KR102637712B1 - Precast explosion proof panel - Google Patents

Abstract

The disclosed content integrates the sacrificial structure with the damping structure in the explosion-proof panel, so it can be applied even in cases of large explosive force such as the explosion of hydrogen gas, and the explosion-proof panel is formed in the form of precast, so it can be constructed on floors, vertical walls, and ceiling slabs, etc. This relates to a precast explosion-proof panel that has the advantage of being able to increase the convenience of construction.
The disclosed contents include a panel base that is manufactured using a precast method and is destroyed when hydrogen gas explodes and absorbs the shock of the explosion; the panel base is spaced at regular intervals in the X-axis and Y-axis directions and is formed to penetrate the panel base. A through-hole portion that secures the cast explosion-proof panel to the wall of the hydrogen gas storage facility, is formed at the top of the panel base portion and extends in the direction of the Y-axis of the panel base portion, and includes all positions where the through-hole portion is formed in the direction of the X-axis. formed at regular intervals and having a constant width to maintain the shape of the precast explosion-proof panel, and a load support part formed at the top of the panel base and formed between the load support parts to plastically deform when hydrogen gas explodes. A damping part that absorbs the explosion shock, a damping fixing part that is spaced at a certain distance in the X-axis and Y-axis directions at the top of the damping part, and both ends are fixed to the load supporter to secure the damping part to the panel base, and the load A precast explosion-proof panel including a rigid support part that is formed in the space formed by the support part, the damping part, and the damping fixing part and provides rigidity to the part in contact with the wall of the hydrogen gas storage facility is presented as an example.

Description

Precast explosion-proof panel {PRECAST EXPLOSION PROOF PANEL}

The disclosed content relates to an explosion-proof panel for an underground hydrogen storage facility in a precast form combining a sacrificial structure and a damping structure.

Unless otherwise indicated herein, the matters described in this identification are not prior art to the claims of this application, and are not admitted to be prior art by virtue of being described in this identification.

Recently, as the demand for carbon neutrality increases around the world, the use of electric energy using hydrogen gas is on the rise.

However, when hydrogen gas explodes, the shock causes enormous damage, so it can be difficult to store or transport it.

Accordingly, inventions for explosion-proof panels are emerging to respond to hydrogen gas explosions that may occur while storing hydrogen gas at electric vehicle charging stations, etc.

As an example of an invention for such an explosion-proof panel, Korean Patent Registration No. 10-1738823 (registered on May 16, 2017) includes a high-corrosion-resistant steel plate with a tensile strength of 410 to 490 MPa or a high-strength steel plate with a tensile strength of 700 to 760 MPa. The central bearing plate, a pair of foamed aluminum plates disposed on both sides of the central bearing plate, and a tensile strength of each of the two sides of the pair of foamed aluminum plates on the side opposite to the side on which the central bearing plate is disposed are 410. It includes an outer plate formed of a pair of high corrosion-resistant steel plates with a tensile strength of 700 to 760 MPa or a pair of high-strength steel plates with a tensile strength of 700 to 760 MPa, and the central load-bearing plate and the outer plate are made of the same high corrosion-resistant steel plate or high-strength steel plate. It consists of a foamed aluminum plate, characterized in that a ceramic adhesive layer mixed with ceramic and adhesive is interposed between the central load-bearing plate and the pair of foamed aluminum plates and between the pair of foamed aluminum plates and the outer plate. An explosion-proof panel is disclosed.

In addition, in Korean Patent Registration No. 10-1250903 (registered on March 29, 2013), an aluminum foam is made of a plate-shaped shell material facing each other at intervals, and aluminum foam that is filled between the shell materials to absorb external pressure. A panel is formed, and a concrete plate having a thickness is installed in contact with the outer surface of the indoor skin of the aluminum foam panel, so that the aluminum foam panel and the concrete plate are integrally combined, and the aluminum foam panel has a plurality of side surfaces. It has a structure in which the aluminum foam panels are connected to each other, and a connecting beam of H-shaped cross-section having a first flange, a web, and a second flange is disposed between the sides where the aluminum foam panels are connected to each other, and a connecting beam of H-shaped cross section is placed on both sides of the web of the connecting beam. Between the flange and the second flange, the sides of both aluminum foam panels are inserted and fastened by inserting a fastening member to penetrate the first flange, the aluminum foam panel, and the second flange, so that the aluminum foam panels are continuous with each other laterally. A composite explosion-proof wall characterized by having a combined structure is disclosed.

However, although the explosion-proof panels described above can function as mechanical dampers, they are insufficient to function as structural dampers.

As an example of an explosion-proof panel that is structurally capable of absorbing shock, Republic of Korea Patent Registration No. 10-1593566 (registered on February 3, 2016) describes a sandwich structure in which an aluminum foam panel made of expanded aluminum and a bulletproof plate are laminated between two outer skin plates. A plurality of bulletproof and explosion-proof panel units that exhibit bulletproof and shock-absorbing functions are attached in the required number to the front of a back plate made of a thick steel plate, and a thick front plate is placed in front of the bulletproof and explosion-proof panel unit. An explosion-proof wall is disclosed that has a structure arranged at intervals in each direction, exhibits excellent explosion-proof performance through efficient shock absorption and excellent bullet-proof performance against bullets, etc., and can be quickly constructed through rapid assembly.

However, the explosion-proof panel structurally capable of absorbing shock as described above still had a problem in that it was difficult to apply in cases of strong explosive force such as a hydrogen gas explosion because the panel was not provided with a sacrificial member.

1. Republic of Korea Patent Registration No. 10-1738823 (registered on May 16, 2017) 2. Republic of Korea Patent Registration No. 10-1250903 (registered on March 29, 2013) 3. Republic of Korea Patent Registration No. 10-1593566 (registered on February 3, 2016)

For the safety of underground hydrogen storage and hydrogen charging facilities, we aim to provide an explosion-proof panel that can be applied even in cases of large explosive force such as a hydrogen gas explosion, and is convenient to install on floors, vertical walls, and ceiling slabs.

Additionally, it is not limited to the technical challenges described above, and it is obvious that other technical challenges may be derived from the description below.

The disclosed content includes a panel base that is manufactured using a precast method and is destroyed when hydrogen gas explodes and absorbs the shock of the explosion; the panel base is formed at regular intervals in the directions of the X and Y axes, and A through hole portion is formed to penetrate the panel base and secure the precast explosion-proof panel to the wall of the hydrogen gas storage facility, and is formed at the top of the panel base and runs in the front and rear direction of the Y axis of the panel base. A load support part that is formed to extend and is spaced at a certain distance in the direction of the When hydrogen gas explodes, it is plastically deformed and absorbs the shock of the explosion. A damping pipe is formed at a certain distance in the direction of the a damping fixing part that secures the damping part to the panel base, and a rigid support part that is formed in a space surrounded by the load support part, the damping part, and the damping fixing part and provides rigidity to the part in contact with the hydrogen gas storage facility. A cast explosion-proof panel is presented as an example.

According to a preferred feature of the disclosed content, the panel base portion includes a concrete member formed by a precast method using a cement concrete composition and a plurality of through hole forming members formed at a location where the through hole portion is to be formed. do.

According to a preferred feature of the disclosed content, the through hole portion is formed at a predetermined distance from the lower part of the panel base to the upper direction and is formed at a predetermined interval in the direction of the X and Y axes of the panel base to form a plurality of threads. A plurality of first through holes into which (Thread) bolts are respectively inserted and a plurality of fixing nuts that secure the plurality of thread bolts are accommodated, and from the top of the plurality of first through holes the top of the panel base. It is formed to extend to and includes a plurality of second through holes into which the plurality of thread bolts are inserted.

According to a preferred feature of the disclosed content, the load support portion is formed to have a plurality of support member bodies formed in the shape of upper and lower beams at the top of the panel base portion, and each of the plurality of support member bodies is formed to have a constant width on both sides of the lower part of the plurality of support member bodies. A plurality of wing members that secure the plurality of support member bodies to the top of the panel base are formed on each upper part of the plurality of support member bodies, and are formed at the same position as the through hole portion to insert a thread bolt. It includes a plurality of support member holes.

According to a preferred feature of the disclosed content, the damping portion includes a plurality of pipe members formed in the shape of a pipe at the top of the panel base portion and extending in the front and rear direction of the Y axis of the panel base portion, and each of the plurality of pipe members. It includes a plurality of filling members filled within the.

According to a preferred feature of the disclosed content, the plurality of filling members are formed of a cement mortar composition.

According to a preferred feature of the disclosed content, the damping fixing part includes a plurality of damping fixing members formed to extend in the direction of both ends of the The fixing member is formed so that the height of each upper end is the same as the height of the upper end of the load support unit.

According to a preferred feature of the disclosed content, the rigid support unit includes a plurality of foam resin members, and the plurality of foam resin members apply a composition for forming a resin foam containing gas bubbles to the load. It is formed by filling the space surrounded by the support part, damping part, and damping fixing part and then drying it.

According to a preferred feature of the disclosed content, the precast explosion-proof panel includes a panel base forming step of forming the panel base by a precast method, a through hole forming step of forming the through hole at the top of the panel base, A load support part forming step of forming the load support part at an upper end of the panel base part, a damping part forming step of forming the damping part at an upper end of the panel base part, and a damping fixing part forming the damping fixing part at an upper end of the damping part. It is formed by forming a rigid support portion and forming the rigid support portion in a space surrounded by the load support portion, the damping portion, and the damping fixing portion.

According to the precast explosion-proof panel according to an embodiment of the disclosed content, the sacrificial structure and the damping structure are integrated into the explosion-proof panel, so it can be applied even when the explosive force is large, such as an explosion of hydrogen gas. In addition, since the explosion-proof panel is formed in the form of precast, it can be installed on floors, vertical walls, and ceiling slabs, which has the advantage of increasing the convenience of construction.

The effects of the present invention are not limited to the effects mentioned above, and other effects not mentioned will be clearly understood by those skilled in the art from the description of the claims.

1 is a diagram showing a state of use of a precast explosion-proof panel according to an embodiment of the disclosed content.
2 is a plan view of a precast explosion-proof panel according to one embodiment of the disclosed subject matter.
3 is a cross-sectional view of a precast explosion-proof panel according to one embodiment of the disclosed subject matter.
Figure 4 is a diagram showing the operating state of a precast explosion-proof panel according to an embodiment of the disclosed content.
5 is a cross-sectional view of a precast explosion-proof panel according to another embodiment of the disclosed subject matter.
Figure 6 is a block diagram of the formation process of a precast explosion-proof panel according to an embodiment of the disclosed content.
Figure 7 is a schematic diagram of the formation process of a precast explosion-proof panel according to an embodiment of the disclosed content.

Hereinafter, the configuration, operation, and effects of the preferred embodiment will be examined with reference to the attached drawings. For reference, in the drawings below, each component is omitted or schematically depicted for convenience and clarity, and the size of each component does not reflect the actual size. In addition, the same reference numerals refer to the same components throughout the specification, and reference numerals for the same components in individual drawings will be omitted.

Figure 1 is a diagram showing a state of use of a precast explosion-proof panel according to an embodiment of the disclosed content.

According to one embodiment of the disclosed content, the precast explosion-proof panel 10 is to be respectively inserted into a plurality of thread bolts 30 formed on the wall 20 of the hydrogen underground storage facility, as shown in FIG. 1(a). You can.

As shown in FIG. 1 (b), the plurality of thread bolts 30 inserted into the precast explosion-proof panel 10 are each penetrated into the precast explosion-proof panel 10 and then a plurality of fixing nuts 40 ) can be respectively fastened and fixed.

Accordingly, the precast explosion-proof panel 10 can be constructed by a simple method of installing by inserting a plurality of the thread bolts 30, so it can be installed not only on the vertical walls of hydrogen underground storage facilities, but also on floors or ceiling slabs, etc. Storage facilities can be safely protected from gas explosions.

Figure 2 is a plan view of a precast explosion-proof panel according to an embodiment of the disclosed content, and Figure 3 is a cross-sectional view of a precast explosion-proof panel according to an embodiment of the disclosed content.

According to one embodiment of the disclosed content, the precast explosion-proof panel 10, as shown in FIGS. 1 to 3, includes a panel base portion 100, a through-hole portion 200, a load support portion 300, and a damping portion ( 400), a damping fixing part 500, and a rigid support part 600.

Here, the panel base portion 100 may be manufactured using a precast method. The panel base portion 100 is destroyed when hydrogen gas explodes and can absorb the shock of the explosion.

Additionally, the panel base portion 100 according to an embodiment of the disclosed content may include a concrete member 110 and a plurality of through-hole forming members 120.

Here, the concrete member 110 may be formed of a cement concrete composition by a precast method.

Additionally, the plurality of through-hole forming members 120 may be formed respectively at positions where the through-hole portion 200 is to be formed. The plurality of through hole forming members 120 may each be removed from the panel base portion 100 when the through hole portion 200 is formed.

Additionally, when the panel base portion 100 is formed from a cement concrete composition, it may be difficult to form the through-hole portion 200 by drilling the concrete after forming the panel base portion 100.

Therefore, when forming the panel base portion 100, the panel base portion 100 can be formed by including a plurality of through-hole forming members 120 in advance at the position where the through-hole portion 200 is to be formed.

According to one embodiment of the disclosed content, the through-hole portions 200 may be formed at regular intervals in the directions of the X and Y axes of the panel base portion 100, as shown in FIGS. 1 to 3. The through hole portion 200 may be formed to penetrate the panel base portion 100. The precast explosion-proof panel 10 can be fixed to the wall 20 of a hydrogen gas storage facility by the through-hole portion 200.

Additionally, the through hole portion 200 according to an embodiment of the disclosed content may include a plurality of first through holes 210 and a plurality of second through holes 220.

Here, the plurality of first through holes 210 may be formed at a certain distance from the bottom of the panel base 100 to the top. The plurality of first through holes 210 may be formed at regular intervals in the X-axis and Y-axis directions of the panel base portion 100, respectively. A plurality of thread bolts 30 may be respectively inserted into the plurality of first through holes 210 . A plurality of fixing nuts 40 that respectively secure the plurality of thread bolts 30 may be accommodated in the plurality of first through holes 210 .

Additionally, the plurality of second through holes 220 may be formed to extend from the top of the plurality of first through holes 210 to the top of the panel base portion 100, respectively. A plurality of thread bolts 30 may be inserted into the plurality of first through holes 210 and the plurality of second through holes 220, respectively.

Additionally, the plurality of first through holes 210 may be formed to have a larger diameter than the plurality of second through holes 220.

According to one embodiment of the disclosed content, the load support portion 300 may be formed at the top of the panel base portion 100, as shown in FIGS. 1 to 3. The load support portion 300 may be formed to extend in the front and rear direction of the Y axis of the panel base portion 100. The load support portions 300 may be formed to be spaced apart at regular intervals in the direction of the X-axis of the panel base portion 100. The load support portion 300 may be formed to have a constant width to include all of the through hole portion 200. The load support portion 300 can maintain the shape of the precast explosion-proof panel 10.

Additionally, the load support unit 300 according to an embodiment of the disclosed content may include a plurality of support member bodies 310, a plurality of wing members 320, and a plurality of support member holes 330.

Here, the plurality of support member bodies 310 may be formed in the shape of upper and lower beams, respectively, at the upper end of the panel base portion 100.

Additionally, the plurality of wing members 320 may be formed on both sides of the lower portion of the plurality of support member bodies 310 to have a constant width. The plurality of wing members 320 may respectively secure the plurality of support member bodies 310 to the upper end of the panel base portion 100.

In addition, the plurality of support member holes 330 may be formed on each upper part of the plurality of support member bodies 310. The plurality of support member holes 330 may each be formed at the same position as the through hole portion 200. Threaded bolts 30 may be inserted into each of the plurality of support member holes 330.

Additionally, the load support portion 300 may be formed of a material selected from the group consisting of general structural carbon steel, general structural rolled steel, hot rolled steel, and mixtures thereof.

According to one embodiment of the disclosed content, the damping part 400 may be formed at the top of the panel base part 100, as shown in FIGS. 1 to 3. The damping portion 400 can absorb the explosion shock while being plastically deformed when hydrogen gas explodes.

Additionally, the damping unit 400 according to an embodiment of the disclosed content may include a plurality of pipe members 410 and a plurality of filling members 420.

Here, the plurality of pipe members 410 may each be formed in the shape of a pipe at the top of the panel base portion 100. The plurality of pipe members 410 may be formed to extend in the front and rear directions of the Y axis of the panel base portion 100, respectively.

Additionally, the plurality of filling members 420 may be filled inside each of the plurality of pipe members 410.

And the plurality of pipe members may be formed of a material selected from the group consisting of general structural carbon steel, general structural rolled steel, hot rolled steel, and mixtures thereof.

Additionally, the plurality of filling members may be formed of a cement mortar composition.

According to one embodiment of the disclosed content, the damping fixing part 500 may be formed at a certain interval in the directions of the X and Y axes at the top of the damping part 400, as shown in FIGS. 1 to 3 there is. Both sides of the damping fixing part 500 are fixed to the load support part 300, so that the damping part 400 can be fixed to the panel base part 100.

Additionally, the damping fixing member 500 according to an embodiment of the disclosed content may include a plurality of damping fixing members 510.

Here, the plurality of damping fixing members 510 may be formed to extend in the direction of both ends of the X-axis of the panel base portion 100, respectively. Both sides of the plurality of damping fixing members 510 may be respectively fixed to the load support portion 300.

Additionally, the height of the upper end of each of the plurality of damping fixing members 510 may be formed to be the same as the height of the upper end of the load support part 300.

And the plurality of damping fixing members 510 may each be formed of a material selected from the group consisting of general structural carbon steel, general structural rolled steel, hot rolled steel, and mixtures thereof.

According to one embodiment of the disclosed content, the rigid support part 600 is located in a space surrounded by the load support part 300, the damping part 400, and the damping fixing part 500, as shown in FIGS. 1 to 3. can be formed. The rigid support portion 600 can provide rigidity to the portion in contact with the underground hydrogen storage facility.

In addition, the rigid support part 600 according to an embodiment of the disclosed content may include a plurality of foam resin members 610.

Here, the plurality of foam resin members 610 are filled with a composition for forming resin foam containing gas bubbles in the space surrounded by the load support portion 300, the damping portion 400, and the damping fixing portion 500. It can be formed by drying.

Additionally, each of the plurality of foam resin members 610 may be formed to have a strength of a certain range or more.

Figure 4 is a diagram showing the operating state of a precast explosion-proof panel according to an embodiment of the disclosed content.

According to one embodiment of the disclosed content, the precast explosion-proof panel 10 has rigidity above a certain range in order to support the load received from the wall 20 or other facilities, as shown in FIG. 4(a) in normal times. It may be necessary.

In addition, in order to support the load applied to the precast explosion-proof panel 10, the precast explosion-proof panel 10 may include the panel base portion 100 and the rigid support portion 600 that provide rigidity.

And when hydrogen gas explodes, the precast explosion-proof panel 10 is plastically deformed, as shown in FIG. 4(b), and has ductility over a certain range to absorb the impact of the explosion and not damage the wall 20. This may be necessary.

In addition, the precast explosion-proof panel 10 may include a panel base portion 100 that absorbs the shock of an explosion while being destroyed to absorb the shock of an explosion, and a damping portion 400 that absorbs the shock of an explosion while being plastically deformed. You can.

Figure 5 is a cross-sectional view of a precast explosion-proof panel according to another embodiment of the disclosed content.

According to another embodiment of the disclosed content, the damping part 400 of the precast explosion-proof panel 10 is a laminated type in which a plurality of embossing panels (not shown) are stacked, as shown in FIG. 5(a). May include dampers.

Here, a plurality of the embossed panels (not shown) may be stacked to have the same shape in the vertical direction.

According to another embodiment of the disclosed content, the damping portion 400 of the precast explosion-proof panel 10 includes a stacked damper in which a plurality of embossed panels (not shown) are stacked, as shown in FIG. 5(b). can do.

Here, a plurality of the embossed panels (not shown) may be stacked so that each has a shape that is symmetrical in the vertical direction.

Figure 6 is a block diagram of the formation process of a precast explosion-proof panel according to an embodiment of the disclosed content, and Figure 7 is a schematic diagram of the formation process of a precast explosion-proof panel according to an embodiment of the disclosed content.

As shown in FIGS. 1 to 7, the precast explosion-proof panel 10 according to an embodiment of the disclosed content includes a panel base forming step (S100), a through-hole forming step (S200), and a load support forming step ( It may include a damping part forming step (S300), a damping part forming step (S400), a damping fixing part forming step (S500), and a rigid support forming step (S600).

Here, the panel base forming step (S100) may be a step of forming the panel base portion 100 using a precast method, as shown in FIG. 7(a).

Additionally, the through-hole forming step (S200) may be a step of forming the through-hole portion 200 at the top of the panel base portion 100, as shown in FIG. 7(b).

And the load support portion forming step (S300) may be a step of forming the load support portion 300 at the top of the panel base portion 100, as shown in FIG. 7(c).

Additionally, the damping part forming step (S400) may be a step of forming the damping part 400 on the top of the panel base part 100, as shown in FIG. 7(d).

And the damping fixing part forming step (S500) may be a step of forming the damping fixing part 500 on the top of the damping part 400, as shown in FIG. 7(e).

In addition, in the rigid support forming step (S600), as shown in FIG. 7(f), the rigid support portion 600 is formed by the load support portion 300, the damping portion 400, and the damping fixing portion 500. It may be a step of forming in an enclosed space.

Although preferred embodiments of the present invention have been described above with reference to the accompanying drawings, the embodiments described in this specification and the configuration shown in the drawings are only one of the most preferred embodiments of the present invention and do not represent the entire technical idea of the present invention. Since this is not the case, it should be understood that there may be various equivalents and modifications that can replace them at the time of filing this application. Therefore, the embodiments described above should be understood in all respects as illustrative and not restrictive, and the scope of the present invention is indicated by the claims described later rather than the detailed description, and the meaning and scope of the claims and their All changes or modified forms derived from the equivalent concept should be construed as falling within the scope of the present invention.

100: Panel base part
110: Concrete member
120: Through-hole forming member
200: Through hole part
210: first through hole
220: second through hole
300: load support part
310: Support member body
320: wing member
330 ; Support member hole
400: Damping part
410: Pipe member
420: Filling member
500: Damping fixing part
510: Damping fixing member
600: rigid support
610: Foam resin member
10: Precast explosion-proof panel
20: wall
30: thread bolt
40: fixing nut
50: Hydrogen gas storage facility
60: hydrogen gas
S100: Panel base forming step
S200: Through-hole forming step
S300: Load support forming step
S400: Damping part formation step
S500: Damping fixture formation stage
S600: Rigid support formation stage

Claims (9)

A panel base that is manufactured using a precast method and is destroyed when hydrogen gas explodes, absorbing the shock of the explosion;
Through-hole portions formed at regular intervals in the X-axis and Y-axis directions of the panel base portion and formed to penetrate the panel base portion to secure the precast explosion-proof panel to the wall of the hydrogen gas storage facility;
It is formed at the top of the panel base, extends in the front and rear direction of the Y-axis of the panel base, is formed at regular intervals in the A load support part that maintains the shape of the explosion-proof panel;
A damping portion formed at the top of the panel base portion to absorb the explosion shock while being plastically deformed when hydrogen gas explodes;
Damping fixing parts formed on the top of the damping part at regular intervals in the X-axis and Y-axis directions and fixed on both sides to the load support part to fix the damping part to the panel base; and
Characterized in that it includes a rigid support part formed in the space surrounded by the load support part, the damping part and the damping fixing part and providing rigidity to the part in contact with the hydrogen gas storage facility,
The load support part,
A plurality of support member bodies formed in the shape of upper and lower beams at the upper end of the panel base portion;
a plurality of wing members formed on both sides of the lower portions of the plurality of support member bodies to have a certain width and fixing the plurality of support member bodies to the upper end of the panel base portion; and
A precast explosion-proof panel comprising: a plurality of support member holes formed on each upper part of the plurality of support member bodies and at the same position as the through hole portion, into which threaded bolts are inserted.
In claim 1,
The panel base part,
A concrete member formed by a precast method using a cement concrete composition; and
A precast explosion-proof panel comprising a plurality of through-hole forming members formed at a position where the through-hole portion is to be formed.
In claim 1,
The through hole part,
It is formed at a predetermined distance from the lower part of the panel base to the upper direction, and is formed at a predetermined interval in the X-axis and Y-axis directions of the panel base, so that a plurality of thread bolts are respectively inserted and the plurality of thread bolts are fixed. a plurality of first through holes in which a plurality of fixing nuts are accommodated; and
A precast explosion-proof panel comprising a plurality of second through holes formed to extend from the top of the plurality of first through holes to the top of the panel base into which the plurality of thread bolts are inserted.
delete In claim 1,
The damping part,
a plurality of pipe members formed in the shape of a pipe at the top of the panel base and extending in the front and rear directions of the Y-axis of the panel base; and
A precast explosion-proof panel comprising a plurality of filling members filled within each of the plurality of pipe members.
In claim 5,
The plurality of filling members are,
A precast explosion-proof panel, characterized in that it is formed from a cement mortar composition.
In claim 1,
The damping fixing part is,
A plurality of damping fixing members formed to extend in the direction of both ends of the X-axis of the panel base and each side of which is fixed to the load support unit,
The plurality of damping fixing members,
A precast explosion-proof panel, characterized in that the height of each upper end is formed to be the same as the height of the upper end of the load support unit.
In claim 1,
The rigid support part,
Includes a plurality of foam resin members,
The plurality of foam resin members are,
A precast explosion-proof panel, characterized in that it is formed by filling the space surrounded by the load support part, the damping part and the damping fixing part with a composition for forming a resin foam containing gas bubbles and then drying it.
In claim 1,
The precast explosion-proof panel is,
A panel base forming step of forming the panel base using a precast method;
A through-hole forming step of forming the through-hole portion at the top of the panel base portion;
A load support portion forming step of forming the load support portion at the top of the panel base portion;
A damping portion forming step of forming the damping portion at the top of the panel base portion;
A damping fixing part forming step of forming the damping fixing part at the top of the damping part; and
A precast explosion-proof panel formed by a rigid support forming step of forming the rigid support in a space surrounded by the load support, damping, and damping fixing parts.

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