KR100939495B1 - A soundproofing apparatus for a tunnel - Google Patents

Abstract

PURPOSE: A sound-insulating device of a tunnel pithead is provided to prevent the damage of cutoff walls due to blast pressure by forming plural discharge holes on the outside of cutoff walls positioned in the pithead of a tunnel. CONSTITUTION: A sound-insulating device of a tunnel pithead is composed of a first cutoff wall(110), a second cutoff wall(210), and a shock absorbing unit(410). The first cutoff wall is positioned in the pithead of a tunnel and a first door(112) is formed in the center. The second cutoff wall is positioned in the inside of a tunnel and a second door(212) is formed in the center. The second cutoff wall is spaced from the first cutoff wall. The shock absorbing unit is installed between the first cutoff wall and the second cutoff wall and is composed of plural guide shafts(412), a first flow plate(414) and a first elastic member(416). A cutout hole is formed in a first cover member(140) of both sides of the door of the second cutoff wall. One side of the guide shaft is connected to a second frame exposed by a cutout hole(242) of the second cutoff wall. The other side of the guide shaft is fastened to a first frame(120) of the first cutoff wall. The first flow plate is fitted to the guide shaft to cover the cutout hole. The first elastic member is fitted to the guide shaft and is positioned between the first cutoff wall and the first flow plate. Plural air exhaust holes(142) are formed in the first cover member.

Description

Soundproofing apparatus for a tunnel

The present invention relates to a soundproofing device for a tunnel shaft, and more particularly, to extinguish the blasting noise and the storm pressure generated during the blasting work in the tunnel to block the noise from being transmitted to the outside of the shaft and simultaneously to generate the noise. The present invention relates to a soundproofing device for a tunnel shaft that minimizes damage, prevents environmental pollution, and prevents accidents from scattering.

In general, tunnels are constructed so that roads or railroads can pass in a short time through straight lines without bypassing mountains or hills, and are passages opened through obstacles such as mountains.

Thus, in order to construct a tunnel, it is essential to carry out blasting work using explosives.

Here, the tunnel blasting method is to excavate the tunnel by filling the explosives in a number of charge holes perforated on the free surface of the tunnel and then exploded in a chain so that the explosion noise and explosion vibration noise generated when the explosives are exploded. In addition to being discharged, small blasts and powders blown out during blasting are released to the outside. These explosion noises, explosion vibration noises, and blasted stones and stone dust cause noise pollution and dust pollution around the construction site. When raising livestock in farms around the site, the explosion noise and explosion vibration generated during tunnel blasting can cause serious damage to livestock.

In addition, in the tunnel, the storm pressure (noise) from a certain space is very large, causing considerable displeasure to nearby residents, causing complaints.

In the prior art, when constructing a tunnel excavation by tunnel blasting method, a soundproof wall is formed by installing a steel plate soundproof wall in a previously excavated tunnel or stacking sponge blocks to release explosion noise, explosion vibration noise, stones and stone dust to the outside. It's blocking you from being.

However, the steel plate soundproof wall of the prior art as described above is very difficult to assemble and low soundproofing effect is not only inefficient, but also requires a lot of manpower and time to dismantle and reassemble when moving the steel plate soundproof wall according to the excavation by a certain section tunnel tunnel air It is pointed out that the delay is considerably delayed, and the sponge block soundproof wall also has a problem that requires a lot of manpower and time because it must move while repeatedly stacking and dismantling a plurality of sponge blocks.

Therefore, recently, as shown in FIG. 1, a technique for blocking noise generated when blasting is provided by installing a soundproof door in a shaft portion of a tunnel disclosed in Japanese Patent Laid-Open No. 2001-355300.

As shown, in order to prevent the noise generated in the tunnel from leaking to the outside, the door body 1 is formed in a closed hollow shape at the shaft position, and the inside of the door body 1 is vacuumed. The door body is divided into a plurality of blocks by the partition wall 2, and the partition wall 2 has a configuration in which a through hole 3 is provided. Soundproof door (4) is installed so as to be able to open and close.

This soundproof door 4 is provided with a pair of doors 5, These doors 5 are attached to the door main body 1 so that opening and closing is possible. The door 5 is formed in the form of a hollow box sealed with a material such as an iron plate, for example, and the inside thereof is divided into partition walls 2 vertically and horizontally, and penetrates the partition walls 2 vertically and horizontally. The ball 3 is drilled so that a large number of small rooms 6 separated by the longitudinal partition walls pass through. Their small rooms 6 draw a vacuum inside the vacuum pump (not shown) from the outside.

Such a conventional soundproof door is made of a steel plate, the strength is high, the damage is reduced by the storm pressure during blasting, and the vacuum chamber inside to reduce the permeation component of the blasting sound, but in fact through the vertical partition wall There is a problem that the blast sound is transmitted.

In addition, since the vertical and horizontal partition walls made of iron plates are welded like a plurality of checkerboards, the production is complicated and takes a lot of time, and in particular, many small rooms 6 must be welded precisely in order to vacuum them. There was a problem.

In addition, since the impact of the storm pressure generated at the time of blasting is shocked as it is fixed to the wall in the tunnel, the partition wall is damaged by repeated blasting, and it is expensive to maintain the damaged partition wall. At the same time, maintenance work was very difficult.

In addition, since there is no separate device capable of extinguishing the storm pressure generated during the blasting, the partition wall receives the storm pressure as it is, so that the door is opened by the storm pressure, and there is a problem that severe noise is generated.

SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned conventional problems. The present invention provides a pair of barrier walls and provides a shock absorbing portion between the pair of barrier walls, thereby preventing storm pressure generated during blasting in the tunnel. The purpose of the present invention is to prevent the shock absorbing of the shock absorbing unit from being absorbed by the buffer.

In addition, by forming a plurality of discharge holes in the outer surface of the barrier wall located at the entrance of the tunnel among the pair of barrier walls, the impact is primarily reduced when passing through the barrier wall located inside the tunnel, and the primary relief The purpose is to prevent the barrier wall from being damaged by the storm pressure by releasing the secondary storm pressure to the outside through the discharge hole.

In addition, air discharge holes are formed at the upper end of the pair of blocking walls to be automatically opened by the impact of the storm pressure, and the air is discharged to the outside while alleviating the impact of the storm pressure to disperse the shock generated by the storm pressure. The purpose is to prevent the wall from breaking.

On the other hand, the interior of the barrier wall located at the entrance of the tunnel, the interior material with the styrofoam embedded, and the interior of the barrier wall located inside the tunnel is provided with a rubber material, a non-woven fabric, and a built-in foam material is laminated to each other by the interior material The purpose of the present invention is to prevent the noise generated during the blasting work from being absorbed to the outside by absorbing the impact of the explosion pressure.

In order to achieve the above object, the present invention provides a soundproofing device for a tunnel shaft that is installed in a tunnel to block noise from being emitted to the outside, and is located at an entrance of a tunnel, and includes a first entrance wall provided with a first entrance door in a central portion thereof. And, located inside the tunnel, the second entrance door is formed in the center is provided between the first blocking wall and the first blocking wall spaced at a predetermined interval, and installed between the first blocking wall and the second blocking wall Characterized in that consisting of a buffer.

Here, the first blocking wall is provided with a first frame fixed to the inner wall of the tunnel, the first filler is provided on the inner side of the first frame, the first cover member is provided to cover the front of the first frame, One cover member is characterized in that a plurality of air discharge holes formed.

Further, the first filler is characterized in that the styrofoam.

The second barrier wall is provided with a second frame fixed to the tunnel inner wall, a second filler is provided inside the second frame, and a second cover member is provided to cover the front surface of the second frame. It is done.

Here, the second filler is provided with a sponge on the front surface, a rubber plate formed with a plurality of holes in the opposite direction of the sponge, characterized in that the non-woven fabric is provided between the sponge and the rubber plate.

In addition, the connecting plate to cover the outer circumferential surface of the first blocking wall and the second blocking wall to each other is provided.

In addition, the shock absorbing portion is formed with a cutting hole in the first cover member on both sides of the door of the second blocking wall, one side is fastened and fixed to the second frame exposed to the cutting hole of the second blocking wall, the other side is the first blocking A plurality of guide shafts are fastened to and fixed to the first frame of the wall, and are provided with a first flow plate that slides on the guide shaft to cover the cut holes, and is fitted to the guide shaft to be fitted with the first blocking wall and the first flow plate. Between the first elastic member is characterized in that it is provided.

On the other hand, the auxiliary air discharge portion is further provided at the upper end of the first blocking wall and the second blocking wall.

Here, the auxiliary air discharge portion is formed with a through hole in the upper portion of the first blocking wall, the open hole is formed on the same line of the through hole in the upper end of the second blocking wall, the second frame located in the open hole of the second blocking wall One side is fixed to, the other side is provided with a slide shaft for fastening a plurality of flow to the first frame located in the through hole, the front of the slide shaft is provided with a second flow plate for covering the through hole, the first blocking And a second elastic member fitted to the slide shaft so as to be provided between the wall and the second blocking wall.

According to the present invention configured as described above, a pair of barrier walls is provided, and a buffer portion is provided between the pair of barrier walls to absorb the storm pressure generated at the time of blasting in the tunnel, thereby absorbing the storm pressure on the barrier wall. There is an effect to prevent the impact is applied.

In addition, by forming a plurality of discharge holes in the outer surface of the barrier wall located at the entrance of the tunnel among the pair of barrier walls, the impact is primarily reduced when passing through the barrier wall located inside the tunnel, and the primary relief The secondary storm pressure is discharged to the outside through the discharge hole to prevent the barrier wall from being damaged by the storm pressure.

In addition, air discharge holes are formed at the upper end of the pair of blocking walls to be automatically opened by the impact of the storm pressure, and the air is discharged to the outside while alleviating the impact of the storm pressure to disperse the shock generated by the storm pressure. There is an effect to prevent the wall from being broken.

On the other hand, the interior of the barrier wall located at the entrance of the tunnel, the interior material with the styrofoam embedded, and the interior of the barrier wall located inside the tunnel is provided with a rubber material, a non-woven fabric, and a built-in foam material is laminated to each other by the interior material By absorbing the impact of the explosion pressure it is effective to block the noise generated during the blasting work to be emitted to the outside.

Hereinafter, a soundproofing device for a tunnel shaft according to the present invention will be described in detail with reference to the accompanying drawings.

Figure 2 is a perspective view showing a soundproofing device of the tunnel shaft according to the present invention, Figure 3 is a cross-sectional view showing a soundproofing device of the tunnel shaft according to the invention, Figure 4 is an enlarged perspective view showing a buffer of the present invention, Figure 5 is 6 is an enlarged cross-sectional view showing the buffer unit of the present invention, Figure 6 is an enlarged perspective view showing an auxiliary air discharge of the present invention, Figure 7 is an enlarged cross-sectional view showing an auxiliary air discharge of the present invention.

As shown in Figure 2 to 7 in the soundproofing device 100 of the tunnel shaft according to the present invention is installed in the inside of the tunnel in the soundproofing device of the tunnel shaft to block the noise generated during the blasting work to the outside Is located in the entrance direction of the tunnel, the first blocking wall 110 is provided with a first entrance door 112 in the center.

Here, the first blocking wall 110 is formed in a circular shape of the tunnel is fixed to the inner wall of the tunnel, the first frame 120 is provided with a space therein, the inner space of the first frame 120 The first filler 130 is provided.

At this time, the first filler 130 filled in the space of the first frame 120 is filled with a foaming agent such as styrofoam 132.

Furthermore, the front of the first frame 120 is provided with a first cover member 140 to cover the front, a plurality of air discharge holes 142 is formed at the lower end of the first cover member 140, A through hole 144 through which the first filler 130 and the first cover member 140 pass is formed at an upper end of the first access door 112.

The second entrance door 212 is formed at the same position as the first entrance door 112 in the center of the tunnel and is spaced apart from the first blocking wall 110 at a predetermined interval. 210 is provided.

Here, the second blocking wall 210 is formed with a second frame 220 formed in the same shape as the first blocking wall 110, the second filler 230 in the inner space of the second frame 220 Filled.

In this case, the second filler 230 is made of a sponge 232, a nonwoven fabric 234 and a rubber plate 236, the sponge 232 is located in the front portion in the direction of the first blocking wall 110, the rubber plate 236 is located on the back side opposite the sponge 232, a nonwoven fabric 234 is located between the sponge 232 and the rubber plate 236, a plurality of holes 236a in the rubber plate 236 Is formed.

Further, the second cover member 240 is provided to cover the front surface of the second frame 220, the incision hole 242 is formed on both sides of the front surface of the second cover member 240.

In addition, an open hole 244 is formed at the upper end of the second access door 212, that is, at the upper end of the front surface of the second cover member 240 on the same line as the through hole 144 of the first blocking wall 110. In addition, a flow hole 232a is formed in the second filler 230 at the open hole 244.

At this time, the first frame 120 and the second frame 220 are spaced apart from each other in the front and rear to form a frame, the main frame 122, 222 is provided so that the space is formed inside, the main formed spaced apart from each other Connection frames 124 and 224 are provided to connect the outer portions of the frames 122 and 222 to each other, and the first and second entrance doors 112 and 212 are installed at the center of the main frames 122 and 222. It is composed of door frames (125) and (225).

In addition, by covering the outer peripheral surface of the first frame 120 of the first blocking wall 110 and the outer peripheral surface of the second frame 220 of the second blocking wall 210 are connected to each other, the first blocking wall 110 and the second A connecting plate 310 is provided to cover the space between the blocking walls 210.

In addition, a buffer unit 410 is installed between the first blocking wall 110 and the second blocking wall 210 to cushion the storm pressure and noise generated during the blasting operation.

Here, the buffer part 410 forms a second fixture 226 in the second frame 220 exposed to the cut-out hole 242 of the second blocking wall 210 and one side to the second fixture 226. A plurality of guide shafts 412 are additionally fastened and fixed, and the other side of the guide shaft 412 is provided on the first frame 120 of the first blocking wall 110. A first fixture 126 corresponding to 226 is formed, and an opposite direction of the guide shaft 412 is fastened to the first fixture 126.

Furthermore, the guide shaft 412 is fastened to be slidably movable to cover the incision hole 242 formed in the second cover member 240 of the second blocking wall 210, storm pressure generated during the blasting operation The first flow plate 414 is provided to slide forward by the impact of the.

In addition, a first that is inserted between the guide shaft 412, the first flow plate 414, which is located between the first blocking wall 110 and the first flow plate 414, and slides forward. An elastic member 416 is provided.

Therefore, when the blasting operation is performed inside the tunnel, the first fluid plate 414 moves forward while pressing the first elastic member 416 along the guide shaft 412 by the storm pressure generated by the blasting operation. The first barrier wall 210 is first mitigated by the impact of the storm pressure, and the air pressure passing through the second barrier wall 210 is discharged through the incision hole 242 of the second barrier wall 210 and air After the discharge is completed, the first flow plate 414 is returned to its original state by the elastic force of the first elastic member 416.

In addition, the upper end portion between the first blocking wall 110 and the second blocking wall 210 is further provided with an auxiliary air discharge unit 510 for discharging the air generated by the storm pressure to the outside during the blasting operation.

Here, the auxiliary air discharge part 510 has an open hole 244 on the same line to correspond to the through hole 144 formed in the upper portion of the first blocking wall 110 at the upper end of the second blocking wall 210. Is formed.

Furthermore, a fourth fixture 228 is formed in the second frame 220 exposed to the opening hole 244 of the second blocking wall 210, and the first frame 120 corresponds to the fourth fixture 228. The third fastener 128 is formed on the slide shaft 512 is fastened to the third fastener 128 and the fourth fastener 228, the slide shaft 512 fastened to the fourth fastener 228 The end portion is positioned in the flow hole 232a formed in the second filler 230, the other side is provided to protrude forward of the first frame (120).

In this case, the locking member 514 is fastened to the slide shaft 512 and fastened to the slide shaft 512 to be positioned in front of the second frame 220.

In addition, a second flow plate 516 positioned on the front surface of the first frame 120 to cover the through hole 144 and fastened and fixed to the slide shaft 512 is provided.

Then, the second elastic member 518 is provided between the first frame 120 and the second frame 220 is inserted into the slide shaft 512, one side is supported by the locking member 514.

  Therefore, the air discharged through the second blocking wall 210 is discharged to the outside through the through hole 144 of the first blocking wall 110, at this time by the air pressure discharged through the through hole 144. The second flow plate 516 is advanced forward while pressing the second elastic member 518, the air is discharged to the outside through the gap created by the advance of the second flow plate 516, the discharge of air is completed Afterwards, the second flow plate 516 is returned to its original state by the elastic force of the second elastic member 518.

Referring to the relationship between the soundproofing device of the tunnel shaft according to the present invention configured as described above are as follows.

8 is a view showing an operation relationship of the soundproof device of the tunnel shaft according to the present invention, a view showing a state in which air is discharged through the shock absorbing portion, Figure 9 is a view showing an operation relationship of the soundproof device of the tunnel shaft according to the present invention. , Is a view showing a state in which air is discharged through the auxiliary air discharge unit.

As shown therein, the soundproofing device 100 of the tunnel shaft according to the present invention first installs in the tunnel and then performs a blasting operation, thereby generating storm pressure and noise by the blasting operation, and also causing the monument to fly.

At this time, the noise generated by the blasting operation and the wind pressure is impacted by the noise and wind pressure by the rubber plate 236, the nonwoven fabric 234, and the sponge 232, which is the second filler 230 of the second barrier wall 210. Will be destroyed.

And, the outside through the cut hole 242 formed on the front surface of the second barrier wall 210 by the impact and residual air pressure generated when the pressure generated by the second barrier wall 210 to mitigate the pong wind pressure generated during the blasting operation It is discharged to the discharge to the space between the first blocking wall 110 and the second blocking wall (210).

That is, when the air remaining in the cut-out hole 242 of the second blocking wall 210 is discharged, the first flow plate 414 along the guide shaft 412 is discharged by the first elastic member ( While moving to the first blocking wall 110 while pressing the 416, the air is discharged to the outside through the gap formed in the cutting hole 242 due to the movement of the first flow plate 414.

In addition, when the discharge of the discharged air is completed, the first flow plate 414 is returned to its original state to cover the cutout 242 of the second blocking wall 210 by the elastic force of the first elastic member 416. do.

Therefore, the storm pressure and noise generated by the blasting operation by the operation of the shock absorbing unit 410 are extinguished in the second blocking wall 210 and the shock applied to the second blocking wall 210 is alleviated. The secondary blocking wall 210 is prevented from being damaged.

On the other hand, the air discharged between the first blocking wall 110 and the second blocking wall 210 is a through hole 14 formed in the upper portion of the first blocking wall 110 and the air discharge hole 142 formed in the lower end It is discharged to the outside through.

That is, when the air is discharged to the outside through the through hole 144, the slide shaft 512 moves forward while pressing the second elastic member 518 by the pressure of the air discharged through the through hole 144. As the slide shaft 512 moves forward, the second flow plate 516 fixed to the front surface of the slide shaft 512 moves to the front surface, whereby a gap is formed in the through hole 144. Air will be exhausted to the outside.

After the air is discharged through the through hole 144, the slide shaft 512 returns to its original state by the elastic force of the second elastic member 518, and the second flow plate 516 passes through the through hole 144. It will cover the front of the unit.

The shock applied to the first blocking wall 110 and the second blocking wall 210 while extinguishing storm pressure and noise generated during the blasting work by the buffer unit 410 and the auxiliary air discharge unit 510 as described above. By mitigating the soundproofing device 100 is prevented from being damaged, and noise is emitted to the outside of the tunnel to prevent damage to nearby residents and livestock.

In addition, tunnel excavation work is performed through the first and second access doors 112 and 212 formed on the first blocking wall 110 and the second blocking wall 210.

In the above, a preferred embodiment of the soundproofing device for a tunnel shaft according to the present invention has been described, but the present invention is not limited thereto, and various modifications are made within the scope of the claims and the detailed description of the invention and the accompanying drawings. It is possible to implement, which also belongs to the scope of the present invention.

The present invention relates to a soundproofing device for a tunnel shaft, and more particularly, to extinguish the blasting noise and the storm pressure generated during the blasting work in the tunnel to block the noise from being transmitted to the outside of the shaft and simultaneously to generate the noise. The present invention relates to a soundproofing device for a tunnel shaft that minimizes damage, prevents environmental pollution, and prevents accidents from scattering.

1 is a view showing a soundproofing device of a conventional tunnel shaft.

Figure 2 is a perspective view showing a soundproofing device of the tunnel shaft according to the present invention.

Figure 3 is a cross-sectional view showing a soundproofing device of the tunnel shaft according to the present invention.

Figure 4 is an enlarged perspective view showing the buffer of the present invention.

Figure 5 is an enlarged cross-sectional view showing a buffer of the present invention.

Figure 6 is an enlarged perspective view showing the auxiliary air discharge of the present invention.

Figure 7 is an enlarged cross-sectional view showing an auxiliary air discharge of the present invention.

8 is a view showing an operation relationship of the soundproofing device of the tunnel shaft according to the present invention, a view showing a state in which air is discharged through the buffer unit.

9 is a view showing an operation relationship of the soundproofing device of the tunnel shaft according to the present invention, a view showing a state in which air is discharged through the auxiliary air discharge.

[Description of Symbols for Main Parts of Drawing]

100: sound insulation device 110, 210: first and second barrier wall

112, 212: Gates 1, 2, 120, 220: Frames 1, 2

122, 222: main frame 124, 224: connection frame

125, 225: Moon 126, 128, 226, 228: Fixture

130, 230: First and second filler 132: Styrofoam

140, 240: first and second cover member 142: air discharge hole

144: through hole 232: sponge

232a: floating hole 234: nonwoven fabric

236: rubber plate 236a: hole

242: cutting hole 244: opening hole

310: connecting plate 410: buffer part

412: guide shafts 414, 516: first and second flow plates

416, 518: first and second elastic members 510: auxiliary air exhaust

512: slide shaft 514: locking member

Claims (9)

In the soundproofing device of the tunnel shaft is installed in the tunnel to block the noise emitted to the outside, Located at the entrance of the tunnel, the first blocking wall is provided with a first entrance door in the center, A second blocking wall positioned inside the tunnel and having a second entrance door formed at a center thereof, and spaced apart from the first blocking wall at a predetermined interval; It is installed between the first blocking wall and the second blocking wall, the incision hole is formed in the first cover member on both sides of the door of the second blocking wall, one side in the second frame exposed to the cutting hole of the second blocking wall An additional fastening and fixing, the other side is provided with a plurality of guide shafts fastened and fixed to the first frame of the first blocking wall, is provided to slide to the guide shaft is provided with a first flow plate for covering the incision hole, the guide shaft The soundproofing device of the tunnel shaft, characterized in that composed of a buffer portion provided with a first elastic member between the first blocking wall and the first flow plate. The method of claim 1, The first barrier wall is provided with a first frame fixed to the inner wall of the tunnel, a first filler is provided inside the first frame, a first cover member is provided to cover the front of the first frame, the first cover The soundproofing device of the tunnel shaft, characterized in that the member is formed with a plurality of air discharge holes. The method of claim 2, The first filler is a soundproofing device of a tunnel shaft, characterized in that the styrofoam. The method of claim 1, The second blocking wall is provided with a second frame fixed to the inner wall of the tunnel, a second filler is provided inside the second frame, and a second cover member covering the front surface of the second frame is provided. Sound insulation of the tunnel shaft. The method of claim 4, wherein The second filler is provided with a sponge on the front surface, a rubber plate formed with a plurality of holes in the opposite direction of the sponge, the soundproofing device of the tunnel shaft, characterized in that the non-woven fabric is provided between the sponge and the rubber plate. The method of claim 1, Soundproofing device of the tunnel shaft, characterized in that the connection plate is provided with a cover connecting the outer peripheral surface of the first blocking wall and the second blocking wall to each other. delete In the soundproofing device of the tunnel shaft is installed in the tunnel to block the noise emitted to the outside, Located at the entrance of the tunnel, the first blocking wall is provided with a first entrance door in the center, A second blocking wall positioned inside the tunnel and having a second entrance door formed at a center thereof, and spaced apart from the first blocking wall at a predetermined interval; A buffer unit disposed between the first blocking wall and the second blocking wall; The soundproofing device of the tunnel shaft, characterized in that the auxiliary air discharge portion provided in the upper end of the first blocking wall and the second blocking wall. The method of claim 8, The auxiliary air discharge portion has a through hole formed in an upper portion of the first blocking wall, and an open hole formed in the same line of the through hole in the upper end of the second blocking wall. One side is fixed to the second frame located in the opening hole of the second blocking wall, the other side is provided with a slide shaft which is fastened to the plurality of flow to the first frame located in the through hole, In front of the slide shaft is provided with a second flow plate for covering the through hole, And a second elastic member fitted to the slide shaft so as to be provided between the first blocking wall and the second blocking wall.

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