KR101800848B1 - Retractable type prevention of explosion spparatus for security facilities - Google Patents

Abstract

An opening/closing explosion-proof device for security facility is disclosed. The opening/closing explosion-proof device for security facility comprises: a plurality of door support frames which are installed on the circumference of an interface between a protected section and an unprotected section, wherein one surface thereof is directed to the protected section; a plurality of hinge brackets which are arranged along a length direction of each of two door support frames symmetric with each other of the plurality of door support frames, and are fixed to one surface opposed to the protected section of each door support frame; a first explosion-proof door and a second explosion-proof door in which a side portion on one side positioned in parallel to two door support frames to which the hinge bracket are fixed is connected to hinge brackets fixed to two door support frames; and a locking device which is provided on surfaces facing the unprotected section of each of the first explosion-proof door and the second explosion-proof door.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a retractable type explosion-

BACKGROUND OF THE INVENTION 1. Field of the Invention [0002] The present invention relates to an explosion-proof device, and more particularly, to an explosion-proof type explosion-proof device for a security facility which can be opened and closed and increased in stability.

Military facilities, such as military facilities and security facilities, are needed. For example, airplane hangars, major arsenals, and underground bunkers for evacuation are needed. Because, when a national disaster such as an external invasion occurs, the core personnel of the nation need to stay in a safe state and command the national defense. Therefore, in order to prevent external bombings, major national figures need safety facilities that are not easily damaged by bombing.

The entrance to a safety facility (eg, an underground bunker for evacuation) is the only place through the safety facility, whilst it is the most vulnerable of the safety facilities. Because access doors of safety facilities must be opened and closed for access, safety doors need to be designed so that they are not easily damaged. However, most of the doors of security facilities are vulnerable to vulnerable parts such as the hinge area when the doors are bombarded.

Therefore, in a country where danger is likely to occur at any time, such as a country where South and North are in a state of truce, such as South Korea, there is a need for an explosion proof door that can withstand bombardment even if the door is directly bombed.

BACKGROUND ART [0002]

Registration No. 10-0401809

Therefore, a problem to be solved by the present invention is to provide a security system for a security facility which can completely block an impact caused by blast or bombardment by storm pressure, dust, and scattering, is not easily broken, And to provide an explosion-proof device.

The door opening and closing type explosion-proof apparatus for a security facility according to an embodiment of the present invention is characterized in that a plurality of door support frames are installed around an interface between an unprotected section and a protection section, one door support frames are installed in an unprotected space, Installed in the space; A plurality of hinge brackets fixed to one surface of the two door support frames installed in the unprotected section; A first explosion-proof door and a second explosion-proof door in which a side portion parallel to the two door support frames to which the hinge bracket is fixed is connected to hinge brackets fixed to each of the two door support frames; And a locking device provided on each of the first and second explosion proof doors facing the unprotected section, wherein each of the explosion proof doors forms an outer appearance of the door and exposes the exterior of the door A plurality of hinge blocks protruding from surfaces of the outer explosion-proof module facing the hinge brackets; and a plurality of hinge blocks protruding from the inner explosion-proof module, And a second inner explosion-proof channel part provided in an inner space of the outer explosion-proof module so as to be disposed behind the first inner explosion-proof channel part, and a second inner explosion-proof channel part provided in an inner space of the outer explosion- , An explosion-proof channel compartment assembly for partitioning the first inner explosion-proof channel part and the second inner explosion-proof channel part in an inner space of the outer explosion-proof module Wherein the first inner explosion-proof channel portion includes a first explosion-proof material filled in the inner space of the outer explosion-proof module in the form of particles, and the second inner explosion-proof module is filled in the inner space of the outer explosion- Is characterized by including a second explosion-proof material.

In one embodiment, the outer explosion-proof module includes: a first outer frame frame forming one side edge parallel to the height direction of the door; A second outer frame frame arranged symmetrically with the first outer frame frame and forming a second frame parallel to a height direction of the door; A third outer frame frame connected to the upper ends of the first outer frame frame and the second outer frame frame on both sides in the longitudinal direction and forming a side frame parallel to the width direction of the door; A fourth outer frame frame connected to the lower ends of the first outer frame frame and the second outer frame frame on both sides in the longitudinal direction and forming a second frame parallel to the width direction of the door; An outer explosion-proof front plate connected to one side of all of the outer frame frames to form a front face of the door; And an outer side explosion-proof back plate connected to the other side of both of the outer side frame frames to oppose the outer side explosion-proof front plate and forming a rear surface of the door, wherein the explosion-proof channel partitioning assembly comprises: A first space dividing frame partially connected to the inner surface of the outer frame; A second space dividing frame disposed symmetrically with respect to the first space dividing frame and partially connected to the inner surface of the outer explosion-proof back plate so as to be spaced apart from the second outside frame; A third space division frame having both longitudinal sides connected to upper ends of the first and second space dividing frames; A fourth space partition frame in which both sides in the longitudinal direction are connected to the lower ends of the first and second space dividing frames; And a space partition diaphragm connected to one side of all of the space dividing frames and disposed adjacent to the outside explosion-proof front plate, wherein the first inside explosion-proof channel portion is provided between the space partition diaphragm and the outside explosion- The second inner explosion-proof channel part may be provided between the space partition plate and the outer explosion-proof back plate.

In one embodiment, the first inner explosion-proof channel portion includes a first channel space between the space partition plate and the outer explosion-proof front plate, a second channel space between the second space partition frame and the second outer frame, The first explosion-proof material filled in the channel space and the second channel space, and a Kevlar mesh embedded in the first explosion-proof material and disposed between the space partition plate and the outer explosion-proof front plate, and the second inside explosion- Wherein the first explosion-proof material is sand, and the second explosion-proof material is filled in the third channel space, wherein the first explosion-proof material is sand, and the second explosion- 2 The explosion-proof material may be concrete.

The explosion-proof device for a security facility according to the present invention is installed between a protection section and an unprotected section and is excellent in an explosion-proof effect for preventing impacts caused by storm pressure, dust, and scattering generated when a blasting operation progresses in a protection section, Thus, the shock caused by storm pressure, dust, and scattering can be completely blocked, and there is an advantage that it is not easily broken.

In addition, since each explosion proof door has a double lock structure, it is advantageous in that it can not be easily opened due to a shock caused by storm pressure, dust, scattering, etc., and thus safety can be increased.

FIGS. 1A and 1B are cross-sectional views illustrating a state where the openable explosion-proof device for a security facility according to an embodiment of the present invention is installed between a protection section and an unprotected section.
FIGS. 2 and 3 are perspective views showing the appearance of the first explosion proof door and the second explosion proof door shown in FIGS. 1A and 1B.
4 is a perspective view showing the inside of the first explosion proof door and the second explosion proof door shown in FIG.
Fig. 5 is a cross-sectional view of the first explosion-proof door and the second explosion-proof door shown in Figs. 2 and 3 in the width direction.
6A and 6B are enlarged sectional views of a portion of the first explosion proof door and the second explosion proof door shown in FIG.
FIG. 7A is a sectional view of the first explosion proof door shown in FIG. 5 cut in the height direction. FIG.
Fig. 7B is an enlarged cross-sectional view of a portion of the first explosion proof door shown in Fig. 7A.
FIG. 8A is a sectional view of the second explosion proof door shown in FIG. 5 cut in the height direction. FIG.
8B is an enlarged cross-sectional view of a portion of the second explosion proof door shown in FIG. 8A.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, an explosion-proof type for a security facility according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings. The present invention is capable of various modifications and various forms, and specific embodiments are illustrated in the drawings and described in detail in the text. It should be understood, however, that the invention is not intended to be limited to the particular forms disclosed, but includes all modifications, equivalents, and alternatives falling within the spirit and scope of the invention. Like reference numerals are used for like elements in describing each drawing. In the accompanying drawings, the dimensions of the structures are enlarged to illustrate the present invention in order to clarify the present invention.

The terms first, second, etc. may be used to describe various components, but the components should not be limited by the terms. The terms are used only for the purpose of distinguishing one component from another. For example, without departing from the scope of the present invention, the first component may be referred to as a second component, and similarly, the second component may also be referred to as a first component.

The terminology used in this application is used only to describe a specific embodiment and is not intended to limit the invention. The singular expressions include plural expressions unless the context clearly dictates otherwise. In this application, the terms "comprises", "having", and the like are used to specify that a feature, a number, a step, an operation, an element, a part or a combination thereof is described in the specification, But do not preclude the presence or addition of one or more other features, integers, steps, operations, components, parts, or combinations thereof.

Unless defined otherwise, all terms used herein, including technical or scientific terms, have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. Terms such as those defined in commonly used dictionaries are to be interpreted as having a meaning consistent with the contextual meaning of the related art and are to be interpreted as either ideal or overly formal in the sense of the present application Do not.

FIGS. 1A and 1B are cross-sectional views illustrating a state in which an openable explosion-proof type explosion-proof device for a security facility according to an embodiment of the present invention is installed between a protection section and an unprotected section. FIGS. 2 and 3 are cross- FIG. 4 is a perspective view showing the inside of the first explosion proof door and the second explosion proof door shown in FIG. 3, and FIG. 5 is a perspective view showing the inside of the first explosion proof door and the second explosion proof door shown in FIGS. 6A and 6B are enlarged cross-sectional views of a portion of the first explosion proof door and the second explosion proof door shown in FIG. 5, and FIG. 7A is a cross-sectional view of the second explosion proof door, 7A is an enlarged cross-sectional view of a portion of the first explosion proof door shown in FIG. 7A, FIG. 8A is a sectional view of the second explosion proof door shown in FIG. 5 in a height direction 8B is a cross-sectional view taken along the direction of Fig. 8A Is a graph illustrating a close-up showing the second portion of the explosion-proof door section.

The explosion-proof device for a security facility according to an embodiment of the present invention can be used as a door of a safety facility for explosion-proof. For example, in a subterranean bunker for evacuation.

1 to 8B, an explosion-proof type for a security facility according to an embodiment of the present invention includes a plurality of door support frames 110 and 120, a plurality of hinge brackets 200, a first explosion-proof door 300, A second explosion proof door 300 ', and a locking device 400.

A plurality of door support frames 110 and 120 are installed around the interface 30 between the unprotected section 10 and the guard section 20. The protection zone 20 means an inner space of a safety facility where a person can be evacuated and protected from the outside, and the unprotected zone 10 means an outer space of the safety facility. There is no particular limitation on the number of the door support frames 110 and 120, and the number may vary according to the installation site conditions of the apparatus. For example, the interface 30 may include three surfaces opposite the guard interval 20. In such a case, the plurality of door support frames 110 and 120 may include three surfaces, Four on each of the inner wall and the bottom surface of the guard interval 20 connected to the interface 30 perpendicularly. In the following description, the door supporting frames provided on the interface 30 will be referred to as a "first door supporting frame 110" for convenience of explanation, The support frames will be referred to as "second door support frame 120 ".

The plurality of hinge brackets 200 allow the first explosion-proof door 300 and the second explosion-proof door 300 'to be rotatably provided on the interface 30. The plurality of hinge brackets 200 are provided on the second door support frame 120 symmetrical to each other. For example, the plurality of hinge brackets 200 may be provided along the longitudinal direction of each of the second door support frames 120.

The first explosion-proof door 300 and the second explosion-proof door 300 'are disposed on the interface 30 and are connected to the plurality of hinge brackets 200 so as to be opened and closed. Each of the explosion proof doors 300 and 300 'includes an outer explosion-proof module 310 and 310', an explosion-proof channel compartment assembly 320 and 320 ', a first inner explosion-proof channel part 330 and 330' The inner explosion-proof channel portions 340 and 340 ', the reinforcing member 350, the plurality of hinge blocks 360, and the hinge fixing rods 370.

The outer explosion-proof modules 310 and 310 'include a first outer frame frame 311 and 311', a second outer frame frame 312 and 312 ', a third outer frame frame 313 and 313' And may include frames 314 and 314 ', outer explosion-proof face plates 315 and 315', and outer explosion-proof backplanes 316 and 316 '.

The first outer frame frames 311 and 311 'form one side edge parallel to the height direction of each of the explosion proof doors 300 and 300'. For example, the first outer frame frames 311 and 311 'are provided in a' C 'shape and include a frame surface 311a and 311a', a first coupling surface 311a and 311b 'disposed on both sides of the frame surfaces 311a and 311a' (311b, 311b ') and second mating surfaces (311c, 311c').

The second outer frame frames 312 and 312 'are disposed symmetrically with the first outer frame frames 311 and 311' to form a second frame parallel to the height direction of the respective explosion proof doors 300 and 300 ' . For example, the second outer frame frames 312 and 312 'are provided in a' C 'shape and include a frame surface 312a and a first coupling surface 312a' disposed on both sides of the frame surfaces 312a and 312a ' (312b, 312b ') and second mating surfaces (312c, 312c').

The third outer frame frames 313 and 313 'are connected to the upper ends of the first outer frame frames 311 and 311' and the second outer frame frames 312 and 312 'on both sides in the longitudinal direction, A side edge parallel to the width direction of the first and second electrodes 300 and 300 'may be formed. For example, the third outer frame frames 313 and 313 'are formed in a' C 'shape and are disposed on both sides of the frame surfaces 313a and 313a' and the frame surfaces 313a and 313a ' And may include first and second mating surfaces 313b and 313b 'and second mating surfaces 313c and 313c'.

The longitudinal sides of the fourth outer frame frames 314 and 314 'are connected to the lower ends of the first outer frame frames 311 and 311' and the second outer frame frames 312 and 312 ' And the other edge parallel to the width direction of the doors 300 and 300 'can be formed. For example, the fourth outer frame frames 314 and 314 'are provided in a " C " shape and include a first coupling surface 314a and a second coupling surface 314a', which are disposed on both sides of the rim surfaces 314a and 314a ' (314b, 314b ') and second mating surfaces (314c, 314c').

The outer frame frames 311, 311 ', 312, 312', 313, 313 ', 314 and 314' are connected to the outer frame frames 311, 311 ' 314b, 313b, 313b, 314b, 314b 'and the second mating surfaces 311c, 311c, 312c, 312c ', 313c, 313c', 314c, and 314c 'are arranged in the same direction.

The outer explosion-proof front plates 315 and 315 'are connected to one side of each of the outer frame frames 311, 311', 312, 312 ', 313, 313', 314 and 314 ' , And 300 '. 311 ', 313', 314 ', 314') of the respective outer frame frames 311, 311 ', 312, 312', 313, 313 ' , 312b, 312b ', 313b, 313b', 314b, 314b '.

The outer explosion-proof back plates 316 and 316 'are connected to the other sides of all of the outer frame frames 311, 311', 312, 312 ', 313, 313', 314 and 314 ' 'To form the back surface of each of the explosion proof doors 300 and 300'. 311 ', 312', 312 ', 313, 313', 314, 314 ') of the outer edge frame 311, 311' , 312c, 312c ', 313c, 313c', 314c, 314c '.

The explosion-proof channel partitioning assemblies 320 and 320 'are formed in the inner space of the outer explosion-proof modules 310 and 310' so that the first inner explosion-proof channel parts 330 and 330 'and the second inner explosion-proof channel parts 340 and 340' . The explosion-proof channel compartment assemblies 320 and 320 'include a first space partition frame 321 and 321', a second space partition frame 322 and 322 ', a third space partition frame 323 and 323' A space partitioning frame 324, 324 ', and a space partitioning plate 325.

The first space partitioning frames 321 and 321 'may be partially connected to the inner surfaces of the outer explosion-proof backplanes 316 and 316' and the first outer frame frames 311 and 311 '. The first space partitioning frames 321 and 321 'are provided in a' C 'shape and include first and second coupling surfaces 321b and 321b' arranged on both sides of the rim surfaces 321a and 321a 'and the rim surfaces 321a and 321a' 321b 'and second mating surfaces 321c, 321c'. In this case, the rim surfaces 321a and 321a 'of the first space division frames 321 and 321' are supported inside the rim surfaces 311a and 311a 'of the first outer rim frames 311 and 311' 2 coupling surfaces 321b and 321b 'can be supported on the inner surfaces of the outer explosion-proof rear plates 316 and 316'. At this time, the first engagement surfaces 321b and 321b 'are spaced apart from the outer explosion-proof front plates 315 and 315'.

The second space partitioning frames 322 and 322 'may be arranged symmetrically with the first space dividing frames 321 and 321' and a part of the second space dividing frames 322 and 322 'may be connected to an inner surface of the outer explosion-proof backplane 316 and 316'. The second space partitioning frames 322 and 322 'are provided in a' C 'shape and include first and second coupling surfaces 322b and 322b' disposed on both sides of the rim surfaces 322a and 322a 'and the rim surfaces 322a and 322a' 322b 'and second mating surfaces 322c, 322c'. In this case, the second engagement surfaces 322c and 322c 'of the second space dividing frames 322 and 322' are supported inside the outer explosion-proof rear plates 316 and 316 ', and the rim surfaces 322a and 322a' And the first engagement surfaces 322b and 322b 'are spaced apart from the outer explosion-proof front plates 315 and 315'.

The third space partitioning frames 323 and 323 'may be connected to the upper ends of the first space dividing frames 321 and 321' and the second space dividing frames 322 and 322 '. The third space partitioning frames 323 and 323 'are provided in a' C 'shape and include first and second coupling surfaces 323b and 323b' disposed on both sides of the rim surfaces 323a and 323a 'and the rim surfaces 323a and 323a' 323b 'and second mating surfaces 323c, 323c'. In this case, the rim surfaces 323a and 323a 'of the third spatial divider frame 323 and 323' are supported inside the third outer frame frames 313 and 313 ', and the second mating surfaces 323c and 323c' Are supported inside the outer explosion-proof rear plates 316 and 316 ', and the first fitting surfaces 323b and 323b' are spaced apart from the outer explosion-proof front plates 315 and 315 '.

The fourth space partitioning frames 324 and 324 'may be connected to the lower ends of the first space partitioning frames 321 and 321' and the second space partitioning frames 322 and 322 '. The fourth space partitioning frames 324 and 324 'are provided in a' C 'shape and include first and second coupling surfaces 324a and 324b' disposed on both sides of the rim surfaces 324a and 324a ' 324b 'and second mating surfaces 324c, 324c'. In this case, the rim surfaces 324a and 324a 'of the fourth space partitioning frame 324 and 324' are supported inside the fourth outer rim frame 314 and 314 ', and the second mating surfaces 324c and 324c' Are supported inside the outer explosion-proof rear plates 316 and 316 ', and the first fitting surfaces 324b and 324b' are spaced apart from the outer explosion-proof front plates 315 and 315 '.

Here, the first coupling surfaces 321b, 321b ', 322b, 322b', 323b, 323b ', and 324b of the respective space partition frames 321, 321', 322, 322 ', 323, 323' 321 ', 323', 323 ', 324', 324 'are spaced apart from the outer explosion-proof front plate 315, 315' The heights of the first coupling surfaces 321b, 321b ', 322b, 322b', 323b, 323b ', 324b, and 324b' are all the same.

The space partitioning plate 325 is connected to one side of each of the space division frames 321, 321 ', 322, 322', 323, 323 ', 324 and 324'. That is, the space partition diaphragm 325 is spaced apart from the first engagement surfaces 321b, 321b ', 322b, 322b' of the respective space partition frames 321, 321 ', 322, 322', 323, 323 ' , 323b, 323b ', 324b, 324b'. At this time, the space partitioning plate 325 is spaced apart from the outer explosion-proof front plate 315 and 315 ', and each of the space partitioning frames 321, 321', 322, 322 ', 323, 323', 324 and 324 ' Ensure that the inside is sealed.

The first inner explosion-proof channel portions 330 and 330 'are disposed between the space partitioning plate 325 and the outer explosion-proof front plates 315 and 315' in the inner space of the outer explosion-proof modules 310 and 310 '. For example, the first inner expansible channel unit 330 includes first channel spaces 331 and 331 ', second channel spaces 332 and 332', first explosion-proof members 333 and 333 ', a Kevlar mesh 334 , 334 '.

The first channel spaces 331 and 331 'are spaces between the space partition plate 325 and the outer explosion-proof front plates 315 and 315'.

The second channel spaces 332 and 332 'are spaces between the second spatial partition frame 322 and 322' and the second outer frame frames 312 and 312 ' It is the following space.

The first explosion-proof material 333 and 333 'are filled in the first channel spaces 331 and 331' and the second channel spaces 332 and 332 '. Sand is used as the first explosion-proof material 333 and 333 '.

The Kebla meshes 334 and 334 'are located in the first channel spaces 331 and 331' and embedded in the first explosion-proof material 333 and 333 ', i.e., sand. At this time, the Kebla meshes 334 and 334 'are disposed between the space dividing partition 325 and the outer explosion-proof front plates 315 and 315'.

The second inner explosion-proof channel portions 340 and 340 'are provided between the space partition plate 325 and the outer explosion-proof rear plates 316 and 316'. For example, the second inner expansible channel portion 340 may include a third channel space 341, 341 'and a second explosion proof material 342, 342'.

The third channel spaces 341 and 341'are connected to the respective space partition frames 321, 321 ', 322, 322', 323, 323 ', 324 and 324', the space partition plate 325, 316, and 316 '.

The second explosion-proof material 342, 342 'is filled in the third channel space 341, 341'. Concrete is used as the second explosion-proof material 342, 342 '.

The reinforcing member 350 reinforces the strength of the second inner-side explosion-proof channel portions 340 and 340 '. The reinforcing member 350 may include a plurality of first reinforcing wires 351 and a plurality of second reinforcing wires 352.

Each first reinforcement wire 351 is coupled to the second space dividing frames 322 and 322 'and extends from the second space dividing frames 322 and 322' toward the first space dividing frames 321 and 321 ' . A plurality of first reinforcing wires 351 are arranged along the longitudinal direction of the second space dividing frames 322 and 322 '. For example, the first reinforcing wire 351 may be U-shaped. In this case, both end portions of each first reinforcing wire 351 are coupled to the second space dividing frames 322 and 322 'and connected to the second space dividing frames 322 and 322' May extend into the space partition frame 321, 321 'and be located in the third channel space 341, 341'. The plurality of first reinforcing wires 351 are embedded in the concrete used as the second explosion-proof material 342 and 342 'in the third channel spaces 341 and 341'.

Each second reinforcement wire 352 is coupled to the second spatial divider frame 322 or 322 'and extends from the second spatial divider frame 322 or 322' toward the first spatial divider frame 321 or 321 ' And is embedded in the concrete used as the second explosion-proof material 342, 342 'in the third channel space 341, 341'. The second reinforcing wire 352 is connected to the outer explosion-proof rear plates 316 and 316 'of the respective explosion proof doors 300 and 300' and the space partition plate 325 so as to penetrate the third channel spaces 341 and 341 ' . The plurality of second reinforcing wires 352 are arranged in the height direction and the width direction of the respective explosion proof doors 300 and 300 '. At this time, a part of the plurality of second reinforcing wires 352 is divided into a first outer frame frame 311, 311 ', an outer explosion-proof back plate 316, 316', a first space dividing frame 321, 321 ' The first outer frame frames 311 and 311 ', the outer explosion-proof back plates 316 and 316', the first space dividing frames 321 and 321 ', and the space dividing plates 325, which are coupled to the partition dividing plates 325, Fix the connection status.

The plurality of hinge blocks 360 may protrude from the outer explosion-proof modules 310 and 310 'of the respective explosion-proof doors 300 and 300' on the surface facing the hinge brackets 200. The first outer frame frames 311 and 311 'and the second outer frame frames 312 and 312' of the first outer frame frame 311 and 311 ' . Each of the hinge blocks 360 includes a hinge connection portion 361 and a door connection portion 362 including a plurality of rod engagement holes 362a arranged in the longitudinal direction of the bar shape extending from the hinge connection portion 361 to a predetermined length 362). The plurality of hinge blocks 360 are connected to the respective explosion proof doors 300 and 300 'by a hinge fixing rod 370 described later.

The hinge fixing rod 370 fixes the plurality of hinge blocks 360 to the respective explosion proof doors 300 and 300 '. For connection between each hinge block 360 and each explosion proof door 300, 300 'via the hinge fixing rod 370, the door connection portion 362 of the hinge block 360 is connected to each first explosion proof door The edge faces 311a and 311a 'of the first outer edge frames 311 and 311' of the second explosion proof door 300 and the edge faces 312a and 312b of the second outer edge frames 312 and 312 ' And the hinge fixing rods 370 are inserted into the third channel spaces 341 and 341 'through the third channel spaces 341 and 341' And is coupled to the rod engagement holes 362a of the door connection portion 362 inserted into the channel spaces 341 and 341 '. The hinge fixing rods 370 and the door connecting portions 362 of the respective hinge blocks 360 located in the third channel spaces 341 and 341 'are connected to the third channel spaces 341 and 341' And is buried and fixed in the concrete used as the second explosion-proof material 342, 342 'to be filled.

The locking device 400 is provided on the surfaces of the first explosion-proof door 300 and the second explosion-proof door 300 ', respectively, which face the protection zone 20. For example, the locking device 400 may be provided on the second outer explosion-proof backplane 316, 316 'of each explosion proof door 300, 300'. The locking device 400 may include a first locking portion 410 and a second locking portion 420.

The first locking portion 410 includes a first locking metal 411 and a first locking rod 412. The first locking metal fittings 411 are provided on the outer side explosion-proof backplanes 316 and 316 'of the first and second explosion-proof doors 300 and 300', respectively, adjacent to each other at the same height, And a first rod insertion hole 411a parallel to the width direction of the first and second rod insertion holes 300 and 300 '. The first locking rod 412 may be inserted into the first rod insertion holes 411a of the first locking metal fitting 411 and may be engaged with the first locking metal fitting 411. In one example, the first locking rod 412 may be in the shape of a square bar.

The second locking portion 420 may include a plurality of second locking brackets 421 and a plurality of second locking rods 422. Each of the second locking brackets 421 is connected to the third outer frame frames 313 and 313 'and the fourth outer frame frames 314 and 314' of the first and second explosion proof doors 300 and 300 ' And a second rod insertion hole 421a which is adjacent to each other at the same height and parallel to the height direction of each of the explosion proof doors 300 and 300 'may be provided. The plurality of second lock rods 422 can be inserted into the second rod insertion holes 421a of the respective second lock brackets 421 and coupled to the second lock brackets 421. [

The second locking portion 420 is disposed at the upper and lower ends of the first and second explosion proof doors 300 and 300 'to face a plurality of the second door support frames 120, The end of the rod 422 may be fixedly coupled to the second door support frame 120 facing the second locking portion 420. Here, the second rod insertion hole 421a of the second locking metal fitting 421 may have a threaded shape, and the second locking rod 422 may be a bolt.

The open-type explosion-proof apparatus for a security facility according to an embodiment of the present invention may be installed at an interface 30 between the unprotected section 10 and the protected section 20. At this time, the first explosion-proof door 300 and the second explosion-proof door 300 'are connected to the hinge brackets 200 provided on the first door support frame 110 by a plurality of hinge blocks 360, The first explosion-proof door 300 and the second explosion-proof door 300 'can be opened and closed by rotation.

In this installed state, the first explosion-proof door 300 and the second explosion-proof door 300 'can be closed to block the unprotected section 10 and the protection section 20 from each other and vice versa.

The first explosion-proof door 300 and the second explosion-proof door 300 'are closed to prevent the storm pressure and dust from the unprotected section 10 when the blasting operation is proceeding in the unprotected section 10, And the protection section (20). That is, each of the first explosion-proof doors 300 and the second outside frame frames 312 and 312 'of the second explosion-proof door 300' are interfaced with each other so that the first explosion-proof door 300 and the second explosion- ') Is closed.

The closed state of the first explosion-proof door 300 and the second explosion-proof door 300 'is fixed and held by the first locking part 410 and the second locking part 420. That is, the first lock rod 412 is locked to the first lock bracket 411 at the positions of the outer side explosion-proof back plates 316 and 316 'of the respective explosion-proof doors 300 and 300' And the second lock rod 422 is coupled to the second lock bracket 421 so that an end of the second lock rod 422 is connected to the second door support frame 120 facing the second locking portion 420, And is locked in a secondary position.

At this time, each of the first explosion-proof door 300 and the second explosion-proof door 300 'faces the unprotected section 10 of the outer explosion-proof front plate 315 and 315' The first inner side explosion-proof channel parts 330 and 330 'inside the outer side explosion-proof modules 310 and 310' of the first inner side explosion-proof module 300 'are located behind the outer side explosion proof face plates 315 and 315' 340, and 340 'are positioned behind the first inner-side explosion-proof channel units 330 and 330'.

In this state, when the blasting operation is progressed in the unprotected section 10, the storm pressure, dust, and fly ash generated in the unprotected section 10 are protected through the first explosion proof door 300 and the second explosion proof door 300 ' The transmission to the section 20 is blocked.

That is, when the blasting operation progresses in the unprotected section 10, the storm pressure, dust, and fly ash are primarily blocked by the outer explosion-proof front plates 315 and 315 'of the explosion-proof doors 300 and 300' Is blocked by the first inner-side explosion-proof channel portions 330 and 330 'located behind the outer-side explosion-proof front plates 315 and 315' and the second inner-side explosion-proof channel portions 330 and 330 ' 2 by the inner explosion-proof channel portions 340 and 340 ', and can be cut off by the outer explosion-proof rear plates 316 and 316'.

Since the Kebla meshes 334 and 334 'are positioned in the first inner side explosion-proof channel units 330 and 330', the strong explosion due to the explosion in the protection zone 20, , Dust, and fly ash are moved into the protection zone 20 by the Kevlar mesas 334 and 334 'even if a portion of the first and the second inner explosion-proof channel portions 316 and 316' is broken and flows into the first inner explosion-proof channel portions 330 and 330 ' Can be safely blocked.

The Kevlar mesh 334 and 334 'are made of Kevla, and Kevlar is known to be five times stronger than steel and light in weight. The Kevlar mesh is made of fibers, It maintains the strength to withstand any force from any direction. Accordingly, since each of the explosion proof doors 300 and 300 'is provided with the Kevlar mesas 334 and 334' provided with the Kevlar in the form of a mesh, it is possible to prevent the storm pressure, dust and scattering from the unprotected section 10 It is possible to withstand the shock to completely prevent the impact of the storm pressure, dust, and fly ash from being transmitted to the protection zone 20. [

Since the second inner explosion-proof channel portions 340 and 340 'maintain strong strength by the first reinforcing wire 351 and the second reinforcing wires 352 buried in the concrete and concrete, the first inner explosion- It is possible to stably withstand the impacts caused by storm pressure, dust, and fly ash along with the first inside explosion-proof channel portions 330 and 330 'behind the portions 330 and 330'.

The second locking part 420 is formed by a first locking part 410 and a second locking part 420. The second locking part 420 is provided on the inner wall and the bottom surface of the protection section 20, Even if an impact is applied by the storm pressure, dust, scattering or the like transmitted from the unprotected section 10, the respective explosion proof doors 300 and 300 'are coupled to the frame 120, The closed state of each explosion proof door 300, 300 'can be safely maintained without being easily opened or easily detached from the interface 30.

The openable type explosion-proof device for a security facility according to an embodiment of the present invention is installed in an unprotected section 10 and a protection section 20 and is installed in a storm pressure, dust, It is possible to completely cut off the impact caused by storm pressure, dust, and scattering, and is advantageous in that it is not easily broken.

In addition, since each of the explosion proof doors 300 and 300 'has a double lock structure, it is advantageous that the door is not easily opened due to a shock caused by storm pressure, dust, scattering, etc., and thus safety can be increased.

Meanwhile, the explosion-proof type for the security facility according to an embodiment of the present invention is used as an explosion-proof door for a security facility or a security facility in the ground or the ground, so that the object of protection for preventing damage from outside bombardment can be effectively Can be achieved.

Meanwhile, the first reinforcing wire 351 and the second reinforcing wire 352 of the explosion-proof type explosion-proof type security apparatus according to an embodiment of the present invention may be used for surface application of a metal material to prevent corrosion of the surface from dust, A surface protective coating layer may be formed of a material. The surface protective coating layer is composed of 2.5% by weight of zirconium powder, 60% by weight of alumina powder, 30% by weight of NH ₄ Cl, 2.5% by weight of zinc, 2.5% by weight of magnesium and 2.5% by weight of titanium.

The zirconium powder is excellent in corrosion resistance and heat resistance. These zirconium powders were mixed at 2.5 wt%. If the mixing ratio of the zirconium powder is less than 2.5% by weight, the corrosion resistance and the heat resistance are not greatly improved. On the other hand, when the mixing ratio of the zirconium powder exceeds 2.5% by weight, the above-mentioned effect is not further improved, but the material cost is greatly increased. Therefore, titanium is preferably mixed at 2.5% by weight.

The alumina powder is added for the purpose of sintering, entangling, fusion prevention, etc. when heated to a high temperature. When such an alumina powder is added in an amount of less than 60% by weight, the effect of sintering, entangling and fusion prevention is deteriorated. When the alumina powder exceeds 60% by weight, the above effect is not further improved, but the material cost is greatly increased. Therefore, it is preferable to add 60 wt% of the alumina powder.

The NH ₄ Cl reacts with zinc and magnesium in a vapor state to activate diffusion and penetration. This NH ₄ Cl is added in an amount of 30% by weight. When NH ₄ Cl is added in an amount of less than 30% by weight, reaction with zinc or magnesium in a vapor state is not properly performed, and thus diffusion and penetration are not activated. On the other hand, if NH ₄ Cl exceeds 30 wt%, the above-mentioned effect is not further improved, but the material cost is greatly increased. Therefore, it is preferable to add 30 wt% of NH ₄ Cl.

The zinc is compounded to prevent corrosion of the metal that is in contact with water and to be used for electrical applications. 2.5% by weight of this zinc is mixed. If the mixing ratio of zinc exceeds 2.5% by weight, corrosion of the metal which is in contact with water can not be properly prevented. On the other hand, when the mixing ratio of zinc exceeds 2.5% by weight, the above-mentioned effect is not further improved, but the material cost is greatly increased. Therefore, it is preferable that zinc is mixed at 2.5% by weight.

Since the pure metal of magnesium has a low structural strength, it is used in combination with the zinc and the like to improve the hardness, tensile strength and corrosion resistance of the metal. This magnesium is mixed at 2.5% by weight. When the mixing ratio of magnesium is less than 2.5% by weight, the hardness, the tensile strength and the corrosion resistance to the salt water of the metal are not greatly improved when they are combined with zinc and the like. On the other hand, when the mixing ratio of magnesium exceeds 2.5% by weight, the above-mentioned effect is not further improved, but the material cost is greatly increased. Therefore, it is preferable that magnesium is mixed with 2.5% by weight.

The titanium is a lightweight, hard and corrosion resistant transition metal element with a silver-white metallic luster. Because it has excellent corrosion resistance and specific gravity, it weighs only 60% of steel. Therefore, the weight of the coating material applied to the metal base material is reduced, Excellent water resistance and corrosion resistance.

This titanium is mixed at 2.5% by weight. If the mixing ratio of titanium is less than 2.5% by weight, the weight of the coating material applied to the metal base material is not so reduced, and glossiness, water resistance and corrosion resistance are not greatly improved. On the other hand, when the mixing ratio of titanium exceeds 2.5% by weight, the above effect is not further improved, but the material cost is greatly increased. Therefore, titanium is preferably mixed at 2.5% by weight.

The method of applying the surface of the first reinforcing wire 351 and the second reinforcing wire 352 according to the present invention is as follows.

The base material on which the surface protective coating layer is to be formed and the coating material combined with the above composition are put into a closed furnace together with argon gas at a rate of 2 L / min in order to prevent oxidation of the base material. Is maintained at a temperature of 700 ° C to 800 ° C for 4 to 5 hours.

The zirconium powder, the alumina powder, the zinc, the magnesium and the titanium compound penetrate into the surface of the base material to form the surface protective coating layer. The zirconium powder, the alumina powder, the zinc, the magnesium and the titanium, .

After the surface protective coating layer is formed, the temperature inside the closed chamber is maintained at a temperature of 800 ° C. to 900 ° C. for 30 to 40 hours to form an anti-corrosive surface protective coating layer on the surface of the base material. Thereby isolating the outside air. At this time, the abrupt temperature change in performing the above process may cause a temperature change at a rate of 60 ° C / hr because the surface protective coating layer on the surface of the base material may be peeled off.

The surface protective coating layer of the present invention has the following advantages.

Since the surface protective coating layer of the present invention has a very wide range of applications, it can be applied by various methods such as curtain coating, spray painting, dip coating, flooding and the like.

The surface protective coating layer of the present invention can be coated with a very thin layer thickness in addition to the principle protection against corrosion and / or scale, thereby improving electrical conductivity as well as material and cost reduction. A thin electrically conductive primer may be applied to the top of the application layer if high electrical conductivity is desired after the hot forming process.

After the molding process or the hot forming process, the coating material can be retained on the surface of the substrate, for example, to increase scratch resistance, to improve corrosion protection, to meet aesthetic appearance, to prevent discoloration, And may be provided as a primer for conventional downstream processes (e.g., impregnated and electro-mobile dip application).

Since the first reinforcing wire 351 and the second reinforcing wire 352 are coated with a surface protective coating layer made of zirconium powder, alumina powder, NH ₄ Cl, zinc, magnesium and titanium, Corrosion of the surfaces of the wire 351 and the second reinforcing wire 352 can be prevented.

Meanwhile, the anti-fouling coating layer coated with the anti-fouling coating composition may be formed on the periphery of the hinge bracket 200 according to an embodiment of the present invention so as to effectively prevent and remove the contaminants. The antifouling coating composition contains hydrogen peroxide and sodium metasilicate in a molar ratio of 1: 0.01 to 1: 2, and the total content of hydrogen peroxide and sodium metasilicate is 1 to 10 wt% with respect to the total aqueous solution. In addition, sodium metasilicate or calcium carbonate may be used as the material for improving the coating property of the anti-fouling coating layer, but sodium metasilicate is preferably used. The hydrogen peroxide and sodium metasilicate are preferably in a molar ratio of 1: 0.01 to 1: 2, and when the molar ratio is out of the above range, the coating property of the substrate is lowered or the moisture adsorption on the surface after coating is increased to remove the coating film have.

The hydrogen peroxide and sodium metasilicate are preferably used in an amount of 1 to 10% by weight based on the total weight of the composition. When the amount of the hydrogen peroxide is less than 1% by weight, the applicability of the base material is deteriorated. Precipitation tends to occur.

As a method of applying the composition for anti-fouling coating on a substrate, it is preferable to apply the coating composition by a spray method. The thickness of the final coated film on the hinge bracket 200 is preferably 500 to 2000 Å, more preferably 1000 to 2000 Å. When the thickness of the coating film is less than 500 ANGSTROM, there is a problem that it deteriorates in the case of a high-temperature heat treatment. When the thickness is more than 2000 ANGSTROM, crystallization of a coated surface tends to occur.

Further, the composition for antifouling coating can be prepared by adding 0.1 mol of hydrogen peroxide and 0.05 mol of sodium metasilicate to 1000 mL of distilled water and then stirring.

The description of the disclosed embodiments is provided to enable any person skilled in the art to make or use the present invention. Various modifications to these embodiments will be readily apparent to those skilled in the art, and the generic principles defined herein may be applied to other embodiments without departing from the scope of the invention. Thus, the present invention is not intended to be limited to the embodiments shown herein but is to be accorded the widest scope consistent with the principles and novel features presented herein.

110, 120: door support frame 200: hinge bracket
300: first explosion proof door 300 ': second explosion proof door
310, 310 ': outer explosion-proof module 320, 320': explosion-proof channel compartment assembly
330, 330 ': first inner side explosion-proof channel part 340, 340': second inner side explosion-proof channel part
350: reinforcement member 360: hinge block
370: hinge fixing rod 400: locking device

Claims (3)

A plurality of door support frames 110 and 120 are provided around the interface 30 between the unprotected section 10 and the protection section 20 and the door support frames 110 are installed in the unprotected space 10, Other door support frames 120 are installed in the guard space 20;
A plurality of hinge brackets (200) fixed to one surface of the two door support frames (110) installed in the unprotected section (10);
A side surface portion of one side of the hinge bracket 200 which is parallel to the two door support frames 110 to which the hinge bracket 200 is fixed is connected to the hinge brackets 200 fixed to the two door support frames 110, The explosion proof door 300 and the second explosion proof door 300 '; And
And a locking device 400 provided on each of the surfaces of the first and second explosion-proof doors 300 and 300 'facing the protection zone 20,
Each of the explosion proof doors 300 and 300 '
The hinge bracket (200) according to claim 1, wherein the outer explosion-proof module (310, 310 ') is provided to form an outer appearance of the door and is provided for explosion- A plurality of hinge blocks 360 protruding from the outer explosion-proof modules 310 and 310 'so as to protrude from the outer explosion-proof modules 310 and 310' 310 ', 310', 310 ', 310', 310 ', 310', 310 ', 310' and 310 ', respectively, 310 'in the inner space of the outer explosion-proof module 310, 310', and a second inner-side explosion-proof channel part 340, 340 ' And an explosion-proof channel compartment assembly (320, 320 ') for partitioning the first and second inner explosion-proof channel sections (340, 340'),
The first inner explosion-proof channel part 330 and 330 'includes a first explosion-proof material 333 and 333' filled in the inner space of the outer explosion-proof module 310 and 310 ' The internal explosion-proof channel part (340, 340 ') includes a second explosion-proof material (342, 342') filled in the inner space of the external explosion-proof module (310, 310 '
Explosion - proof device for security facilities. The method according to claim 1,
The outer explosion-proof module (310, 310 ') includes a first outer frame (311, 311') forming one side parallel to the height direction of the door; A second outer frame frame (312, 312 ') arranged symmetrically with the first outer frame frame (311, 311') and forming a second frame parallel to the height direction of the door; And a third outer side frame 313 connected to the upper ends of the first outer frame frames 311 and 311 'and the second outer frame frames 312 and 312' in the longitudinal direction and having a side edge parallel to the width direction of the door, Border frames 313 and 313 '; And a fourth outer side frame 314 connected to the lower ends of the first outer frame frames 311 and 311 'and the second outer frame frames 312 and 312' in the longitudinal direction and forming a second frame parallel to the width direction of the door Border frames 314 and 314 '; An outer explosion-proof front plate 315, 315 'connected to one side of all of the outer frame frames 311, 311', 312, 312 ', 313, 313', 314, 314 'to form a front face of the door; 315 ', 315', 315 ', 315', 315 ', 315', 315 ', 315', 315 'and 315' are connected to the other side of both of the outer frame frames 311, 311 ', 312, 312', 313, 313 ' (316, 316 ') which form an outer explosion-proof back plate (316, 316'),
The explosion-proof channel dividing assembly 320 or 320 'includes a first space dividing frame 313 and a second space dividing frame 313', which are partially connected to the inner surfaces of the outer explosion-proof backplane 316 and 316 'and the first outer frame 311 and 311' (321, 321 '); Are symmetrically arranged with respect to the first space dividing frames 321 and 321 'and are partly connected to the inner surfaces of the outer explosion-proof backplanes 316 and 316' so as to be connected to the second outer frame 312 and 312 ' A second spacing frame (322, 322 ') spaced apart; A third space dividing frame 323, 323 ', both sides of which are connected to the upper ends of the first space dividing frames 321, 321' and the second space dividing frames 322, 322 '; A fourth space partition frame 324, 324 ', both sides of which are connected to the first space partitioning frame 321, 321' and the lower end of the second space partitioning frame 322, 322 '; And a space partition which is connected to one side of all of the space partition frames 321, 321 ', 322, 322', 323, 323 ', 324 and 324' and is disposed adjacent to the outer side explosion- proof front plates 315 and 315 ' Includes a diaphragm 325,
The first inner explosion-proof channel units 330 and 330 'are provided between the space partition plate 325 and the outer explosion-proof front plates 315 and 315', and the second inner explosion-proof channel units 340 and 340 ' Is provided between the space dividing partition plate (325) and the outer explosion-proof back plate (316, 316 ').
Explosion - proof device for security facilities. 3. The method of claim 2,
The first inner explosion-proof channel portions 330 and 330 'may include first channel spaces 331 and 331' between the space partition plate 325 and the outer explosion-proof front plates 315 and 315 ' The second channel spaces 332 and 332 'between the frames 322 and 322' and the second outer frame frames 312 and 312 ', the first channel spaces 331 and 331' and the second channel spaces 332 ' 333 'embedded in the first explosion-proof material 333, 333' and the space partition plate 325 and the outer explosion-proof front plates 315, 315 'embedded in the first explosion-proof material 333, 333' And Kevlar mesas 334 and 334 'disposed between the first and second surfaces,
The second inner expansible channel sections 340 and 340 'are formed in the inner space of each of the space dividing frames 321, 321', 322, 322 ', 323, 323', 324 and 324 ', the space partition plate 325, The third channel spaces 341 and 341 'formed inside the explosion-proof rear plates 316 and 316' and the second explosion-proof material 342 and 342 'filled in the third channel spaces 341 and 341' Including,
, Wherein the first explosion-proof material (333, 333 ') is sand and the second explosion-proof material (342, 342') is concrete.
Explosion - proof device for security facilities.

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