KR102502989B1 - Springkler system for fire extinction - Google Patents

Abstract

Disclosed is a sprinkler system for fire extinguishing. According to one aspect of the present invention, the provided sprinkler system for the fire extinguishing comprises: a primary side pipe filled with a fire extinguishing water; a secondary side pipe; a plurality of first open type sprinkler heads coupled to the secondary side pipe and disposed in a protection zone; a temperature-sensitive automatic opening/closing valve including a shape memory alloy to automatically open and close according to an air temperature of the protection zone; and a simultaneous opening valve connecting the primary side pipe and the secondary side pipe, and opening and closing a flow path connecting the primary side pipe and the secondary side pipe according to opening and closing of the temperature-sensitive automatic opening/closing valve. Provided is the deluge sprinkler system for the fire extinguishing including the simultaneous opening valve.

Description

Fire sprinkler system {SPRINGKLER SYSTEM FOR FIRE EXTINCTION}

The present invention relates to a sprinkler system for fire suppression, and more particularly, to a sprinkler system for a fire extinguishing fire sprinkler system comprising a temperature sensitive automatic on/off valve and a simultaneous open valve interlocked therewith.

Fire extinguishing sprinkler systems can be largely classified into dry, wet, pre-action, negative pressure, and full-spreading types.

Among them, dry, wet, pre-actuated or negative pressure fire extinguishing sprinkler systems use closed sprinkler heads, which are problematic due to the high defect rate of closed sprinkler heads.

On the other hand, the sprinkler system for fire extinguishing of the simultaneous distribution type can be freed from the above problems because it uses an open type sprinkler head.

However, in the conventional sprinkler system for fire extinguishing, it is almost essential to use a fire detector and a solenoid valve to automatically control the simultaneous opening valve that connects the primary piping filled with fire extinguishing water and the secondary piping filled with outside air through an open sprinkler head. However, if there is a problem with the fire detector or solenoid valve or a problem with related electrical equipment, the entire system may not operate or malfunction.

In addition, the simultaneous opening valve has a first chamber connected to the primary side pipe, a second chamber connected to the secondary side pipe, and a third chamber connected to the solenoid valve, and a bypass is formed between the first chamber and the third chamber. A flow path is formed, and the flow path between the first chamber and the second chamber is generally opened and closed by a valve body. As a result, when the solenoid valve is closed, the valve body closes the flow path between the first chamber and the second chamber by the pressure of fire extinguishing water filled in the third chamber through the bypass flow path, whereas when the solenoid valve is open has a structure in which the valve body opens a flow path between the first chamber and the second chamber by the pressure of the fire extinguishing water filled in the first chamber while the fire extinguishing water filled in the third chamber is discharged to the outside.

However, when the solenoid valve is open, even if most of the fire extinguishing water supplied through the primary pipe flows to the secondary pipe, about 1% of the fire extinguishing water may continue to be discharged to the outside through the open solenoid valve. There was also a problem of loss of fire extinguishing water.

In addition, there was a problem in that the solenoid valve had to be manually operated to close the flow path between the first chamber and the second chamber after the fire suppression was completed.

Republic of Korea Patent Registration No. 10-1695430 (2017.01.11, Piston driven type simultaneous opening valve)

An embodiment of the present invention is a fire sprinkler system for fire suppression that includes a temperature sensitive automatic opening/closing valve that can operate automatically without using a fire detector and a solenoid valve and without external electricity supply and a simultaneous opening valve interlocked therewith. provides

According to one aspect of the present invention, the primary side pipe to be filled with fire extinguishing water; secondary side piping; a plurality of first open type sprinkler heads coupled to the secondary pipe and disposed in a protection zone; a temperature-sensitive automatic on-off valve containing a shape memory alloy to automatically open and close according to the air temperature of the protection zone; and a simultaneous opening valve connecting the primary side pipe and the secondary side pipe and opening and closing a flow path connecting the primary side pipe and the secondary side pipe according to the opening and closing of the temperature sensitive automatic on/off valve. system can be provided.

It may further include a second open type sprinkler head coupled to the temperature sensitive automatic opening/closing valve and disposed in the protection zone.

The temperature sensitive automatic opening/closing valve may include a first valve case having a first flow path therein connecting the simultaneous opening valve and the second open sprinkler head; a first valve body coupled to the first valve case and opening and closing the first flow path; and a shape memory spring made of a shape memory alloy interposed between the first valve case and the first valve body. It is deformed to open, but when the temperature is lower than a set temperature, the first valve body may be restored to its original state to close the first flow path.

The temperature-sensitive automatic on-off valve further includes a first return spring interposed between the first valve case and the first valve body, and the first return spring is configured to open the first valve when the first flow path is opened. When the shape memory spring is restored to its original state by being deformed by the main body, an elastic force may be provided to the first valve body so that the first valve body closes the first flow path.

The simultaneous opening valve is a second valve having a first chamber connected to the primary side pipe, a second chamber connected to the secondary side pipe, and a third chamber connected to the temperature sensitive automatic opening/closing valve formed therein. case; And a second valve body coupled to the second valve case to open and close a second flow path between the first chamber and the second chamber by a pressure difference between the first chamber and the third chamber, wherein the A bypass flow path connecting the first chamber and the third chamber may be provided.

The second valve body is coupled to the second valve case and includes a diaphragm separating the first chamber and the second chamber from the third chamber, and the second valve case is inside the second valve case. A dam protrudes from the lower surface toward the diaphragm to separate the first chamber and the second chamber from each other, and the second flow path is opened between the diaphragm and the dam when the diaphragm is deformed, The bypass passage may be formed in the form of a through hole in the diaphragm.

The simultaneous opening valve further includes a second return spring interposed between the second valve case and the diaphragm, and the second return spring is deformed by the diaphragm when the second passage is opened, An elastic force may be provided to the diaphragm so that the diaphragm closes the second flow path when the temperature sensitive automatic opening/closing valve is closed.

fire alarm; and a control unit generating a control signal to operate the fire alarm, wherein the simultaneous opening valve includes a reed switch coupled to an upper portion of the second valve case and driving the control unit; and a permanent magnet coupled to the diaphragm and approaching the reed switch by the diaphragm when the second passage is opened.

According to an embodiment of the present invention, the temperature-sensitive automatic on-off valve can replace a fire detector and a solenoid valve by automatically opening and closing according to the air temperature of the protection zone using a shape memory alloy and can operate without an external electricity supply. Therefore, problems caused by the use of conventional fire detectors and solenoid valves can be prevented.

In addition, unlike the solenoid valve, the temperature-sensitive automatic shut-off valve is placed in the protection area, and when the temperature-sensitive automatic shut-off valve is opened, the fire extinguishing water continuously discharged through the temperature-sensitive automatic shut-off valve can be used for fire suppression in the protection area. Therefore, it is possible to improve the conventional problem of loss of fire extinguishing water.

In addition, the temperature-sensitive automatic on-off valve can be automatically closed according to the temperature drop in the protection zone after fire suppression is completed, so the hassle of conventional manual operation can be eliminated, and in the event of re-ignition, it is re-operated, providing a semi-permanent can be used

1 is a view showing a fire extinguishing sprinkler system according to an embodiment of the present invention;
2 and 3 are views showing the simultaneous opening valve of FIG. 1 and an example of its operation,
4 and 5 are diagrams illustrating the temperature sensitive automatic on-off valve of FIG. 1 and an example of its operation.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

Terms used in the embodiments of the present invention may be interpreted as meanings that can be generally understood by those of ordinary skill in the art to which the present invention belongs, unless clearly defined otherwise, and only specific The examples are intended to be illustrative and are not intended to limit the present invention.

In this specification, the singular form will be considered to include the plural form as well, unless otherwise specified.

In addition, when a part is described as "including" a certain component, it means that the corresponding part may further include other components.

In addition, when a component is described as "on", it means above or below the corresponding component, and does not necessarily mean that it is located on the upper side relative to the direction of gravity.

Also, when a component is described as being “connected” or “coupled” to another component, that component is not only directly connected to or coupled to another component, but also indirectly through another component. It may also include the case of being connected or combined with.

In addition, although terms such as first and second may be used to describe a certain component, these terms are only used to distinguish the corresponding component from other components, and the essence or sequence of the corresponding component is determined by the term. or order, etc., is not intended to be limiting.

1 is a view showing a fire extinguishing sprinkler system according to an embodiment of the present invention, FIGS. 2 and 3 are views showing the simultaneous opening valve of FIG. 1 and an example of its operation, and FIGS. 4 and 5 are diagrams It is a drawing showing the temperature sensitive automatic on-off valve of 1 and an example of its operation.

1 to 5, the fire extinguishing sprinkler system 10 according to an embodiment of the present invention includes a primary pipe 110, a secondary pipe 120, a plurality of first open sprinkler heads 210, It may include a temperature sensitive automatic opening/closing valve 300 and a simultaneous opening valve 400, a connection pipe 130, an emergency operation pipe 140, a second open sprinkler head 220, and a manual opening/closing for emergency operation. A valve 500, a fire alarm 600 and/or a control unit 700 may be further included.

Fire extinguishing water may be filled in the primary side pipe 110 and may be connected to, for example, a water supply pipe. Therefore, it may become unnecessary to install a separate fire extinguishing tank. On the other hand, the fire extinguishing water filled in the primary pipe 110 may mean water, but is not necessarily limited thereto, and may mean a mixture of fire extinguishing agent (powder), carbon dioxide gas, or fire extinguishing agent (powder) and water. .

The secondary side pipe 120 is connected to the primary side pipe 110 through the simultaneous opening valve 400, and when the simultaneous opening valve 400 is opened, fire extinguishing water can be supplied through the primary side pipe 110.

The plurality of first open sprinkler heads 210 may be coupled to the secondary pipe 120 .

Accordingly, the secondary side pipe 120 may be filled with air introduced through the plurality of first open sprinkler heads 210 during normal times, that is, when the simultaneous opening valve 400 is closed.

The plurality of first open-type sprinkler heads 210 are disposed in the protection area (A), and when the simultaneous opening valve 400 is opened, the fire extinguishing water supplied through the secondary side pipe 120 can be sprayed to the protection area (A). there is.

The second open type sprinkler head 220 may be coupled to the temperature sensitive automatic opening/closing valve 300 and disposed in the protection area A.

Accordingly, the second open sprinkler head 220 can spray fire extinguishing water supplied through the temperature sensitive automatic opening/closing valve 300 to the protection area A when the temperature sensitive automatic opening/closing valve 300 is opened.

The temperature-sensitive automatic opening/closing valve 300 may be connected to the simultaneous opening valve 400 and disposed in the protection zone (A), and may include a shape memory alloy so as to be automatically opened and closed according to the air temperature of the protection zone (A). there is.

The temperature-sensitive automatic opening/closing valve 300 may be directly connected to the simultaneous opening valve 400 or may be connected to the simultaneous opening valve 400 through a connection pipe 130 .

The temperature-sensitive automatic on-off valve 300 may include a first valve case 310, a first valve body 320, and a shape memory spring 330, and may further include a first return spring 340. there is.

A first flow path 311 connecting the simultaneous opening valve 400 and the second open sprinkler head 220 may be formed inside the first valve case 310 .

For example, the connection pipe 130 may be coupled to one end of the first passage 311 and the second open sprinkler head 220 may be coupled to the other end of the first passage 311 .

The first valve body 320 may be coupled to the first valve case 310 to open and close the first flow path 311 .

For example, the first valve body 320 may be slidably coupled to the first valve case 310 .

The shape memory spring 330 may be interposed between the first valve case 310 and the first valve body 320, and is made of a shape memory alloy, and when the temperature exceeds a predetermined temperature, the first valve body 320 is removed. Deformed to open the first flow path 311, for example, when the length is increased and becomes less than a set temperature, the first valve body 320 returns to its original state to close the first flow path 311, for example, the length is reduced. can

The first return spring 340 may be interposed between the first valve case 310 and the first valve body 320, and is deformed by the first valve body 320 when the first flow path 311 is opened. For example, when the shape memory spring 330 is restored to its original state by being compressed, an elastic force may be provided to the first valve body 320 so that the first valve body 320 closes the first flow path 311 .

That is, when the shape memory spring 330 is coupled to the first valve case 310 and the first valve body 320, the opening and closing of the first flow path 311 may be performed only by the shape memory spring 330, but the first flow path 311 may be opened and closed. Due to the existence of the return spring 340, perfect closing of the first flow path 311 may be guaranteed.

The simultaneous opening valve 400 may connect the primary side pipe 110 and the secondary side pipe 120, and may also be connected to the temperature sensitive automatic opening/closing valve 300 through the connecting pipe 130, for example.

The simultaneous opening valve 400 may have a flow path connecting the primary side pipe 110 and the secondary side pipe 120, and the corresponding flow path can be opened and closed according to the opening and closing of the temperature-sensitive automatic on-off valve 400. .

The simultaneous opening valve 400 may include a second valve case 410 and a second valve body 420, and may include a second return spring 430, a reed switch 440 and/or a permanent magnet 450. may include more.

A first chamber 411 , a second chamber 412 , and a third chamber 413 may be formed inside the second valve case 410 .

The first chamber 411 may be connected to the primary side pipe 110, the second chamber 412 may be connected to the secondary side pipe 120, and the third chamber 413 may be a temperature sensitive automatic opening/closing valve ( 300) may be connected.

For example, the primary side pipe 110 may be coupled to one side of the second valve case 410, and the secondary side pipe 120 may be coupled to the other side of the second valve case 410. A connection pipe 130 may be coupled to an upper portion of the valve case 410 .

The second valve body 420 is coupled to the second valve case 410, and the pressure difference between the first chamber 411 and the third chamber 413 causes a gap between the first chamber 411 and the second chamber 412. The second flow path 414 of can be opened and closed.

The second valve body 420 may include a diaphragm coupled to the second valve case 410 to separate the first chamber 411 and the second chamber 412 from the third chamber 413 . An edge of the diaphragm may be fixed to the second valve case 410, the first chamber 411 and the second chamber 412 may be disposed below the diaphragm, and the third chamber 413 may be a diaphragm. It can be placed on the upper side of the frame. For example, the second valve case 410 includes a case body forming the first chamber 411 and the second chamber 412, and a case detachably coupled to the case body and forming the third chamber 413. A cover may be included, and an edge of the diaphragm may be fixed between the case body and the case cover. In addition, a dam 415 protruding toward the diaphragm is formed on the inner lower surface of the second valve case 410 to separate the first chamber 411 and the second chamber 412 from each other.

Therefore, when the pressure in the first chamber 411 is greater than the pressure in the third chamber 413, the central portion of the diaphragm is deformed or curved toward the third chamber 413, and the first chamber is formed between the diaphragm and the dam 415. The second flow path 414 connecting the 411 and the second chamber 412 may be formed or opened, and when the pressure of the third chamber 413 is greater than the pressure of the first chamber 411, the dam 415 close to the second flow path 414 can be closed.

The simultaneous opening valve 400 may include a bypass passage 421 connecting the first chamber 411 and the third chamber 413 .

The bypass passage 421 may be formed in the form of a through hole in the diaphragm, but is not necessarily limited thereto, and the bypass passage 421 may be formed in the second valve case 410 .

However, forming the bypass passage 421 on the diaphragm may be more preferable in terms of valve manufacturing and maintenance.

The second return spring 430 may be interposed between the inner upper surface of the second valve case 410 and the diaphragm, and when the second flow path 414 is opened, it is deformed, for example, compressed by the diaphragm, and the temperature is reduced. When the sensitive automatic opening/closing valve 300 is closed, an elastic force may be provided to the diaphragm so as to close the second flow path 414 . That is, opening and closing of the second flow path 414 may be performed by deformation of the diaphragm, and the diaphragm may be deformed only by a pressure difference between the first chamber 411 and the third chamber 413, but the second return flow path 414 may be opened and closed. By receiving the elastic force from the spring 430, the second passage 414 may be more completely closed.

The reed switch 440 may be coupled to an upper portion of the second valve case 410 to drive the control unit 700 .

Specifically, the reed switch 440 may be connected to the control unit 700, and the electrical contact of the reed switch 440 may be normally off, but as will be described later, when the permanent magnet 450 approaches When turned on, the control unit 700 can be operated.

The permanent magnet 450 is coupled to the central portion of the diaphragm and can approach the reed switch 440 by means of the diaphragm that is upwardly curved toward the third chamber 413 when the second passage 414 is opened.

The manual opening/closing valve 500 for emergency operation may be installed in the emergency operation pipe 140 branched off from the connection pipe 130 .

Therefore, the user can operate the fire-extinguishing sprinkler system 10 by manually opening the manual opening/closing valve 500 for emergency operation, thereby actively coping with emergency situations.

The fire alarm 600 may generate sound or light required for fire alarm, and the control unit 700 is driven by the reed switch 440 as described above to generate a control signal necessary for the operation of the fire alarm 600. can do. However, it is not necessarily limited thereto, and the control unit 700 may be driven by a switch installed in the secondary side pipe 120 and detecting water flow.

On the other hand, in the case of using a conventional solenoid valve, there is a problem in that water hammer occurs in the process of suddenly opening and closing the simultaneous opening valve, but the temperature sensitive automatic opening and closing valve 300 and the simultaneous opening valve 400 interlocked therewith ), the temperature-sensitive automatic opening/closing valve 300 and the simultaneous opening valve 400 extending thereto can be opened and closed at a gentle speed due to the thermal expansion of the shape memory spring 330, so that water hammer action does not occur. There may also be some advantages.

Although the above has been described with a focus on preferred embodiments of the present invention, this is only an example and does not limit the present invention. Those skilled in the art to which the present invention pertains can modify and change the embodiments in various ways by adding, changing, deleting, or adding components within the scope that does not deviate from the spirit of the present invention described in the claims. It will be possible, and this will also be said to be included within the scope of the present invention.

10: sprinkler system for fire extinguishing 110: primary side piping
120: secondary side piping 130: connection piping
140: piping for emergency operation 210: first open sprinkler head
220: second open sprinkler head 300: temperature-sensitive automatic on-off valve
310: first valve case 311: first flow path
320: first valve body 330: shape memory spring
340: first return spring 400: simultaneous opening valve
410: second valve case 411: first chamber
412: second chamber 413: third chamber
414: second flow 415: dam
420: second valve body 421: bypass flow path
430: second return spring 440: reed switch
450: permanent magnet 500: manual on-off valve for emergency operation
600: fire alarm 700: control unit

Claims (8)

Primary side piping filled with fire extinguishing water;
secondary side piping;
a plurality of first open type sprinkler heads coupled to the secondary pipe and disposed in a protection zone;
a temperature-sensitive automatic on-off valve containing a shape memory alloy to automatically open and close according to the air temperature of the protection zone;
a simultaneous opening valve connecting the primary side pipe and the secondary side pipe, and opening and closing a flow path connecting the primary side pipe and the secondary side pipe according to the opening and closing of the temperature sensitive automatic opening/closing valve; and
A fire extinguishing sprinkler system comprising a second open sprinkler head coupled to the temperature sensitive automatic opening and closing valve and disposed in the protection zone. delete According to claim 1,
The temperature sensitive automatic opening and closing valve,
a first valve case formed therein with a first passage connecting the simultaneous opening valve and the second open sprinkler head;
a first valve body coupled to the first valve case and opening and closing the first flow path; and
A shape memory spring made of a shape memory alloy interposed between the first valve case and the first valve body,
The shape memory spring is deformed so that the first valve body opens the first flow path when the temperature is higher than a predetermined temperature, and when the temperature is lower than a predetermined temperature, the first valve body is restored to its original state to close the first flow path. for sprinkler systems. According to claim 3,
The temperature sensitive automatic opening and closing valve,
Further comprising a first return spring interposed between the first valve case and the first valve body,
The first return spring is deformed by the first valve body when the first flow path is opened, and when the shape memory spring is restored to its original state, the first valve body is attached to the first valve body to close the first flow path. A fire extinguishing sprinkler system that provides spring force. According to claim 1,
The simultaneous opening valve,
a second valve case in which a first chamber connected to the primary side pipe, a second chamber connected to the secondary side pipe, and a third chamber connected to the temperature sensitive automatic opening/closing valve are formed therein; and
A second valve body coupled to the second valve case and opening and closing a second flow path between the first chamber and the second chamber by a pressure difference between the first chamber and the third chamber;
A fire extinguishing sprinkler system comprising a bypass passage connecting the first chamber and the third chamber. According to claim 5,
The second valve body includes a diaphragm coupled to the second valve case to separate the first chamber and the second chamber from the third chamber,
The second valve case has a dam protruding toward the diaphragm from an inner lower surface of the second valve case to separate the first chamber and the second chamber from each other,
The second passage is opened between the diaphragm and the dam when the diaphragm is deformed,
The bypass flow path is formed in the form of a through hole in the diaphragm. According to claim 6,
The simultaneous opening valve,
Further comprising a second return spring interposed between the second valve case and the diaphragm,
The second return spring is deformed by the diaphragm when the second flow path is opened, and provides elastic force to the diaphragm so that the diaphragm closes the second flow path when the temperature sensitive automatic opening/closing valve is closed. Fire sprinkler system. According to claim 6,
fire alarm; and
Further comprising a control unit for generating a control signal to operate the fire alarm,
The simultaneous opening valve,
a reed switch coupled to an upper portion of the second valve case and driving the control unit; and
and a permanent magnet coupled to the diaphragm and approaching the reed switch by the diaphragm when the second passage is opened.

Images