KR102544030B1 - Automatic fire extinguisher for small space - Google Patents

Abstract

The present invention relates to a small space automatic fire extinguishing device. The present invention is a fire extinguishing agent storage container (200) in which a fire extinguishing agent is stored and a blocking film (250) is installed at the inlet (220), and an operating unit for spraying the fire extinguishing agent stored in the fire extinguishing agent storage container (200) in the event of a fire. (100), wherein the operation unit (100) includes a heat sensing glass valve (60) that is damaged by the heat of a fire; a hitting member 40 that strikes and destroys the blocking film 250 when the heat-sensing glass valve 60 is damaged; and an elastic body 50 providing a forward force to the striking member 40, wherein the elastic body 50 is an automatic fire extinguishing device for a small space installed between the heat-sensing glass valve 60 and the striking member 40. provides The present invention is installed in a small space such as a switchboard or an electric panel box, and in the event of a fire, the fire extinguishing agent can be sprayed in an instant to extinguish the fire at an early stage, and it is structurally compact, so it has the effect of occupying less installation space. .

Description

Small space automatic fire extinguishing device {AUTOMATIC FIRE EXTINGUISHER FOR SMALL SPACE}

The present invention relates to an automatic fire extinguishing device in a small space, and more particularly, installed in a small space such as a switchboard or an electric panel box, in the event of a fire, it can instantly extinguish the fire by spraying an extinguishing agent in an instant, structurally It relates to a small space automatic fire extinguishing device that is compact and can occupy a small installation space.

The fire extinguishing system extinguishes the fire by injecting an extinguishing agent through a spray nozzle in the event of a fire. Fire extinguishing devices can be classified according to the type of fire extinguishing agent, for example, a water fire extinguisher that sprays water through compressed air, a CO ₂ fire extinguisher that sprays carbon dioxide (CO ₂ ), and a powder fire extinguisher that sprays powder such as sodium bicarbonate. , and foam fire extinguishers (or foam fire extinguishers) that spray foam. In addition, fire extinguishing devices are classified as manual and automatic depending on the operation method, and in the case of power plants or factories, automatic fire extinguishing devices (or automatic fire extinguishing equipment) are mainly installed.

The automatic fire extinguishing device automatically sprays the fire extinguishing agent by opening the valve by heat detection or by an electric signal in the event of a fire. For example, Korean Utility Model Registration No. 20-0457601, Korean Utility Model Registration No. 20-0459249, Korean Patent Registration No. 10-1757760, and Korean Patent Publication No. 10-2017-0107728 disclose technologies related to the above. this is presented.

In addition, in most cases, a heat-sensing automatic fire extinguishing device is installed with a heat-sensing glass valve (glass tube) that is damaged by the heat of a fire. In general, a heat-sensing automatic fire extinguishing device includes an extinguishing agent storage container with a barrier (copper plate) installed at the entrance, a heat-sensing glass valve (glass tube) that is damaged by the heat of the fire when a fire occurs, and when the heat-sensing glass valve is damaged, It includes a striking member that strikes and destroys the blocking film, and an elastic body (spring) that provides a forward force to the striking member. In the case of such a heat-sensing automatic fire extinguishing device, when the heat-sensing glass valve is damaged by the heat of fire, the striking member moves forward by the elastic force of the elastic body (spring) to destroy (tear) the blocking film, and by breaking the blocking film It operates in a structure in which the fire extinguishing agent stored in the fire extinguishing agent storage container is sprayed.

The heat-sensing automatic fire extinguishing device can be manufactured in a small size as well as in a general building and is installed in a small space such as a switchboard or an electric panel box in an electrical room. For example, Korean Patent Registration No. 10-1900874 and Korean Patent Registration No. 10-2048799 suggest an automatic fire extinguishing device installed in a small space.

However, the heat-sensing automatic fire extinguishing device according to the prior art has the following problems.

In general, as described above, a heat-sensing automatic fire extinguishing device provides forward force to a striking member that destroys a barrier film installed in a fire extinguishing agent storage container, a heat-sensing glass valve (glass tube) that is damaged by the heat of a fire, and the striking member. In the case of the heat-sensing automatic fire extinguishing device according to the prior art in the arrangement structure (installation position) between these components, the heat-sensing glass valve (glass tube) is It is arrange|positioned between elastic bodies. At this time, when a fire occurs, glass fragments are generated as the heat-sensing glass valve is damaged. In some cases, these glass fragments remain between the impact member and the elastic body to hinder the forward force of the impact member. Accordingly, since the forward force of the striking member is weak, the shielding film is not instantly destroyed, making it difficult to extinguish the fire at an early stage.

In addition, the heat-sensing automatic fire extinguishing device according to the prior art has a separate member for supporting each other between the heat-sensing glass valve and the elastic body as well as between the heat-sensing glass valve and the striking member due to the above arrangement structure. being installed As a result, there is a problem in that the number of parts is large and the volume is large, occupying a lot of installation space in a small space such as a switchboard.

In addition, as described above, there is a blocking film that can be destroyed (torn) by a striking member at the entrance of the fire extinguishing agent storage container, and conventionally, copper plate (Cu) is mainly used as the blocking film. However, the shielding film made of copper plate (Cu) has poor sealing properties. In particular, when a long period of time has passed, there is a problem in that a fine gap is generated at the joint between the barrier film and the inlet, and leakage of the fire extinguishing agent occurs through this gap. Accordingly, the conventional fire extinguishing device must be periodically checked for leaks and replaced. Otherwise, the discharge amount of the fire extinguishing agent is reduced in the event of a fire due to leakage of the fire extinguishing agent (lower pressure in the storage container due to gas leakage), resulting in a fire may be difficult to suppress initially.

Korean Utility Model Registration No. 20-0457601 Korea Utility Model Registration No. 20-0459249 Korean Patent Registration No. 10-1757760 Korean Patent Publication No. 10-2017-0107728 Korean Patent Registration No. 10-1900874 Korean Patent Registration No. 10-2048799

Therefore, the present invention is a heat-sensing automatic fire extinguishing device, which is installed in a small space, such as a switchboard or an electric panel box, can instantly extinguish a fire by spraying an extinguishing agent in an instant when a fire occurs, and is structurally compact. (Compact) The purpose is to provide an automatic fire extinguishing device that can occupy less installation space.

In addition, another object of the present invention is to provide an automatic fire extinguishing device capable of preventing leakage of fire extinguishing agents and improving durability by improving sealing properties and chemical resistance of a barrier film.

In order to achieve the above object, the present invention,

A fire extinguishing agent storage container in which the fire extinguishing agent is stored and a barrier is installed at the entrance;

Including an operation unit for spraying the fire extinguishing agent stored in the fire extinguishing agent storage container in the event of a fire,

The operating unit is

A heat-sensing glass valve broken by the heat of a fire;

a hitting member that strikes and destroys the blocking film when the heat-sensing glass valve is damaged; and

Including an elastic body that provides a forward force to the striking member,

The elastic body provides an automatic fire extinguishing device installed between the heat sensing glass valve and the striking member.

According to a preferred embodiment of the present invention, the operation unit,

An outer case coupled to the fire extinguishing agent storage container;

a first cylinder installed inside the outer case;

a second cylinder installed inside the first cylinder;

a striking member that destroys a barrier installed at the entrance of the fire extinguishing agent storage container in the event of a fire;

a first elastic body installed inside the first cylinder, between an inner surface of the upper plate of the first cylinder and an outer surface of the upper plate of the second cylinder, and allowing the first cylinder to move when a fire occurs;

a second elastic body installed inside the second cylinder, between an inner surface of the upper plate of the second cylinder and an upper outer surface of the striking member, and providing forward force to the striking member in case of fire;

a heat-sensing glass valve installed inside the upper end of the outer case, one side of which is in close contact with the outer surface of the upper plate of the first cylinder; and

and a ball valve installed in the insertion groove of the striking member and supported by a lower end of the first cylinder to lock the striking member.

At this time, the operation unit moves the first cylinder when the heat sensing glass valve is damaged in the event of a fire, and the ball valve is separated from the insertion groove by the movement of the first cylinder, and the ball valve is separated from the ball valve. As a result, the striking member moves forward, and the blocking film is destroyed by the forward movement of the striking member, so that the fire extinguishing agent is sprayed.

In addition, the outer case includes a ball seating portion in which the ball valve is seated away from the insertion groove; a close contact part installed below the ball seating part and in close contact with the blocking film; and a cylinder stopper installed on the upper side of the ball seat and supporting the first cylinder.

In addition, according to a preferred embodiment of the present invention, the blocking film includes a substrate layer composed of a metal thin film, and a sealing layer formed on at least one surface of the substrate layer. At this time, the sealing layer has sealing properties and chemical resistance.

According to the present invention, it is installed in a small space, such as a switchboard or an electric panel box, for example, and when a fire occurs, the fire extinguishing agent can be sprayed in an instant to extinguish the fire at an early stage, and it is structurally compact so that it can be stored in a small space. has the effect of occupying less installation space.

In addition, according to the present invention, the barrier film has excellent sealing properties and chemical resistance, so that leakage of the fire extinguishing agent is prevented and durability is improved.

1 is an exploded perspective view of an automatic fire extinguishing device according to an embodiment of the present invention.
2 is a cross-sectional configuration view showing an automatic fire extinguishing device according to an embodiment of the present invention before operation.
3 is a cross-sectional configuration view showing an automatic fire extinguishing device according to an embodiment of the present invention after operation.
4 is a cross-sectional configuration diagram of a blocking film constituting an automatic fire extinguishing device according to an embodiment of the present invention.

The term "and/or" used in the present invention is used to mean including at least one or more of the elements listed before and after. As used herein, the term "one or more" means one or a plurality of two or more. Terms such as "first", "second", "one side" and "other side" used in the present invention are used to distinguish one component from other components, and each component corresponds to the above terms. is not limited by

The terms "formed on", "formed on the upper (upper) side", "formed on the lower (lower side)", "installed on", "installed on the upper (upper side)" and "lower (lower side)" are used in the present invention. "Installed in" does not mean that the components are formed (installed) in direct contact, but also includes the meaning that other components are further formed (installed) between the components. For example, "formed on" and "installed on" mean that the second component is formed (installed) by directly contacting the first component, as well as the first component and the second component. It includes the meaning that a third component can be further formed (installed) between the elements.

The present invention is a heat-sensing automatic fire extinguishing device. Compared to the prior art, the arrangement structure and operation structure between components are improved to have a compact configuration, so that when a fire occurs, an extinguishing agent is instantly sprayed to extinguish the fire at the beginning. It can suppress and is structurally compact to provide an automatic fire extinguishing device that takes up little installation space. The automatic fire extinguishing device according to the present invention may be installed in a small space, for example, in a small space such as a switchboard installed in an electrical room in a factory or an electrical panel box of various equipment.

Hereinafter, embodiments of the present invention will be described with reference to the accompanying drawings. BRIEF DESCRIPTION OF THE DRAWINGS The accompanying drawings illustrate exemplary embodiments of the present invention, which are provided merely to aid in understanding the present invention. In addition, in the accompanying drawings, the thickness may be enlarged to clearly represent each layer and region, and the scope of the present invention is not limited by the thickness, size, and/or ratio shown in the drawings. In describing the embodiments of the present invention, detailed descriptions of known general-purpose functions and/or configurations are omitted.

1 is an exploded perspective view of an automatic fire extinguishing device according to an embodiment of the present invention, and FIGS. 2 and 3 are cross-sectional views of the automatic fire extinguishing device according to an embodiment of the present invention. Figure 2 is a state before operation, Figure 3 is a state after operation.

1 to 3, the automatic fire extinguishing device according to the present invention is a heat-sensing automatic fire extinguishing device, and includes a fire extinguishing agent storage container 200 in which a fire extinguishing agent is stored, and stored in the fire extinguishing agent storage container 200 in the event of a fire. It includes an operation unit 100 that allows the fire extinguishing agent to be sprayed.

The fire extinguishing agent storage container 200 includes a blocking film 250 installed at the inlet 220. According to a specific embodiment, the fire extinguishing agent storage container 200 is formed on the storage container body 210 and the upper end of the storage container body 210, and has a diameter smaller than the diameter (outer diameter) of the storage container body 210 ( It includes an inlet 220 having an outer diameter) and a blocking film 250 installed in the inlet 220. The blocking film 250 seals the inlet 220 to prevent the outflow of the fire extinguishing agent stored in the storage container body 210.

The fire extinguishing agent is not particularly limited, as long as it has a fire extinguishing function (fire suppression function). The fire extinguishing agent may be selected from those commonly used, and may include, for example, CO ₂ , pentafluoroethane, hexafluoropropane, and/or NOVEC-1230 as a main component.

The operating unit 100 includes a heat-sensing glass valve 60 that is damaged by the heat of a fire as usual, and a striking member 40 that strikes and destroys the barrier film 250 when the heat-sensing glass valve 60 is damaged. And, it includes an elastic body 50 for providing a forward force to the striking member 40. At this time, according to the present invention, the elastic body 50 is installed between the heat sensing glass valve 60 and the striking member 40. Specifically, according to the present invention, in the arrangement structure (installation position) of the components constituting the operation unit 100, as in the prior art, the elastic body 50, the heat sensing glass valve 60, and the striking member 40 The elastic body 50 is installed between the heat-sensing glass valve 60 and the impact member 40, and as shown in FIGS. 1 to 3, the heat-sensing glass valve 60, The elastic body 50 and the striking member 40 are arranged in the order of arrangement.

According to the present invention, due to the above arrangement structure, even if glass fragments are generated due to breakage of the thermal sensing glass valve 60 in the event of a fire, the glass fragments do not hinder the forward force of the striking member 40 . Specifically, since the heat-sensing glass valve 60 is not disposed between the impact member 40 and the elastic body 50, even if glass fragments are generated by the damage of the heat-sensing glass valve 60, the impact member 40 There are no glass fragments between the and the elastic body 50. Accordingly, the elastic force (restoring force) of the elastic body 50 is transmitted to the striking member 40 as it is without being hindered by the glass fragments, so that the striking member 40 has a strong forward force. This eventually destroys the blocking film 250 in an instant, enabling initial suppression of the fire.

In addition, as shown in FIGS. 2 and 3, the striking member 40 and the elastic body 50, 52 without a separate member between the striking member 40 and the elastic body 50, 52 may be arranged in a direct contact structure. Accordingly, it has a compact structure with fewer parts than the prior art, which in turn has the advantage of occupying less installation space in a small space because the volume of the automatic fire extinguishing device is reduced.

According to a preferred embodiment of the present invention, the operation unit 100 has the construction and operation structure described below. Each component of the operation unit 100 described below may be made of a metal material, a synthetic resin material, or a combination thereof.

1 to 3, according to a preferred embodiment of the present invention, the operation unit 100 includes an outer case 10 coupled to the fire extinguishing agent storage container 200, and the inside of the outer case 10 The first cylinder 20 installed in the first cylinder 20, the second cylinder 30 installed inside the first cylinder 20, and the blocking film 250 installed at the inlet 220 of the fire extinguishing agent storage container 200 in case of fire. ) A striking member 40 for destroying, the first elastic bodies 50 and 51 installed inside the first cylinder 20, and the second elastic body 50 installed inside the second cylinder 30 (52), a heat sensing glass valve (60) installed inside the upper end of the outer case (10), and a ball valve (70) installed in the insertion groove (42) of the striking member (40).

The outer case 10 has, for example, a circular cross section, and its lower end 11 is coupled to the inlet 220 of the fire extinguishing agent storage container 200. The outer case 10 and the inlet 220 are screwed together, for example. A first space 12 is formed inside the upper end of the outer case 10, and a heat sensing glass valve 60 that is damaged by heat is installed in the first space 12. In addition, a plurality of through holes 13a are formed in the upper wall 13 of the outer case 10 . Heat generated in the event of a fire can be quickly transferred to the heat-sensing glass valve 60 through the through hole 13a. An outlet hole 16a is formed at the center and/or bottom of the outer case 10, and the fire extinguishing agent can flow out from the inside of the outer case 10 through the outlet hole 16a in case of fire. . In the drawing, a state in which a plurality of outlet holes 16a are formed in the lower wall 16 of the outer case 10 is illustrated.

In addition, the outer case 10 has a valve support portion 14 formed below the first space 12 and a second space 15 formed below the valve support portion 14 . A through hole 14a is formed in the longitudinal direction at the center of the valve support 14, and one side 61 of the heat sensing glass valve 60 is installed through the through hole 14a. At this time, one side 61 of the heat sensing glass valve 60 passes through the through hole 14a and then adheres to the outer surface 21 of the top plate of the first cylinder 20 . In the second space 15, the first cylinder 20, the second cylinder 30, the impact member 40, the elastic bodies 50, 51, 52, the ball valve 70, and the like are embedded.

In addition, the outer case 10 may include a ball seating portion 17 installed on the lower wall 16 and a close contact portion 18 installed below the ball seating portion 17 . The ball seating portion 17 and the close contact portion 18 may protrude from the bottom wall 16 toward the second space 15 and be integrally formed. At this time, the ball valve 70 separated into the insertion groove 42 of the striking member 40 is seated in the ball seating portion 17 . The contact portion 18 adheres to the blocking film 250 . When the outer case 10 and the inlet 220 are coupled, the close contact portion 18 presses and adheres the blocking film 250 to the inlet 220 to improve sealing between the blocking film 250 and the inlet 220. .

In addition, the outer case 10 may further include a cylinder stopper 19 installed on the upper side of the ball seating portion 17 . The cylinder stopper 19 supports the first cylinder 20 and prevents the first cylinder 20 from moving further downward. Specifically, the cylinder stopper 19 adheres to the rim portion 29 formed at the lower end of the first cylinder 20 to support the first cylinder 20 . The cylinder stopper 19 may be integrally formed with the wall 16 and/or the ball seating portion 17, or may be configured as a separate member and installed on the upper side of the ball seating portion 17 through adhesion or welding. there is.

The first cylinder 20 has, for example, a cylindrical shape, which is inserted and installed inside the outer case 10. The first cylinder 20 has, for example, a cylindrical body and an upper plate formed on the upper portion of the body. This first cylinder 20 can move up and down inside the outer case 10 . A rim portion 29 protruding outward is formed at the lower end of the first cylinder 20 . As described above, one side 61 of the thermal sensing glass valve 60 is in close contact with the outer surface 21 of the top plate of the first cylinder 20, and the outer surface 29 of the first cylinder 20 is The cylinder stopper 19 formed on the case 10 is in close contact.

In addition, first elastic bodies 50 and 51 are inserted and installed inside the first cylinder 20, and the first elastic bodies 50 and 51 are contracted (compressed) before operation (before a fire occurs). ) is installed inside the first cylinder 20. In addition, the lower end 27 of the first cylinder 20 is in close contact with the ball valve 70. Accordingly, the ball valve 70 is installed in the insertion groove 42 of the striking member 40, but is supported by the lower end 27 of the first cylinder 20 and is not separated from the insertion groove 42. don't

The second cylinder 30 has, for example, a cylindrical shape, and is inserted and installed into the first cylinder 20 . The second cylinder 30 has, for example, a cylindrical body and an upper plate formed on the upper portion of the body. This second cylinder 30 is fixed. For example, the second cylinder 30 may be connected to the outer case 10 and the fixing part 35 and fixed to the outer case 10 . The fixing part 35 may be an extension member integrally protruding from the outer surface of the main body of the second cylinder 30 or may be coupled to the outer surface of the main body of the second cylinder 30 through bonding or welding as a separate member.

In addition, a slit hole 25 having a predetermined length may be formed in the first cylinder 20, and a fixing hole 15a may be formed in the outer case 10. The fixing part 35 may pass through the slit hole 25 of the first cylinder 20 and then be fitted into the fixing hole 15a of the outer case 10 . Accordingly, the second cylinder 30 is fixed to the outer case 10 via the fixing part 35 . At this time, even if the fixing part 35 passes through the slit hole 25 of the first cylinder 20, as shown in the drawing, the slit hole 25 has a predetermined vertical length, so that the first cylinder 20 ) can move up and down.

In addition, as shown in FIG. 2 (before operation), the fixing part 35 adheres to and supports the upper end of the slit hole 25, so even if the cylinder stopper 19 is not installed, the first cylinder 20 No more moving downwards. Therefore, the first cylinder 20 is no longer moved downward by the fixing part 35 and the slit hole 25 before operation (before a fire occurs), and moves upward during operation (when a fire occurs). this is possible In addition, the second cylinder 30 is fixed to the outer case 10 through the fixing part 35 .

The striking member 40 destroys the blocking film 250 installed at the inlet 220 of the fire extinguishing agent storage container 200 when a fire occurs. The striking member 40 is installed below the second elastic bodies 50 and 52. Specifically, one side (upper side) of the striking member 40 is inserted into the second cylinder 30 together with the second elastic bodies 50 and 52 before operation, and the upper outer surface 43 (see FIG. 3) It adheres to the lower ends of the second elastic bodies 50 and 52. In addition, an insertion groove 42 into which the ball valve 70 is inserted and installed is formed at approximately the center of the striking member 40 . The insertion groove 42 has, for example, a substantially U-shaped, C-shaped or U-shaped shape. At this time, the insertion groove 42 may have an inclined surface 42a formed at its lower end. The inclined surface 42a facilitates separation of the ball valve 70 when the fire extinguishing device operates (when a fire occurs).

The elastic body 50 is installed between the heat-sensing glass valve 60 and the impact member 40, and according to the embodiment of the present invention, the first elastic body 50, 51 and the first elastic body 50 ( 51). For the elastic bodies 50, 51, and 52, for example, springs may be used.

The first elastic body 50, 51 is installed inside the first cylinder 20, which is the inner surface of the top plate 22 (see FIG. 3) of the first cylinder 20 and the second cylinder 30. It is installed between the top plate outer surface 32 (see FIG. 3). The first elastic bodies 50 and 51 are installed inside the first cylinder 20 in a compressed (contracted) state. The first elastic bodies 50 and 51 elastically move the first cylinder 20 when a fire occurs. That is, as shown in FIG. 3 , when the heat sensing glass valve 60 is damaged in the event of a fire, the first cylinder 20 is moved upward by the restoring force of the first elastic bodies 50 and 51 .

The second elastic bodies 50 and 52 are installed inside the second cylinder 30, which are the inner surface of the upper plate 33 of the second cylinder 20 (see FIG. 3) and the upper part of the striking member 40. It is installed between the outer surface 43 (see FIG. 3). The second elastic bodies 50 and 52 are installed inside the second cylinder 30 in a compressed (contracted) state. These second elastic bodies 50 and 52 provide forward force to the striking member 40 when a fire occurs. That is, as shown in FIG. 3, when the first cylinder 20 is moved upward and the ball valve 70 is separated from the insertion groove 42 in the event of a fire, the restoring force of the second elastic bodies 50 and 52 As a result, the striking member 40 advances downward to destroy (tear or pierce) the blocking film 250.

As mentioned above, the thermal sensing glass valve 60 is installed inside the top of the outer case 10, and one side 61 is attached to the outer surface 21 of the top plate of the first cylinder 20 (see FIG. 2). It sticks. The heat-sensing glass valve 60 is not particularly limited as long as it can be damaged by the heat of a fire, and a commonly used one may be used. The thermal sensing glass valve 60 may include, for example, a glass tube and a thermal expansion material filled in the glass tube.

As mentioned above, the ball valve 70 is installed in the insertion groove 42 of the impact member 40, and is supported by the lower end 27 of the first cylinder 20. The ball valve 70 locks the striking member 40 before the fire extinguishing device operates. Specifically, referring to FIG. 2, the ball valve 70 is in close contact with and supported by the lower end 27 of the first cylinder 20 before the fire extinguishing device operates, so that the insertion groove 42 of the striking member 40 ) does not deviate. Due to the locking action of the ball valve 70, the striking member 40 does not move forward even when the elastic force (restoring force) of the second elastic bodies 50 and 52 acts. And when a fire occurs, when the ball valve 70 is separated from the insertion groove 42 and the locking action is released, the striking member 40 moves forward by the elastic force (restoring force) of the second elastic bodies 50 and 52. . After the ball valve 70 is separated from the insertion groove 42, it falls and is seated on the ball seat 17.

The ball valve 70 has a spherical shape, and a heavy material selected from metal or ceramic materials may be used. In addition, according to another embodiment of the present invention, a third elastic body (not shown) may be installed in the insertion groove 42 . The third elastic body is for facilitating separation of the ball valve 70 from the insertion groove 42 by elastically pushing the ball valve 70 when the outer case 10 is moved upward in the event of a fire. , which may be selected from, for example, springs or rubber materials. In addition, a portion corresponding to 1/3 to 2/3 of the diameter of the ball valve 70 may be inserted and installed into the insertion groove 42.

In the automatic fire extinguishing device according to the present invention described above, when the heat-sensing glass valve 60 is damaged in the event of a fire, the first cylinder 20 is moved, and by the movement of the first cylinder 20, the ball The valve 70 is separated from the insertion groove 42. In addition, when the ball valve 70 is separated, the striking member 40 advances, and the blocking film 250 is destroyed by the forward movement of the striking member 40, thereby automatically injecting the fire extinguishing agent. A detailed operation process of the automatic fire extinguishing device according to the present invention shown in FIGS. 1 to 3 will be described.

When a fire breaks out, the heat-sensing glass valve 60 is damaged by the heat of the fire, and the first elastic bodies 50 and 51, which have been contracted by the damage of the heat-sensing glass valve 60, are restored (relaxed). The outer case 10 is moved upward by the restoring force of the first elastic bodies 50 and 51 . At the same time, the lower end 27 of the outer case 10, which adheres to and supports the ball valve 70, is moved upward to release the contact and support force of the ball valve 70. Accordingly, the ball valve 70, which is inserted into and installed into the insertion groove 42 of the striking member 40 and locks the striking member 40, is separated from the insertion groove 42, thereby locking the striking member 40. this is released At this time, the ball valve 70 separated from the insertion groove 42 falls and is seated on the ball seat 17. And, when the ball valve 70 is separated from the insertion groove 42, the contracted second elastic bodies 50 and 52 are restored (relaxed), and the restoring force of the second elastic bodies 50 and 52 is affected. As a result, the striking member 40 moves downward. The striking member 40 advances downward to hit the blocking film 250, and the blocking film 250 is destroyed (torn or punctured) by the impact of the hitting member 40. Thereafter, the fire extinguishing agent charged at high pressure in the storage container body 210 by the destruction of the blocking film 250 is sprayed to the outside through the outlet hole 16a to suppress the fire.

In the automatic fire extinguishing device according to the preferred embodiment of the present invention described above, even if glass fragments are generated due to the breakage of the heat sensing glass valve 60, both the elastic bodies 50, 51, 52 and the striking member 40 are removed. Since it is installed inside the cylinder 20, the elastic force (restoring force) of the elastic bodies 50, 51, and 52 and the forward force of the striking member 40 are not hindered by glass fragments. Accordingly, the blocking film 250 is instantly destroyed by the strong forward force of the striking member 40, so that the initial fire suppression is possible. In addition, the striking member 40 and the second elastic bodies 50 and 52 are arranged in a direct contact structure so that the number of parts is small and the structure is compact. Accordingly, the installation space of the automatic fire extinguishing device is less occupied in a small space.

On the other hand, the blocking film 250 is good if it can be destroyed (torn or pierced) by the impact of the impact member 40 . The blocking film 250 may be selected from, for example, a thin copper plate or an aluminum plate. Preferably, the blocking film 250 is configured as follows.

Referring to FIG. 4 , according to a preferred embodiment of the present invention, the blocking film 250 has a layer structure of at least two layers, a base layer 251, and a sealing formed on at least one surface of the base layer 251. Layer 252 is included. At this time, the sealing layer 252 is in close contact with the inlet 220 of the storage container 200, and the base layer 251 is positioned on the sealing layer 252, so that the hitting member 40 is the base layer 251 ) can be installed to hit first.

The base layer 251 is composed of a metal thin film, which may be composed of, for example, a metal thin film selected from copper (Cu), aluminum (Al), and alloys thereof. The base layer 251 is not particularly limited, but may have a thickness of, for example, 10 μm to 800 μm, or 20 μm to 500 μm.

The sealing layer 252 may include silicone resin, polysilsesquioxane, and tetrabutyl titanate according to a preferred embodiment of the present invention. Specifically, the sealing layer 252 may be formed by coating and curing a sealing solution including a silicone resin, polysilsesquioxane, tetrabutyl titanate, and a solvent on the base layer 251 . Additionally, the sealing layer 252 may further include other additives such as a curing agent, a surface leveling agent, and/or an antifoaming agent.

The sealing layer 252 may include, for example, 50 to 120 parts by weight of polysilsesquioxane and 10 to 30 parts by weight of tetrabutyl titanate based on 100 parts by weight of the silicone resin. In the present invention, the silicone resin may use a liquid silicone resin used for sealing in general industrial fields, which may use, for example, organopolysiloxane. The polysilsesquioxane may be selected from a homopolymer of silsesquioxane or a copolymer of silsesquioxane and propylene. The polysilsesquioxane and tetrabutyl titanate may be purchased and used on the market.

According to the present invention, when the sealing layer 252 includes the above silicone resin, polysilsesquioxane, and tetrabutyl titanate, sealing properties and durability are improved. Specifically, according to the present invention, as a component for the sealing layer 252, the sealing property is improved compared to the case of using only a silicone resin, and in particular, acid resistance and resistance due to the polysilsesquioxane and tetrabutyl titanate. Chemical properties and the like are improved, and durability of the blocking film 250 is improved.

Examples of the present invention are exemplified below. The following embodiments relate to the sealing layer 252 constituting the blocking film 250 .

[Example 1]

<Preparation of sealing solution>

First, a liquid silicone resin (organopolysiloxane-based silicone) is prepared, and then, based on 100 parts by weight of the silicone resin, 85 parts by weight of polysilsesquioxane, 15 parts by weight of tetrabutyl titanate, and a solvent (methyl ethyl ketone) A sealing solution was prepared by mixing and stirring 150 parts by weight. Each component was purchased and used commercially. At this time, in the case of the polysilsesquioxane, after adding vinyltrimethoxysilane and phenyltrimethoxysilane to a mixed solution of aqueous hydrochloric acid and tetrahydrofuran (THF), the heat-polymerized silsesquioxane polymer used

< Preparation of coated specimens >

A mixed solution obtained by mixing the sealing solution with benzoyl peroxide (curing agent) was prepared, and then the mixed solution was coated on a glass plate to form a sealing layer. At this time, a coated specimen according to Example 1 was prepared by coating the mixed solution three times to have an appropriate thickness. After coating, heat of about 60°C was applied.

[Example 2]

In contrast to Example 1, a coated specimen according to Example 2 was prepared in the same manner as in Example 1, except that polysilsesquioxane and tetrabutyl titanate were not added to the sealing solution. That is, the sealing layer according to the second embodiment has a silicone resin as a main component.

<Test Example>

Acid resistance of the coated specimens according to each of the above examples was evaluated as follows.

First, a sulfuric acid aqueous solution having a sulfuric acid concentration of about 38wt% was prepared. After putting the sulfuric acid aqueous solution in a constant temperature bath, the coated specimen according to each example was immersed in the sulfuric acid aqueous solution in the constant temperature bath. After impregnating for 24 hours while maintaining a temperature of about 40 ° C., it was taken out and evaluated by visually observing whether or not discoloration or pin holes occurred in the sealing layer according to each embodiment. At this time, after impregnation, if discoloration or pinholes do not occur, “acid resistance”, if discoloration occurs, “discoloration”, and if pinholes occur, “pinhole” are indicated in [Table 1].

<Evaluation results of components and acid resistance of the sealing layer according to each embodiment> note
Example 1
Example 2
Components of the sealing layer Silicone resin + polysilsesquioxane + tetrabutyl titanate silicone resin Acid resistance evaluation result
acid resistance
discoloration, pinhole

As shown in [Table 1], when polysilsesquioxane and tetrabutyl titanate are further included in the sealing layer (Example 1), the acid resistance is significantly better than when only silicone resin is used (Example 2). And it was found. This means that the sealing layer of Example 1 has excellent acid resistance as well as chemical resistance (chemical resistance to fire extinguishing agents), so that the durability of the barrier film can be improved.

10: outer case 17: ball seat
18: close contact 19: cylinder stopper
20: first cylinder 30: second cylinder
40: striking member 42: insertion groove
50: elastic body 51: first elastic body
52: second elastic body 60: heat sensing glass valve
70: ball valve 100: operation unit
200: fire extinguishing agent storage container 210: storage container body
220: entrance 250: barrier
251: base layer 252: sealing layer

Claims (4)

The fire extinguishing agent storage container 200 in which the fire extinguishing agent is stored and the barrier film 250 is installed at the inlet 220;
Including an operation unit 100 for spraying the fire extinguishing agent stored in the fire extinguishing agent storage container 200 in case of fire,
The operation unit 100,
a heat-sensing glass valve 60 that is damaged by the heat of a fire;
a hitting member 40 that strikes and destroys the blocking film 250 when the heat-sensing glass valve 60 is damaged; and
It includes an elastic body 50 that provides a forward force to the striking member 40,
In the automatic fire extinguishing device, the elastic body 50 is installed between the heat sensing glass valve 60 and the striking member 40,
The operation unit 100,
An outer case 10 coupled to the fire extinguishing agent storage container 200;
a first cylinder 20 installed inside the outer case 10;
a second cylinder 30 installed inside the first cylinder 20;
A striking member 40 that destroys the blocking film 250 installed at the inlet 220 of the fire extinguishing agent storage container 200 in the event of a fire;
It is installed inside the first cylinder 20, between the inner surface 22 of the top plate of the first cylinder 20 and the outer surface 32 of the top plate of the second cylinder 30, and in the event of a fire, the first cylinder first elastic bodies 50 and 51 that allow one cylinder 20 to move;
It is installed inside the second cylinder 30, installed between the inner surface 33 of the top plate of the second cylinder 30 and the upper outer surface 43 of the striking member 40, and in case of fire, the striking member Second elastic bodies 50 and 52 providing forward force to (40);
a thermal sensing glass valve 60 installed inside the upper end of the outer case 10 and having one side 61 in close contact with the outer surface 21 of the upper plate of the first cylinder 20; and
A ball valve 70 installed in the insertion groove 42 of the hitting member 40 and supported by the lower end 27 of the first cylinder 20 to lock the hitting member 40, ,
When the heat sensing glass valve 60 is damaged in the event of a fire, the first cylinder 20 is moved, and the ball valve 70 moves from the insertion groove 42 due to the movement of the first cylinder 20. automatically, characterized in that the striking member 40 advances due to the separation of the ball valve 70, and the blocking film 250 is destroyed by the advancement of the striking member 40 and the fire extinguishing agent is sprayed fire extinguisher.
According to claim 1,
The outer case 10,
A ball seat 17 installed on the lower wall 16 and in which the ball valve 70 separated from the insertion groove 42 is seated;
a close contact part 18 installed below the ball seating part 17 and in close contact with the blocking film 250; and
An automatic fire extinguishing device characterized in that it includes a cylinder stopper (19) installed on the upper side of the ball seat (17) and supporting the first cylinder (20).
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