the conventional fire suppression sprinkler 3 is exposed to the ceiling panel 2, which is disadvantageous in that it is not well-viewable. In addition, since it is provided in a protruding form on the top panel 2, there is a limitation in increasing the size of the aesthetic appearance, and thus there is a limit in ensuring a sufficient spray area.

Further, in the conventional fire suppression sprinkler 3, water is sprayed in the form of a water stream, and water is sprayed directly from the sprinkler 3, such as a part of the sprinkler 3 outside the water spraying range, There is a limit in suppressing the fire at the non-reaching portion, so that there is a limit in completely suppressing the fire in the early stage of the fire by the sprinkler 3 alone.

Korean Patent Publication No. 2017-0069725 Korean Patent Publication No. 2017-0087897

A problem to be solved by the present invention is to provide a sprinkler capable of rapidly suppressing a fire.

Another problem to be solved by the present invention is to propose a sprinkler in which the installation cost is reduced.

Another problem to be solved by the present invention is to propose a sprinkler capable of minimizing damage in the fire fighting process.

Another problem to be solved by the present invention is to provide a sprinkler for suppressing a fire in a different injection form according to a point of occurrence of a fire.

To this end, the fire suppression system including the fire suppression sprinkler of the present invention includes a water tank in which water supplied from a water pipe is stored; A pump for supplying water stored in the water tank; A connection pipe connected to the pump and supplied with water from the pump; A sprinkler connected to the connection pipe and installed in the house, for spraying the supplied water with mist; And a control module for controlling the driving of the pump.

The fog spraying sprinkler for fire suppression according to the present invention has the effect of rapidly suppressing fire generated at a point where a water stream does not reach through a mist sprayed through a mist spray nozzle.

In addition, the present invention can reduce the installation cost by installing the water tank and the pump in the house, and minimize the damage in the fire suppression process by spraying the fog instead of the water stream. In addition, the present invention has the effect of suppressing the fire efficiently by proposing a sprinkler that extinguishes the fire in a different injection form according to the point of occurrence of the fire.

In addition, there is an advantage that a fire can be suppressed at an early stage by spraying a fog in not only a sprinkler installed in a fire area but also a sprinkler installed in an adjacent area.

FIG. 1 shows a prior art fire suppression sprinkler.
FIG. 2 shows a fogging sprinkler for fire suppression according to an embodiment of the present invention.
FIG. 3 shows a structure of a mist spray nozzle according to an embodiment of the present invention.
Figure 4 illustrates a fire suppression system in accordance with an embodiment of the present invention.
Figure 5 illustrates a fire suppression system in accordance with another embodiment of the present invention.
Figure 6 shows a sprinkler according to an embodiment of the invention.
7 shows a sprinkler according to another embodiment of the present invention.

BRIEF DESCRIPTION OF THE DRAWINGS The foregoing and further aspects of the present invention will become more apparent from the following detailed description of preferred embodiments with reference to the accompanying drawings. DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Reference will now be made in detail to the embodiments of the present invention, examples of which are illustrated in the accompanying drawings.

FIG. 2 shows a fogging sprinkler for fire suppression according to an embodiment of the present invention. Hereinafter, a mist spraying sprinkler for fire suppression according to an embodiment of the present invention will be described in detail with reference to FIG.

Referring to FIG. 2, the fire suppression mist sprayer 100 for fire suppression is proposed to be sprayed in the form of mist spray instead of the conventional method in which water is sprayed in the form of a water stream. When water is sprayed in the form of a water stream, the fire can be effectively suppressed when a fire occurs in the lower part where water is sprayed. However, there is a problem in that a fire can not be effectively suppressed when a fire occurs in areas other than the area where water is sprayed have. Further, in the case of a conventional sprinkler in which water is sprayed, a large amount of water is temporarily sprayed, and in particular, after the actual fire is extinguished, water is continuously sprayed, and thus water is unnecessarily wasted. Therefore, the present invention proposes a sprinkler capable of spraying mist, not a sprinkler in which water is sprayed.

As described above, FIG. 2 proposes a mist sprayer for fire suppression proposed by the present invention. Referring to FIG. 2, the mist sprayer 100 for fire suppression includes a plurality of mist spray nozzles in which one mist spray nozzle 300 is formed. FIG. 2 shows that a plurality of mist spray nozzles are formed on a frame formed in a concentric shape.

As described above, the present invention is advantageous in that fire can be suppressed by using a small amount of water by suppressing fire by using mist spray, and fire can be extinguished even when a fire occurs in a place not exposed to water by the existing direct injection. In addition, the damage caused by water can be minimized by suppressing the fire by using a small amount of water. In addition, by providing a plurality of sprinklers capable of spraying mist at home, there is an advantage that the fire can be suppressed at the early stage by spraying mist from the adjacent sprinkler as well as the sprinkler installed in the area where the fire occurs. That is, it is possible to suppress the fire efficiently by using fine mist spraying.

In addition, the fog which is sprayed blocks the air, and the fire can be quickly suppressed by the blocked air.

FIG. 3 shows a structure of a mist spray nozzle according to an embodiment of the present invention. Hereinafter, the structure of the mist spraying nozzle according to an embodiment of the present invention will be described in detail with reference to FIG.

According to Fig. 3, the mist spray nozzle includes a discharge port, a check pin, a check spring, a body, a filter, a lower body, and an anti-loose rubber ring. Of course, other configurations other than the above-described configuration may be included in the mist spray nozzle proposed in the present invention.

The lower main body 305 is fastened to the fitting, and one end is formed with a thread groove for fastening to the fitting. The lower main body 305 has a shape of an empty through hole, and water supplied from the piping is passed through. The other side of the lower end body 305 is formed with a thread groove on the inner side. That is, one side of the lower body 305 is formed with a thread groove on the outer side, while the other side of the lower body 305 is formed with a thread groove on the inner side.

The anti-loose rubber ring 310 is coupled to the lower end body 305, and particularly formed at one end of the lower end body 305 to which the fitting is fastened. The anti-loose rubber ring 310 is positioned between the lower end body 305 and the pipe 200 to prevent the pipe 200 from being separated from the lower end body 305.

A filter 315 is disposed inside the lower end body 305 having a hollow interior. The filter 315 filters foreign matters contained in the water particles. In particular, the present invention introduces a filter 315 having a size of 25 mu m into the lower main body 305. [ Also, as shown in FIG. 3, the filter 315 can be easily replaced after the main body 320 and the lower main body 305 are separated from each other.

One side of the main body 320 is fastened to the other side of the lower body 305 and the other side is fastened to the discharge port 335. The main body 320 forms an empty hole for supplying the water particles supplied from the lower end body 305 to the discharge port 335. One side of the main body 320 has a thread groove on the outer side, and the other side also has a thread groove on the outer side.

A check spring 325 is inserted into the main body 320. The check spring 325 is composed of an elastic part having elastic material on one side and a spring on the other side. Normally, the resilient portion cuts the through hole in the main body by the elasticity of the spring. That is, the through hole in the main body is clogged by the elasticity of the spring normally, so that the water particles are not discharged to the outside.

However, when a high pressure is formed in the piping, the high pressure water presses the elastic part, which also presses the spring. When the spring is pressed, the spring is compressed, which causes the check spring 325 to be spaced a distance from the body 320. When the check spring 325 is separated from the main body 320 by a predetermined distance, water (or water particles) in the pipe is discharged to the outside.

The check pin 330 is inserted into the check spring 325, and the inside thereof has an empty through hole shape. That is, the supplied water is discharged to the discharge port 335 through the inside thereof. Particularly, the inside of the check pin 330 forms a through hole for supplying water to the outside, and the diameter of the through hole is relatively smaller than the size of the filter in consideration of the size of water particles discharged to the outside. For example, the size of the through-hole is preferably 5 mu m or less.

The outer diameter of one side of the check pin 330 is configured to have the same diameter as the inner diameter of the spring so as to be introduced into the spring, the outer diameter of the other side is formed to have the same diameter as the outer diameter of the spring, Is formed relatively small in consideration of the size of the discharge portion formed in the discharge port (335).

The discharge port 335 discharges the supplied water particles to the outside. The discharge port 335 has a screw shape on one side in order to fasten it to the main body 320. The discharge port 335 forms a discharge portion, and the discharging portion closely contacts the end of the check pin 330.

Figure 4 illustrates a fire suppression system in accordance with an embodiment of the present invention. Hereinafter, a fire suppression system according to an embodiment of the present invention will be described in detail with reference to FIG.

Referring to FIG. 4, the fire suppression system includes a water tank, a pump, a sensing sensor, a sprinkler, a connection pipe, a humidity sensor, and a control module. Of course, other configurations than those described above may be included in the fire suppression system proposed by the present invention.

The water tank 106 is connected to the water pipe, and water supplied through the water pipe is stored. A water level sensor is formed inside the water tank 106, and a predetermined amount of water is stored in the water tank 106 using a water level sensor.

The pump 104 is connected to the water tank 106 and supplies the water stored in the water tank 106 to the sprinkler 100. In other words, the pump 104 supplies the water stored in the water tank to the sprinkler 100 in accordance with the control command of the control module 108.

The detection sensor 112 is installed at a position spaced a certain distance from the sprinkler 100. The sensing sensor 112 senses the ambient temperature and provides the sensed temperature information to the control module 108. In the present invention, the detection sensor 112 is not installed only at a distance from the sprinkler 100 within a certain distance, but may be installed at various positions if necessary. As described above, since the conventional sprinkler is sprayed in the shape of a water stream, it is common to install a detection sensor in a region where the water stream reaches. In other words, it is not possible to suppress the fire promptly even if water sprays are sprayed from the detection sensor installed in the area where the water stream does not reach. Therefore, it is general that the existing sensor is installed within a certain distance from the sprinkler. In contrast to this, the present invention uses a sprinkler capable of spraying in the form of mist instead of a water stream, so that it is possible to extinguish a fire far to a far point as compared with a conventional sprinkler, and fire generated at a point where an existing water stream, There is an advantage that it can suppress. Therefore, the present invention is advantageous in that the detection sensor can be installed at a relatively wide point as compared with the conventional method.

As described above, the sensor 112 measures the ambient temperature and provides information to the control module 108 about the ambient temperature. Of course, the detection sensor 112 also provides its own position information to the control module 108.

The humidity sensor 110 measures the ambient humidity and provides the measured humidity information to the control module 108. Of course, the humidity sensor 110 provides its position information to the control module 108 in the same manner as the detection sensor 112.

The connection pipe 102 connects the sprinkler 100 and the pump 104. As described above, since the pump is installed in the house, there is an advantage that the length of the connecting pipe is shortened compared with the conventional one. In general, the existing sprinklers installed in the house received water from the fire hydrant, and if the distance from the fire hydrant is too long, the length of the connecting piping is also increased and the installation cost is increased.

In contrast, according to the present invention, the water tank and the pump are installed in the house, and the length of the connecting pipe is shortened compared with the conventional case.

The sprinkler 100 is installed in the house and discharges the water supplied from the connected pump 104 to the outside in the form of mist.

The control module 108 receives temperature information from the sensing sensor 112 and position information of the sensing sensor 112 and receives humidity information and position information of the humidity sensor 110 from the humidity sensor 110. The control module 108 controls the pump 104 to supply water to the sprinkler 100 so that the mist is sprayed if the humidity included in the humidity information provided from the humidity sensor 110 is less than the set humidity.

The control module 108 controls the pump 104 to supply water to the sprinkler 100 so that the mist is sprayed when the temperature included in the temperature information provided from the detection sensor 112 is equal to or higher than the set temperature. As described above, the control module proposed in the present invention controls the driving of the pump according to various environmental information as well as the case where the ambient temperature is higher than the set temperature. In particular, although the present invention proposes a method of increasing the humidity by spraying a mist when the humidity is low, it is possible to lower the temperature of the house by spraying mist over a certain period of time when the temperature of the house is high.

And may be connected to the pump 104 by one connection pipe of a plurality of sprinklers. In this case, when the pump is driven, the mist is injected into all the sprinklers connected through the connecting piping. In contrast, a plurality of sprinklers can be divided into a plurality of groups, and the sprinklers included in each group can be connected by one connection pipe. That is, the home can be divided into a kitchen, a living room, a living room, a study room, and a connection pipe can be installed for each group. Also, one or at least two sprinklers may be connected to each group of connected piping. In this case, water is supplied through the connection pipe corresponding to the kitchen when the fire is recognized as a fire in the kitchen, and water is supplied through the connection pipe corresponding to the living room when the fire is recognized as a fire in the living room. By spraying the fog from the sprinkler included in the area where the fire occurs, other areas can be prevented from damages caused by the sprayed water.

As described above, the present invention is advantageous in that fire can be suppressed by using a small amount of water by suppressing fire by using mist spray, and fire can be extinguished even when a fire occurs in a place not exposed to water by the existing direct injection. In addition, the damage caused by water can be minimized by suppressing the fire by using a small amount of water. In addition, by providing a plurality of sprinklers capable of spraying mist at home, there is an advantage that the fire can be suppressed at the early stage by spraying mist from the adjacent sprinkler as well as the sprinkler installed in the area where the fire occurs.

Figure 5 illustrates a fire suppression system in accordance with another embodiment of the present invention. Hereinafter, a fire suppression system according to another embodiment of the present invention will be described in detail with reference to FIG.

As described above, FIG. 5 proposes a method of installing a plurality of connecting pipes in a house and supplying water to each connected connecting pipe. In this case, the sensing sensor is required to provide its own position information to the control module, and the control module supplies water to the corresponding connection pipe according to the provided location information.

FIG. 5 shows a house divided into a first area, a second area adjacent to the first area, and a third area adjacent to the second area, and the second area is located between the first area and the third area. That is, the house is arranged in the order of the first area, the second area, and the third area. If it is recognized that a fire has occurred in the first area, water is supplied to the connecting piping installed in the first area and the second area. When it is recognized that a fire has occurred in the third area, water is supplied to the connecting piping installed in the second area and the third area. Further, when it is recognized that a fire has occurred in the second area, water is supplied to the connecting piping installed in the first to third areas. As described above, the present invention supplies water to the connection pipe located in the area where the fire occurs and the adjacent area, and does not supply water to the connection pipe of the area located relatively far from the area where the fire occurred. In this case, set the time for supplying water to the connecting pipe located in the area where the fire occurred and the time for supplying water to the connecting pipe located in the area where the fire did not occur. That is, the time for supplying water to the connecting pipe located in the area where the fire occurs is relatively longer than the time for supplying water to the connecting pipe located in the area where no fire occurs.

Figure 6 shows a sprinkler according to an embodiment of the invention. Hereinafter, a sprinkler according to an embodiment of the present invention will be described in detail with reference to FIG.

6, in the sprinkler 100, a plurality of mist spray nozzles 300 are located on the coaxial core, and the blowing means 400 is formed in the periphery. The blowing means 400 is arranged so that the terminating end thereof is inclined at a predetermined angle so as to face the mist spraying nozzle 300. That is, the blowing means 400 positioned to the right with respect to the mist spraying nozzle 300 is formed to be inclined to the left, and the blowing means 400 located on the left side with respect to the mist spraying nozzle 300 is formed to be inclined to the right do. In the event of a fire, the particular blowing means is driven so that the mist sprayed from the mist spray nozzle is directed to the point where the fire occurred.

In other words, when a fire occurs from the left side based on the sprinkler, the ventilation means located on the right side of the sprinkler is driven to move the fog sprayed from the sprinkler to the fire occurrence area. In addition, when a fire occurs on the right side of the sprinkler, the left side blowing means is driven on the sprinkler so that the mist sprayed from the sprinkler moves to the fire occurrence area. As described above, according to the present invention, the blowing means is formed at at least two points spaced apart from each other by a predetermined distance on the basis of the sprinkler, and one of the blowing means is driven in consideration of the area where the fire occurs in the event of fire.

7 shows a sprinkler according to another embodiment of the present invention. Hereinafter, a sprinkler according to another embodiment of the present invention will be described in detail with reference to FIG.

According to Fig. 7, the sprinkler includes a direct injection nozzle, a mist injection nozzle, and a blowing means. Of course, other configurations than the above-described configuration can be included in the sprinkler proposed in the present invention.

The direct injection nozzle 500 injects water in the form of a water stream to the lower end. The direct injection nozzle 500 injects water to the lower end in accordance with the control command of the control module when a fire occurs at the lower end of the ceiling provided with the sprinkler.

The mist spray nozzle 300 emits water in the form of mist. The fog injection nozzle 300 is located around the direct injection nozzle. The mist spray nozzle 300 emits mist to the lower end according to a control command of the control module when a fire occurs on the side of the lower end rather than the bottom of the ceiling where the sprinkler is installed. More specifically, when a fire occurs in an area other than the area in which the direct injection nozzle 500 can inject the mist, the mist injection nozzle emits mist according to a control command of the control module.

The blowing means 400 is driven when the fog is injected through the mist injection nozzle under the control of the control module as shown in Fig. In other words, the blowing means does not drive when the water stream is injected through the direct injection nozzle. That is, when a water stream is injected through the direct injection nozzle, since a fire occurs at the lower end of the sprinkler as described above, there is no need to drive the blowing means.

However, when the fog is sprayed through the mist spray nozzle, it is not the case that a fire occurs at the lower end of the sprinkler. Therefore, driving of the blowing means is required, and driving of one of the at least two blowing means, So that the fog reaches quickly. As described above, according to the present invention, fire is rapidly suppressed by using a sprinkler including a direct injection nozzle and a mist injection nozzle. Especially when a fire occurs under the sprinkler, water is sprayed through the direct injection nozzle, In the event of a fire at a branch point, a fog spray is sprayed through a mist spray nozzle to pro- vide rapid fire suppression.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it will be understood by those of ordinary skill in the art that various changes in form and details may be made therein without departing from the scope of the present invention .

100: sprinkler 102: connection piping
104: Pump 106: Water tank
108: Control module 110: Humidity sensor
112: detection sensor 300: mist spray nozzle
400: blowing means 500: direct injection nozzle

Claims (5)

A water tank in which water supplied from the water pipe is stored;
A pump for supplying water stored in the water tank;
A connection pipe connected to the pump and supplied with water from the pump;
A sprinkler connected to the connection pipe and installed in the house, for spraying the supplied water with mist;
A control module for controlling driving of the pump;
And a sensor installed in the house to provide the measured temperature to the control module,
In the sprinkler,
At least two mist spray nozzles for spraying mist;
At least two blowing means formed on the outside of the mist spraying nozzle and inclined toward the mist spraying nozzle,
The control module includes:
And controlling the mist to be sprayed through the mist spray nozzle when the temperature provided from the detection sensor is equal to or higher than a set temperature,
And controls the blowing means of at least two of the blowing means to be driven such that the mist directed through the mist injection nozzle is directed in the direction in which the detection sensor is located.
delete delete delete The water treatment system according to claim 1, wherein the sprinkler includes a direct-injection nozzle for spraying water in a water-
The blowing means stops driving when water is sprayed in the shape of a water stream through the direct injection nozzle,
And controls to drive one of the at least two blowing means when the mist is injected through the mist injection nozzle.

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