JP6543071B2 - Protective structure - Google Patents

Description

  The present invention relates to a protective structure.

A flammable gas supply facility such as a hydrogen station is required to have a structure capable of minimizing damage by the flammable gas even in the event of an explosion accident, as well as ensuring a smooth flammable gas supply function. The installation of a protective wall is considered as one of the effective means for this.
For example, Patent Document 1 is a technology relating to a protective wall of a flammable gas supply facility.

Patent Document 1 has a configuration in which a protective wall is provided on the outer periphery of a gas supply facility that supplies flammable gas (hydrogen gas), and the shape of the protective wall is determined by performing a simulated hydrogen gas explosion experiment and simulating blast pressure. doing. From the results, the protective wall is shaped to have a vertical part provided vertically to the ground, and a horizontal part provided horizontally on the upper part of the vertical part and having a horizontal surface with respect to the direction of travel of the shock wave. .
With this configuration, even if the height of the protective wall is kept lower than that of a conventional simple wall, the peripheral area of the gas supply facility can be protected from the shock wave generated with the hydrogen gas explosion. .

Unexamined-Japanese-Patent No. 2006-22506

  However, patent document 1 makes the measurement position of blast pressure two points on the ground same as a cylinder of combustible gas. That is, it is not intended for buildings that are built on the ground and higher than the protective wall. For this reason, when the building is constructed in proximity to the gas supply facility, it is not in a shape to protect the building from blast.

  An object of the present invention is to provide a protective structure which protects a building from blast in view of the above-mentioned fact.

The protection structure according to the invention is set up at a distance from the gas supply facility for supplying the flammable gas, and is raised from the base portion to cover one side of the gas supply facility to explode the flammable gas. From the upper part of the first wall which receives the blast of the hour, and the upper part of the first wall, the upper part of the gas supply facility is covered and extended obliquely upward, and the lower end is joined to the first wall The upper end portion is a free end portion , and has a second wall which receives a blast at the time of explosion of the combustible gas.

According to the first aspect of the present invention, the first wall is raised from the base portion at a distance from the gas supply facility, and the blast is received by the first wall at the time of explosion of the flammable gas.
Further, the second wall extends obliquely upward from the upper portion of the first wall so as to cover the upper side of the gas supply facility, and the second wall receives a blast when the flammable gas is exploded.

As a result, even if there is a building behind the gas supply facility, by providing the first wall and the second wall between the gas supply facility and the building, it is possible to blow the building at the time of the explosion of the combustible gas. The impact can be reduced.
Further, since the second wall extends obliquely upward from the upper portion of the first wall and covers the upper side of the gas supply facility, the blast is directed along the second wall away from the gas supply facility. Can be discharged into
In addition, since the free end of the second wall is away from the rear building, propagation of the blast to the rear building can be reduced in addition to the blast scattering by the free end.
In addition, since the second wall is inclined upward and not in the horizontal direction, even if the flammable gas leaks from the gas supply facility, it is possible to suppress the generation of gas stagnation on the lower surface of the second wall.

The invention according to claim 2 is the protective structure according to claim 1, wherein the free end of the second wall is exposed to the blast at the time of explosion of the flammable gas. Shock absorbing means are provided for absorbing an impact in the direction away from the first wall.

  According to the second aspect of the present invention, the impact absorbing means provided on the second wall makes the impact in the direction in which the second wall is separated from the first wall by the blast pressure at the time of explosion of the combustible gas. The shock from the blast pressure is absorbed.

  The invention according to claim 3 is the protection structure according to claim 1 or 2, wherein the gas supply facility and the first wall are installed in a gas supply chamber of a building provided with an opening facing the outside. And a third wall which is raised from the base portion at both ends of the first wall and whose upper portion is joined to the second wall is extended to the opening, the second wall The free end of the body extends from the opening to the outside of the building.

According to the third aspect of the present invention, the gas supply facility is installed in the gas supply chamber of the building, and the first wall and the third wall surround the gas supply facility and stand from the base portion of the gas supply chamber. It is raised. In addition, free ends of the second wall closing the tops of the first and third walls extend from the opening to the outside of the building.
Thereby, even if the combustible gas explodes in the gas supply chamber, the wall (back wall, ceiling and side wall) of the gas supply chamber is protected by the first wall, the second wall and the third wall. Can reduce damage to the building. As a result, the gas supply facility can be installed in the interior space of the building even in an urban area where there are few vacant lands.

  Since this invention is the said structure, it can provide the protection structure which protects a building from a blast.

It is a perspective view showing basic composition of a protection structure concerning a 1st embodiment of the present invention. It is a side view showing basic composition of a protection structure concerning a 1st embodiment of the present invention. FIG. 1 is a perspective view showing a basic configuration of a protective wall in a protective structure according to a first embodiment of the present invention. (A) is a perspective view showing the basic composition of a protective wall in a protective structure concerning a 2nd embodiment of the present invention, and (B) is a Z1-Z1 line sectional view of Drawing 4 (A). (A) is a perspective view which shows the basic composition of the protection structure which concerns on 3rd Embodiment of this invention, (B) is a Z1-Z1 line cross section of FIG. 5 (A). (A) is a perspective view which shows the basic composition of the protective wall in the protective structure which concerns on 4th Embodiment of this invention, (B) and (C) are all the fragmentary sectional views. It is a perspective view which shows the basic composition of the protection structure which concerns on 5th Embodiment of this invention. (A) is a vertical direction sectional view showing the basic composition of the protection structure concerning a 6th embodiment of the present invention, and (B) is a Z1-Z1 line sectional view of Drawing 8 (A).

First Embodiment
A protective structure according to a first embodiment of the present invention will be described using FIGS. 1 to 3.
Here, FIG. 1 is a perspective view showing a basic configuration of the protective structure according to the first embodiment, and FIG. 2 is a side view thereof. FIG. 3 is a perspective view of the protective wall.

As shown in FIGS. 1 and 2, the protective structure according to the first embodiment has a protective wall 10.
The protective wall 10 is provided between the dispenser (gas supply facility) 16 and the building 32. The dispenser 16 is a hydrogen gas filling facility for filling the vehicle 18 with hydrogen gas (flammable gas), and includes a connecting member connected to the hydrogen supply port of the vehicle 18.

  A parking space for the vehicle 18 is provided on the front side 16F of the dispenser 16, and a building 32 is built on the rear side 16B of the dispenser 16. For protection of the building 32, the distance L1 between the dispenser 16 and the building 32 is a legally required distance (for example, 6 m or more).

  The dispenser 16 and the protective wall 10 form part of a so-called hydrogen station. In addition to the above, the hydrogen station also supplies a hydrogen storage unit that supplies hydrogen gas to the dispenser 16, a compression / accumulation unit that adjusts the filling pressure of the hydrogen gas, and, optionally, for removing hydrogen from natural gas etc. Related equipment such as a reforming / refining unit will be installed. These facilities and protective walls provided on the building side of these facilities are provided in the backyard etc. as necessary, but are not shown.

  The protective wall 10 has a vertical wall (first wall) 12 raised from the ground (base portion) 14. The vertical wall 12 has a predetermined distance L2 from the rear side 16B of the dispenser 16 and has a height H1 from the ground 14 in a direction (the Y-axis direction) along the outer wall on the dispenser 16 side of the building 32 It is built.

An oblique wall (second wall) 20 is provided on the vertical wall 12.
The oblique wall 20 extends from the upper end portion (upper surface) of the vertical wall 12 in the upper oblique direction of the dispenser 16. That is, the oblique wall 20 is formed above the dispenser 16 so as to cover the dispenser 16, the lower end 20K is joined to the upper end of the vertical wall 12, and the upper end (tip) 20E is a free end. ing.

It is desirable that the length L3 in the X-axis direction of the oblique wall 20 be a length that covers the entire width of the vehicle 18 where the tip 20E of the oblique wall 20 parks on the front side 16F of the dispenser 16. That is, the diagonal wall 20 covers the dispenser 16 and the entire vehicle 18.
Further, the inclination angle (the inclination angle from the horizontal surface h to the upper side) α of the oblique wall 20 is desirably about 5 to 25 degrees (more desirably 10 to 20 degrees). Thus, retention of hydrogen gas can be suppressed at the intersection of the vertical wall 12 and the oblique wall 20.

Subsequently, a specific configuration of the protective wall 10 will be described with reference to FIG.
The vertical wall 12 has a plurality of columns 22 raised from the ground 14. A plurality of columns 22 are arranged in the Y-axis direction at a predetermined interval Y1. An H-section steel is used for the column 22, and the recesses of width D1 formed by the flange and the web of adjacent H-section steels are made to face each other.
A concrete panel 26 is inserted between the column 22 and the column 22 by inserting both ends into the recess of the adjacent column 22.

The concrete panel 26 is formed of a precast concrete plate.
The width W1 of the concrete panel 26 is substantially equal to the spacing Y1 of the columns 22, and the height H2 is smaller than the height H1 of the vertical wall 12, and a clearance up to a predetermined height in the height direction (Z-axis direction) There are several stacks. The thickness T1 (not shown) is substantially equal to the width D1 of the recess of the H-section steel.

The concrete panel 26 is formed in a dimension with rigidity to withstand blast pressure even if hydrogen gas explodes at the position of the dispenser 16.
In addition, since the concrete panel 26 has a configuration in which both ends are dropped into the recess of the column 22 and stacked, even if a part of the concrete panel 26 is damaged by the explosion of hydrogen gas, only the damaged concrete panel 26 is By removing and replacing with the new concrete panel 26, the vertical wall 12 can be easily repaired.

Similarly, the diagonal wall 20 also has a plurality of beams 24 of H-shaped steel, and the beams 24 are joined to the side surfaces of the columns 22 so as to be inclined obliquely upward. The beams 24 are disposed in the direction in which the recesses formed by the flanges and the webs face each other.
One end of the beam 24 is joined to the side of the column 22 on the dispenser 16 side, and the other end is a free end 24E.

  At this time, a reinforcing material 98 may be provided between the upper end 22E of the column 22 and the free end 24E of the beam 24. The reinforcing member 98 applies tension in a direction of lifting the free end 24E of the beam 24 using, for example, a wire or the like. Thereby, the downward deflection of the free end 24E of the beam 24 can be suppressed.

A plurality of concrete panels 28 are inserted into the recesses of adjacent beams 24 without a gap. The concrete panel 28 is formed of a precast concrete plate.
The width W1 of the concrete panel 28 is substantially equal to the space Y1 of the columns 22, the height H3 is smaller than the length L4 of the diagonal wall 20, and a plurality of the walls are stacked without gaps in the length direction. The thickness T2 is approximately equal to the width D2 of the recess of the H-section steel of the beam 24.

The concrete panel 28 is sized to have the rigidity to withstand blast pressure even if hydrogen gas explodes at the location of the dispenser 16.
In addition, since the concrete panel 28 has a configuration in which both ends are dropped and stacked in the recesses of the adjacent beams 24, the concrete panel is damaged even if part of the concrete panel 28 is damaged by the explosion of hydrogen gas. By removing only 28 and replacing it with a new concrete panel 28, the diagonal wall 20 can be easily repaired.
It is desirable that the concrete panel 26 and the concrete panel 28 be shareable as the same dimension.

According to the present embodiment, the vertical wall 12 having rigidity to withstand the blast (blast pressure) at the time of explosion of the hydrogen gas is lifted from the ground 14 at a distance L3 from the dispenser 16 and at the time of explosion of the hydrogen gas, The vertical wall 12 receives a blast.
In addition, an inclined wall 20 having rigidity to withstand the blast at the time of hydrogen gas explosion covers the upper side of the dispenser 16 and extends upward from the upper part of the vertical wall 12 at the time of hydrogen gas explosion. 20 receives a blast.

As a result, even if the building 32 is on the rear side 16B of the dispenser 16, the vertical wall 12 and the oblique wall 20 receive the blast at the time of the hydrogen gas explosion, so the influence of the blast on the building 32 can be reduced.
At this time, since the oblique wall 20 extends obliquely upward from the upper portion of the vertical wall 12, blast can be discharged along the oblique wall 20 in a direction away from the dispenser 16.

Further, since the tip end portion 20E of the oblique wall 20 can be separated from the building 32, it is possible to reduce the propagation in the direction of the building 32 in addition to the diffraction of the blast.
In addition, since the oblique wall 20 is inclined upward, not in the horizontal direction, it is possible to suppress the generation of hydrogen gas remaining on the lower surface of the oblique wall 20.

In the present embodiment, the case where the concrete panels 26 and 28 are formed of a precast concrete plate has been described. However, the material is not limited to this, and any material may be used as long as it can withstand the blast pressure at the time of explosion of hydrogen gas.
Further, when it is desired to ensure visibility on the back surface of the protective wall 10, the concrete panels 26, 28 may be formed using, for example, an impact resistant resin such as polycarbonate.

  In the present embodiment, the hydrogen gas is used as an example of the flammable gas. However, the present invention is not limited thereto, and may be another combustible gas such as propane gas.

Second Embodiment
A protective structure according to a second embodiment of the present invention will be described with reference to FIGS. 4 (A) and 4 (B). The protective structure according to the second embodiment is different from the first embodiment in that it has a protective wall 30 in which a bent portion is formed at the central portion. The differences will be mainly described.
FIG. 4A is a perspective view of the protective wall 30, and FIG. 4B is a cross-sectional view taken along line Z1-Z1 of FIG.

As shown in FIGS. 4A and 4B, the protective wall 30 has a protective wall 34A and a protective wall 34B, and the ends of the protective wall 34A and the protective wall 34B are joined by a joint 30CP. .
The protective wall 34A and the protective wall 34B are basically the same in basic configuration as the protective wall 10 described in the first embodiment, and have vertical walls 12A and 12B and diagonal walls 20A and 20B.
Moreover, the dispenser 16 is installed in the cross | intersection part of vertical wall 12A, 12B.

  In the protective wall 34A, the vertical wall 12A is constructed in the Y-axis direction, and in the protective wall 34B, the vertical wall 12B is constructed in the X-axis direction. The crossing angle β between the vertical wall 12A and the vertical wall 12B is preferably 90 degrees or more in consideration of the effective space as the protective wall 30.

The protective wall 30 of the present embodiment protects the buildings 32A and 32B from blasts due to hydrogen gas explosion even if the buildings 32A and 32B exist in two directions because a bent portion is formed at the central portion. be able to.
That is, since the protective wall 34A is provided between the dispenser 16 and the building 32A and the protective wall 34B is provided between the dispenser 16 and the building 32B, both of the buildings 32A and 32B are protected.
The other configuration is the same as that of the first embodiment, and the description is omitted.

Third Embodiment
A protective structure according to a third embodiment of the present invention will be described using FIGS. 5 (A) and 5 (B). The protective wall 40 in the protective structure according to the third embodiment differs from the protective wall 30 of the second embodiment in that the protective wall 40 is constructed of cast-in-place reinforced concrete. The differences will be mainly described.
FIG. 5A is a perspective view of the protective wall 40, and FIG. 5B is a cross-sectional view taken along line Z1-Z1 of FIG. 5A.

  As shown in the perspective view of FIG. 5 (A), the protective wall 40 is provided at the intersection of two buildings 32A, 32B. The protective wall 40 has vertical walls 42, 43, 44 of reinforced concrete, and the vertical wall 42 of the protective wall 40 is constructed along the side wall on the dispenser 16 side of the building 32A, and the vertical wall 44 of the protective wall 40 is , And the side wall of the building 32B on the dispenser 16 side.

5B, the vertical wall 43 is constructed facing the intersection of the vertical wall 42 and the vertical wall 44, and bisects the intersection angle of the vertical wall 42 and the vertical wall 44. It is formed in the direction orthogonal to the center line LC.
Diagonal walls 46, 47, 48 are provided at the upper end portions of the vertical walls 42, 43, 44 so as to extend in the direction covering the dispenser 16, respectively. The oblique wall 47 is not shown.

In addition, a storage tank 36 for storing hydrogen gas and supplying the hydrogen gas to the dispenser 16 is provided between the protective wall 40 and the dispenser 16. In addition, between the storage tank 36 and the dispenser 16 there is provided an auxiliary protective wall 38.
The auxiliary protective wall 38 is constructed of reinforced concrete in a flat plate shape. In addition, the auxiliary protective wall 38 is constructed to have a size higher than the height of the storage tank 36 and larger than the width of the storage tank 36.

With this configuration, the vertical wall 42 and the diagonal wall 46, and the vertical wall 43 and the diagonal wall 47 protect the building 32A from the blast even if the hydrogen gas explodes at the position of the dispenser 16. Further, the vertical wall 44 and the oblique wall 48, and the vertical wall 43 and the oblique wall 47 protect the building 32B from the blast.
Also, the auxiliary protective wall 38 protects the storage tank 36 from blasts, even if the hydrogen gas detonates at the location of the dispenser 16. Furthermore, even if hydrogen gas explodes at the position of the storage tank 36, the protection wall 40 protects the buildings 32A, 32B from blast.

  Thereby, even if the buildings 32A and 32B built in the crossing two directions are provided at the rear (rear) of the protective wall 40, the two buildings 32A and 32B can be protected from blast. The other configuration is the same as that of the second embodiment, and the description will be omitted.

Fourth Embodiment
A protection structure according to a fourth embodiment of the present invention will be described using FIGS. 6 (A) to 6 (C). The protective wall 50 in the protective structure according to the fourth embodiment is different from the protective wall 40 of the third embodiment in that a plurality of through holes 62 are formed in the wall surface of the protective wall 50. The differences will be mainly described.

  As shown in FIG. 6 (A), the protective wall 50 has longitudinal walls 52, 53, 54 of reinforced concrete and oblique walls 56, 57, 58 of reinforced concrete. Further, in each of the vertical walls 52, 53, 54 and the diagonal walls 56, 58, a plurality of through holes 62 penetrating the wall in the thickness direction are formed.

Through hole 62, a maximum diameter 200mm, the density of the through holes 62, up to 40 in case of up to 3 / ^{m 2,} up to 10 in case of a diameter of 100 mm / ^{m 2,} diameter 50mm in the case of a diameter of 200mm It is desirable to be about / m ² .
Thus, light can be introduced to the back side of the protective wall 50.
Further, even if hydrogen gas leaks from the dispenser 16 or the storage tank 36, the gas retention can be suppressed.

  As shown in FIG. 6B, the through hole 62 may be tapered. The taper may be such that the diameter d1 on the explosion occurrence side (F side) where the dispenser 16 is installed is larger than the diameter d2 on the back side (B side) (D1> D2). As a result, since the blast pressure falling to the back side is pushed back to the explosion generation side at the hole wall portion of the through hole 62, the blast pressure falling to the back side can be reduced.

  Further, as shown in FIG. 6C, the taper d of the through hole 62 may be set such that the diameter d3 of the explosion occurrence side (F side) is small and the diameter d4 of the back side (B side) is large (D3 < D4). As a result, since the blast pressure that has slipped to the back side is quickly released, the blast pressure that slips to the back side can be reduced.

In addition, you may provide the through-hole 62 of this embodiment in the protective wall 10 as described in 1st Embodiment, and the protective wall 30 as described in 2nd Embodiment.
The other configuration is the same as that of the third embodiment, and the description will be omitted.

Fifth Embodiment
A protective structure according to a fifth embodiment of the present invention will be described with reference to FIG.
The protective structure according to the fifth embodiment has a protective wall 60, and in that an auxiliary protective wall 64 for blocking blast air is provided between the vertical wall 12 of the protective wall 60 and the building 32, the first embodiment. It is different from. The differences will be mainly described.

As shown in the perspective view of FIG. 7, the protective wall 60 has a vertical wall 12 made of reinforced concrete, and on the vertical wall 12 has a diagonal wall 20 made of reinforced concrete. The protective wall 60 is the same in basic size and shape as the protective wall 10 of the first embodiment except for the material.
Between the vertical wall 12 and the building 32 on the back side of the protective wall 60, a secondary protective wall 64 is provided at a distance L4 from the vertical wall 12. The auxiliary protective wall 64 is made of reinforced concrete and is constructed parallel to the vertical wall 12.

In addition, a storage tank 36 which stores hydrogen in the form of gas or liquid and supplies it to the dispenser 16 is provided between the vertical wall 12 and the auxiliary protective wall 64. The distance between the storage tank 36 and the building 32 is L5 (the legal separation distance is 6 m or more).
Thereby, even if hydrogen gas explodes at the position of the dispenser 16, the protective wall 60 shuts off blast, thereby protecting the storage tank 36 and the building 32.
Also, even if the hydrogen gas explodes at the location of the storage tank 36, the auxiliary protective wall 64 blocks the blast, thereby protecting the building 32.

In addition, although the protective wall 60 of this embodiment and the auxiliary protective wall 64 were all demonstrated by the case of a reinforced concrete structure, it is not limited to this, The pillar 22 of H-shaped steel demonstrated in 1st Embodiment , Beams 24 and concrete panels 26, 28.
The other configuration is the same as that of the first embodiment, and the description is omitted.

Sixth Embodiment
A protective structure according to a sixth embodiment of the present invention will be described with reference to FIGS. 8 (A) and 8 (B). The protection wall 70 in the protection structure according to the sixth embodiment is different from the first embodiment in that a part of the protection wall 70 and the dispenser 16 are provided inside a building 66. The differences will be mainly described.
Here, FIG. 8 (A) is a vertical cross-sectional view of the protective wall 70 (cross-sectional view taken along line X1-X1 in FIG. 8 (B)), and FIG. 8 (B) is Z1-Z1 in FIG. 8 (A). FIG.

As shown in FIGS. 8A and 8B, in the building 66, an opening 80 is provided in the outer wall 94 on the side (Y1 ways) facing the road 92, provided in the X-axis direction. The opening 80 is formed by removing the outer wall 94 between the pillars 78 over two spans, and the inside of the building 66 is a gas supply chamber 68.
That is, the gas supply chamber 68 is a range surrounded by two side walls 84 in the Y-axis direction and an inner wall (back wall) 96 inside the building on the opposite side (Y2 way) to the road 92.

In the gas supply chamber 68, a vertical wall (first wall) 72 and vertical walls (third wall) 73 and 74 are raised from the floor surface 90 inside the building 66.
In a plan view, the vertical wall 72 is raised parallel to the inner wall 96, and the vertical walls 73 and 74 have one end joined to the vertical wall 72 and the other end extending to the opening 80.

A diagonal wall (second wall) 76 is provided at the top of the vertical walls 72, 73, 74. The free end 76E of the diagonal wall 76 extends through the opening 80 to the outside of the building 66.
Further, a damper (impact absorbing means) 88 for absorbing an impact is attached to the tip end (free end 76E) of the oblique wall 76 between the ground 14 and the damper.

  According to this configuration, the dispenser 16 is installed in the gas supply chamber 68 of the building 66, and vertical walls 72, 73, 74 are raised in the gas supply chamber 68 so as to surround the dispenser 16. Also, the free end 76E of the oblique wall 76 extends to the outside of the building 66.

Thereby, even if the hydrogen gas leaking from the dispenser 16 explodes, the inner wall 96 forming the gas supply chamber 68, the partition wall 86 of the ceiling, and the side wall 84 are protected by the vertical walls 72, 73, 74, respectively. The damage is suppressed.
That is, even in an urban area where there are few vacant lands, the hydrogen station can be provided by installing the dispenser 16 inside the building 66 and constructing the protective wall 70 around the dispenser 16.

Further, since the damper 88 is provided between the free end 76E of the oblique wall 76 and the ground 14, even if the hydrogen gas leaked from the dispenser 16 explodes, the damper 88 prevents the oblique wall 76 from Since the impact in the direction of moving away from the vertical walls 72, 73, 74 is absorbed, damage to the protective wall 70 is suppressed.
The damper 88 may be provided not only between the free end 76E of the oblique wall 76 and the ground 14, but also between the free end 76E of the oblique wall 76 and the building 66. Thus, similarly, the damper 88 absorbs the impact in the direction in which the oblique wall 76 is moving away from the vertical walls 72, 73, 74.

  Also, between the vertical walls 72, 73, 74 and the inner wall 96 and the side wall 84 of the building 66, equipment such as a storage tank 36 for combustible gas may be installed. Thereby, even if the hydrogen gas leaked from the dispenser 16 explodes, the equipment such as the storage tank 36 is protected by the protective wall 70.

The damper 88 of this embodiment is the same as that of the first to fifth embodiments between the tip of the oblique walls 20, 46, 48, 56, 58 and the ground 14, or the oblique walls 20, 46, 48 , 56, 58 and the building 32 may be provided.
The other configuration is the same as that of the first embodiment, and the description is omitted.

10, 30, 40, 50, 60, 70 Protective wall 12, 42, 43, 44, 52, 53, 54, 72 Vertical wall (first wall)
14 ground (base part)
16 Dispenser (gas supply equipment)
18 Vehicles 20, 46, 48, 56, 57, 58, 76 Diagonal wall (second wall)
20E, 76E Tip (free end)
22 pillars (first wall)
24 Beam (second wall)
26 Precast concrete plate (first wall)
28 Precast concrete plate (second wall)
32, 66 Building 36 Storage Tank 38, 64 Auxiliary Protective Wall 68 Gas Supply Room 73, 74 Vertical Wall (3rd Wall)
80 opening 88 damper (shock absorbing means)
90 floor (base part)
α Angle of inclination from the horizontal plane of the oblique wall

Claims (3)

A first wall which is raised from the base at a distance from a gas supply facility for supplying a flammable gas, covers one side of the gas supply facility, and receives a blast when the flammable gas explodes;
From the upper part of the first wall, it covers the upper part of the gas supply facility and extends obliquely upward, the lower end is joined to the first wall and the upper end is a free end, the flammable The second wall which receives the blast of explosive gas,
With a protective structure. At the free end of the second wall:
Shock absorbing means for absorbing an impact in a direction away from the first wall, which is received by the second wall by the blast at the time of explosion of the combustible gas, is provided.
A protective structure according to claim 1. The gas supply facility and the first wall are installed in a gas supply chamber of a building provided with an opening facing the outside,
At both ends of the first wall, a third wall raised from the base and having an upper portion joined to the second wall is extended to the opening.
The free end of the second wall extends from the opening to the outside of the building,
The protective structure according to claim 1 or 2.

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