KR102247344B1 - Method for constructing vertical structure in vertical tunnel using top down method - Google Patents

Abstract

The present invention relates to a method for constructing a vertical structure using a top-down method, which is able to be constructed by lowering a vertical wall from on the ground toward a lower side of a vertical hole at the same time as excavating the vertical hole. In accordance with the present invention, the method for constructing the vertical structure using the top-down method comprises: a first step to install a temporary structure (100) on the ground; a second step to bury support structures at regular intervals along an inner edge of the temporary structure a third step to install a lowering inducing member (300) on an upper side of the temporary structure; a fourth step to placing the vertical wall (B) on the lowering inducing member at the same time as excavating the vertical hole to a certain depth in the temporary structure; a fifth step to remove an upper end of the support structures exposed to an upper side as much as a certain depth; a sixth step in which the lowering inducing member lowers the vertical wall into the vertical hole for a certain depth; and a seventh step to repeat the fourth to the sixth steps until the vertical wall reaches the target depth.

Description

Method for constructing vertical structure in vertical tunnel using top down method}

The present invention relates to a construction method of a vertical sphere structure using a top-down method in which construction is performed while the vertical sphere wall is lowered from the ground to the bottom of the vertical sphere at the same time as the vertical sphere is excavated.

In general, a vertical hole is a type of vertical tunnel that connects vertically from the ground to an underground tunnel in order to excavate a tunnel. During tunnel construction, various equipment and construction materials are transported and moved from the ground, and the soil and rock generated during tunnel excavation are discharged to the ground. After the tunnel is completed, it connects the mobile passage of the manager and various cables of communication or power outlets from the underground tunnel to the ground and connects various pipes.

These vertical spheres are constructed through the traditional method of installing temporary dirt walls on the outer periphery after digging, and building up from the bottom of the basement to the upper side while supporting the load on the temporary dirt walls with a brace. There are many problems in applying the above construction method when the building is located close to the site boundary line, such as in a large city, because it causes traffic congestion due to vehicle stopping and damages the surrounding area. The brace is a top-down method that has a fast, economical, and structurally safe construction process while increasing land use efficiency and increasing land use efficiency because various problems such as the complexity of the process due to the construction of the structure, the risk of work, and the generation of waste occur. ) Is in the limelight.

As a construction method of a vertical sphere structure using a top-down construction method, a "construction method of a vertical sphere structure using a top-down construction method" disclosed through Patent No. 1885367 is known.

In the above-described conventional top-down construction method, a temporary structure is installed on the ground, a temporary structure is installed on the temporary structure, and a vertical sphere is excavated from the inside of the temporary structure. 1 Mold the vertical sphere wall. Then, the first vertical sphere wall is lowered to a certain depth into the vertical sphere, and a second vertical sphere wall is formed on the upper end of the first vertical sphere wall. In addition, the vertical sphere structure is constructed by lowering the wall of the second vertical sphere together with the first vertical sphere.

However, according to the conventional construction method of the vertical sphere structure using the top-down construction method, when the ground of the vertical sphere is soft, the descending vertical sphere walls do not achieve a horizontal state and are inclined to one side.

In this case, since it is necessary to adjust the position of the inclined vertical sphere wall in a horizontal state, various problems arise, such as delays in air and safety accidents.

In addition, when the vertical sphere wall is inclined and collides with the vertical sphere wall, cracks often occur.In this case, the durability of the completed vertical sphere structure is severely adversely affected, as well as the cracked part inside the vertical sphere wall. As groundwater flows in, it is very urgent to prepare a countermeasure.

The present invention has been conceived to solve the above problems, and provides a method of constructing a vertical sphere structure using a top-down method in which the descending vertical sphere walls are not inclined to one side and are stably descended while maintaining a horizontal state. have.

In order to achieve the above object, the construction method of the vertical sphere structure using the top-down construction method of the present invention includes a first step in which a temporary structure is installed on the ground, and a support structure is buried at regular intervals along the inner edge of the temporary structure. Step 2, a hydraulic jack installed on the upper part of the temporary structure, a shoe supported on the upper end of the support structure, a jack rod connecting the hydraulic jack and the shoe by a shoe, and a descending guide provided with an elevating member installed at the lower part of the shoe. The third step in which the member is installed, the fourth step in which the vertical sphere is excavated to a certain depth inside the temporary structure, and the vertical ball wall is mounted on the descending guide member, and the support structure exposed to the top by a certain depth. A fifth step in which the upper end is removed, a sixth step in which the descending induction member lowers the vertical sphere wall to a certain depth into the vertical sphere, and the fourth to fourth steps until the vertical sphere wall reaches a target depth. It includes a seventh step in which step six is repeated.

In addition, the support structure may be a concrete pile formed by casting concrete on-site in an excavation hole formed from the ground to the rocky ground.

In this case, the fifth step is a step in which the upper end of the concrete pile exposed to the top is cut through a cutter machine, and each time the upper end of the concrete pile exposed to the upper end is removed, the lifting member of the corresponding lowering guide member descends, It is preferable that the step of being supported on the cut top surface is sequentially performed for each concrete pile, and the sixth step includes the step of raising all the lowered lifting members.

In addition, the support structure may be a precast concrete segment laminated assembly inserted into an excavation hole formed from the ground to the rocky ground.

In this case, in the third step, the lifting member of the descending guide member is supported on the top of the precast concrete segment stacking assembly in a state that is lowered by one step, and the fifth step is the step of raising the lifting member by one step and exposing it to the top. The step of separating and removing the precast concrete segment from the precast concrete segment stacking assembly and the step of supporting the lifting member by descending two steps on the separating upper surface of the precast concrete segment stacking assembly from which the precast concrete segment has been removed are each precast. It is made sequentially for each cast concrete segment laminated assembly, and the sixth step includes a step in which all the lifting members lowered in two stages are contracted to one stage.

On the other hand, the precast concrete segments are detachably assembled through pin coupling, and coupling protrusions having pin fitting holes respectively formed at upper and lower ends of the precast concrete segments may protrude in the inner direction of the vertical sphere.

In this case, it is preferable that a sliding groove portion is formed at the lower end of the precast concrete segments in the inward direction of the vertical sphere, and a sliding protrusion corresponding to the sliding groove portion is formed at the upper end of the precast concrete segments.

Meanwhile, the elevating member may be a hydraulic cylinder.

In addition, a height adjustment block may be further provided at the upper end of the support structure to adjust the height so that all the lifting members are located on the same horizontal line.

On the other hand, in the third step, the lifting member of the descending guide member is fixed to the top of the precast concrete segment stacking assembly in a state of being lowered one step, and the fifth step is the precast concrete segment fixed while the lifting member rises one step. The step of lifting the lifted precast concrete segment and removing the lifted precast concrete segment from the lifting member, and the step of supporting the lifting member while descending two steps on the separating upper surface of the precast concrete segment stacking assembly from which the precast concrete segment was removed. It is made sequentially for each precast concrete segment stacking assembly, and the sixth step may include a step in which all the lifting members lowered in two stages are contracted to one stage.

In this case, a first pin member is vertically provided at the lower end of the elevating member, a vertical pin hole into which the first pin member is inserted is formed at the upper end of the precast concrete segments, and the side of the precast concrete segments A horizontal pinhole communicating with the vertical pinhole is formed, and a second pin member is inserted into the horizontal pinhole and coupled to the first pin member and the end is exposed outside the horizontal pinhole, and the exposed end of the second pin member May be coupled by inserting a paper sheet that prevents the flow of the second pin member.

In addition, it is preferable that a protrusion is formed at a lower end of the precast concrete segments and a groove corresponding to the protrusion is formed at an upper end.

On the other hand, it is preferable that the lower end of the precast concrete segment located at the lower end of the precast concrete segments is made of a sharpened portion that converges downward.

In the present invention configured as described above, since the vertical sphere wall is always supported in a horizontal state through a buried support structure, it is not inclined to one side to the target depth and can descend while stably maintaining the horizontal state.

1 and 2 are cross-sectional views sequentially showing a construction method of a vertical sphere structure using a top-down construction method according to an embodiment of the present invention.
Figure 3 is a plan view of Figure 2;
Figure 4 is a cross-sectional view showing the order of the construction method of the vertical sphere structure using a top-down construction method according to an embodiment of the present invention, a view showing a state in which a descending guide member is installed in a temporary structure.
5 to 7 are cross-sectional views showing in sequence a construction method of a vertical sphere structure using a top-down construction method according to an embodiment of the present invention.
8 is a cross-sectional view showing a construction method of a vertical ball structure using a top-down method according to another embodiment of the present invention.
Figure 9 is an exploded perspective view of the precast concrete segment of Figure 8;
10 and 11 are cross-sectional views sequentially showing a construction method of a vertical ball structure using a top-down construction method according to another embodiment of the present invention.
12 is an exploded perspective view of a precast concrete segment according to another embodiment of the present invention.
13 and 14 are cross-sectional views sequentially showing a construction method of a vertical ball structure using a top-down construction method according to another embodiment of the present invention.

Features and advantages of the present invention will become more apparent from the detailed description of the following preferred embodiments based on the accompanying drawings. Prior to this, terms or words used in the present specification and claims are based on the principle that the inventor can appropriately define the concept of the term in order to describe his or her invention in the best way. It must be interpreted as a corresponding meaning and concept.

Hereinafter, in describing an embodiment of the present invention in detail with reference to the drawings, the same reference numerals are used for the same configuration, and only different parts will be mainly described so as not to overlap as possible for clarity.

The construction method of the vertical sphere structure using the top-down construction method according to the present invention includes a first step of installing a temporary structure on the ground, a second step of burying a support structure at regular intervals along the inner edge of the temporary structure, and the temporary structure. The third step in which the descending guide member is installed on the upper part of the structure, the fourth step in which the vertical sphere is excavated to a certain depth inside the temporary structure and the vertical sphere wall is mounted on the descending guide member, and the upper part by a certain depth. The fifth step of removing the upper end of the support structure exposed by the lowering member, the sixth step of lowering the vertical sphere wall by a predetermined depth into the vertical sphere, and the vertical sphere until the wall reaches a target depth. It includes a seventh step in which steps 4 to 6 are repeated.

As shown in Fig. 1, a temporary structure 100 is installed on the ground on which the vertical sphere structure is to be constructed.

The temporary structure 100 provides a solid bottom surface to smoothly perform a series of operations on the ground.

The temporary structure 100 is formed in a ring shape along the vertical sphere to be excavated and has an inner diameter larger than the vertical sphere to be excavated. The temporary structure 100 may be an assembly of a cast-in-place concrete structure or a precast concrete segment 210.

2 and 3, when the installation of the temporary structure 100 is completed, the support structure is buried at regular intervals along the inner edge of the temporary structure 100.

In this case, the support structures may be a concrete pile 200a formed by forming an excavation hole from the ground to the rock ground A so as to exert a solid support and placing concrete in the excavation hole on-site.

As shown in FIG. 4, when the concrete pile 200a is completely buried, the descending guide member 300 is installed on the upper part of the temporary structure 100.

The descending guide member 300 includes a hydraulic jack 310 installed on the upper part of the temporary structure 100, a shoe 320 supported on an upper end of the concrete pile 200a, and the hydraulic jack 310 and shoe 320 ) And a jack rod 330 directly connecting the shoe 320, and an elevating member 340 installed under the shoe 320.

The elevating member 340 is preferably a hydraulic cylinder capable of exerting a large driving force and easy installation and precise control.

As shown in Figure 5a, when the installation of the descending guide member 300 on the upper part of the temporary structure 100 is completed, equipment such as a fork lane is inserted into the temporary structure 100 to excavate the vertical sphere to a certain depth. At the same time, the vertical sphere wall (B) is mounted on the upper portion of the shoe (320).

In this case, the permanent vertical sphere wall (B) may be a precast concrete structure or may be a concrete structure cast in place from the top of the shoe (320). The jack rod 330 is connected through the vertical sphere walls (B).

In this way, since the vertical sphere wall (B) is prepared during the excavation of the vertical sphere, the air can be greatly shortened.

In addition, since the shoe 320 is stably supported in a horizontal state by the concrete pile 200a buried up to the rock ground (A), the vertical sphere wall (B) mounted on the upper portion of the shoe (320) is also a high load. It does not tilt to one side and maintains the horizontal state stably.

Although not shown, when the height of the top of the buried concrete piles 200a is not constant, the shoe 320 is inclined to one side and the vertical ball wall B cannot be supported in a horizontal state, so the concrete pile 200a A height adjustment block for adjusting the height so that all the lifting members 340 are located on the same horizontal line may be further provided at the top of the ).

On the other hand, when the vertical sphere is excavated to a certain depth, the upper part of the concrete pile 200a supporting the elevating member 340 is exposed to a certain height.

As shown in FIG. 5B, when the excavation of the vertical sphere and the mounting of the vertical sphere wall (B) are completed, the upper end of the concrete pile 200a exposed upward by a predetermined depth is removed.

That is, the upper end of the concrete pile 200a exposed to the top is cut using a cutter, and then the upper end of the cut concrete pile 200a is pulled toward the vertical sphere to be removed from the concrete pile 200a.

This cutting operation is performed sequentially for each concrete pile 200a. Whenever the upper end of the concrete pile 200a exposed to the top is removed, the lifting member 340 of the corresponding descending guide member 300 is lowered to lower the concrete pile. By being supported on the cut top surface of (200a), the support of the vertical sphere wall (B) is unchanged and stable.

As shown in FIGS. 5C and 5D, when the upper ends of all the concrete piles 200a are removed in this way, the vertical sphere wall B is lowered to a predetermined depth using the descending guide member 300.

That is, when all the lowered lifting members 340 are simultaneously raised, the vertical sphere wall (B) naturally descends into the vertical sphere by a certain depth due to the weight of the vertical sphere wall (B).

At this time, if the lower end of the elevating member 340 is fixed to the cut upper surface, the elevating member 340 acts to pull the shoe 320 so that the vertical sphere wall (B) descends more easily.

As shown in Fig. 6, the vertical sphere wall (B) is excavated to a predetermined depth until the vertical sphere wall (B) reaches the target depth in the same manner as described above, and the vertical sphere wall (B) is placed on the descending guide member (300). After mounting, the upper end of the concrete pile 200a exposed to the top by a predetermined depth is removed, and the process of lowering the vertical sphere wall (B) into the vertical sphere by a predetermined depth is repeated.

Thereafter, the shoe 320 and the elevating member 340 are removed, concrete is poured into the bottom of the vertical sphere to construct the floor surface (C), and then the descending guide member 300 and the temporary structure 100 installed on the ground are demolished. Then, when concrete is poured into the vertical sphere and the vertical sphere wall to fill the gap (D), the construction of the vertical sphere structure is completed as shown in FIG. 7.

As described above, the present invention is supported in a horizontal state through the concrete pile 200a in which the vertical sphere wall (B) is embedded, so that the vertical sphere wall (B) is stably descended while maintaining the horizontal state without inclining to one side to the target depth. It is done.

8 and 9, as another embodiment of the present invention, the support structures may be a precast concrete segment lamination assembly 200b inserted into an excavation hole formed from the ground to the rock ground (A). .

In this case, when the coupling protrusions 211 having pin fitting holes 212 formed at the upper and lower ends of the precast concrete segments 210, respectively, are formed to protrude in the inner direction of the vertical sphere, the upper precast concrete segment 210 The pin 220 is inserted into the pin fitting hole 212 formed at the bottom and the pin fitting hole 212 formed at the upper end of the precast concrete segment 210 at the lower portion of the pin 200 so that the pin 220 does not come off. The precast concrete segments 210 can be joined very easily by inserting the paper 230 into the wall.

In addition, it is preferable that a sliding groove part 240 is formed at the lower end of the precast concrete segments 210 in the inner direction of the vertical sphere, and a sliding protrusion 250 corresponding to the sliding groove part 240 is formed at the upper end.

In this case, after separating the pin 220 from the pin fitting hole 212, the upper precast concrete segment 210 can be easily removed from the precast concrete segment stacking assembly 200b.

As shown in FIG. 10, in the case where the support structure is a precast concrete segment stacking assembly 200b, when the descending induction member 300 is installed, the elevating member 340 is freely lowered by one stage. It is supported on the top of the cast concrete segment laminate assembly 200b.

And, when removing the upper end of the concrete segment laminate assembly (200b) exposed to the top by a certain depth, as shown in Figure 11a, the lifting member 340 is raised one step, and then the precast concrete exposed to the top The segment 210 is separated and removed from the precast concrete segment laminate assembly 200b.

As shown in FIG. 11B, the removal operation of the precast concrete segment 210 is sequentially performed for each precast concrete segment stacking assembly 200b, and the precast concrete segment 210 exposed to the top is removed. Whenever. By lowering the elevating member 340 that has risen by one step by two steps so as to be supported on the separated upper surface of the precast concrete segment stacking assembly 200b, the support of the vertical sphere wall (B) is unchanged and stably supported.

As shown in FIG. 11C, when all the precast concrete segments 210 exposed to the top are removed in this way, the vertical sphere wall B is lowered to a predetermined depth using the descending guide member 300.

That is, as shown in FIG. 11D, when all the lifting members 340 lowered by two stages are simultaneously contracted to one stage, the vertical sphere wall (B) naturally moves into the vertical sphere by the weight of the vertical sphere wall (B). It descends a certain depth.

At this time, if the lower end of the lifting member 340 is fixed to the separate upper surface, the lifting member 340 acts to pull the shoe 320, so that the vertical sphere wall (B) descends more easily.

In the same manner as described above, until the vertical sphere wall (B) reaches the target depth, the vertical sphere is excavated to a certain depth, and the vertical sphere wall (B) is mounted on the descending guide member 300, and then the vertical sphere wall (B) is mounted by a certain depth. When the precast concrete segment 210 exposed to the top is removed and the process of lowering the vertical sphere wall (B) to a certain depth inside the vertical sphere is repeated, the construction of the vertical sphere structure is completed as shown in FIG. 8. .

As shown in FIG. 12, as another embodiment of the present invention, in the case of the precast concrete segment stacking assembly 200c inserted into the excavation hole formed from the ground to the rock ground (A), the support structures, A first pin member 341 is vertically provided at the lower end of the elevating member 340, and the precast concrete segments 260 have a vertical pin hole 261 into which the first pin member 341 is inserted at the upper end. It is formed, and a horizontal pinhole 262 communicating with the vertical pinhole 261 may be formed in the side.

In this case, the horizontal pinhole 262 is fitted and coupled to the first pin member 341, and the second pin member 270 is inserted into the horizontal pinhole 262. The end of the second pin member 270 is exposed to the outside of the horizontal pin hole 262, and a Ÿ‡ paper 280 is inserted into the exposed end of the second pin member 270 so that the second pin member 270 Prevents the flow of

In addition, a protrusion 264 is formed at the lower end of the precast concrete segments 260 and a groove 263 corresponding to the protrusion 264 is formed at the upper end of the precast concrete segment 260 and the precast concrete segment 260 at the lower part. Cast concrete segments 260 may be stably coupled at a certain position.

On the other hand, it is preferable that the lower end of the precast concrete segment 260a located at the lowermost end of the precast concrete segments 260 has a sharpened portion 265 that converges downward.

In this case, the sharpening part 265 is deeply embedded in the bottom surface of the excavation hole by the load of the precast concrete segments 260 stacked thereon, and the precast concrete segment stacking assembly 200c is stable inside the excavation hole. Helps to be buried.

As shown in Figure 13, when the precast concrete segment 260 is configured as described above, when the descending induction member 300 is installed, the elevating member 340 is stacked in a state in which the precast concrete segment is lowered by one stage. It is fixed to the top of the assembly (200c).

And, when removing the upper end of the concrete segment stacking assembly (200c) exposed to the top by a certain depth, as shown in Figure 14a, if the lifting member 340 is raised one step, the uppermost end along the lifting member 340 The precast concrete segment 260 is lifted, and the lifted top precast concrete segment 260 is separated from the lifting member 340 and removed.

As described above, in this embodiment, since the lifting member 340 is removed by lifting the precast concrete segment 260, no separate equipment is required to remove the precast concrete segment 260, and the removal operation is very easy and fast. It goes on.

As shown in FIG. 14B, the removal operation of the precast concrete segment 260 is sequentially performed for each precast concrete segment stacking assembly 200c, and the precast concrete segment 260 exposed to the top is removed. Whenever. By lowering the elevating member 340, which has risen by one stage, to the precast concrete segment 260 by lowering it by two stages, the support of the vertical sphere wall (B) is unchanged and stably made.

As shown in FIG. 14C, when all the precast concrete segments 260 exposed to the top are removed in this way, the vertical sphere wall B is lowered to a predetermined depth using the descending guide member 300.

That is, as shown in Fig. 14D, when all the lifting members 340 lowered by two stages are simultaneously contracted to one stage, the vertical sphere wall (B) naturally moves into the vertical sphere by the weight of the vertical sphere wall (B). It descends a certain depth.

In the same manner as described above, until the vertical sphere wall (B) reaches the target depth, the vertical sphere is excavated to a certain depth, and the vertical sphere wall (B) is mounted on the descending guide member 300, and then the vertical sphere wall (B) is mounted by a certain depth. If the precast concrete segment 260 exposed to the top is removed and the process of lowering the vertical sphere wall (B) to a certain depth inside the vertical sphere is repeated, the construction of the vertical sphere structure is completed as shown in FIG. 8. .

As such, the support structure is a precast concrete segment laminate assembly (200b, 200c). In this case, compared to the above-described concrete pile (200a), there is an advantage that recycling is possible and removal is quick and easy.

As described above, preferred embodiments of the present invention have been described above with reference to the drawings, but the present invention is not limited to the above-described embodiments, and those of ordinary skill in the art to which the present invention pertains are modified without departing from the spirit of the present invention. It is possible, and such modifications will fall within the scope of the present invention.

100...Temporary structure 200a...Concrete pile
200b,200c... Precast Concrete Segment Lamination Assembly
210,260... precast concrete segments
211...Joining protrusion 212...Pin inserting hole
220...pin 240...sliding groove
250...Sliding protrusion 261...Vertical pinhole
262...Horizontal pinhole 263...groove
264... protrusion 265... sharpening
270...second pin member 280...Ÿ‡paper
300...down induction member 310...hydraulic jack
320...Shoe 330...Jack Rod
340...elevating member 341...first pin member
A...rock ground B...vertical sphere wall

Claims (13)

The first step of installing a temporary structure on the ground;
A second step of burying a supporting structure composed of a concrete pile formed by placing concrete in an excavation hole formed from the ground to the rocky ground at regular intervals along the inner edge of the temporary structure;
A descending guide member having a hydraulic jack installed on the upper part of the temporary structure, a shoe supported on the upper end of the support structure, a jack rod connecting the hydraulic jack and the shoe, and an elevating member installed under the shoe is installed. The third step;
A fourth step in which a vertical sphere wall is mounted on the descending guide member while the vertical sphere is excavated to a predetermined depth within the temporary structure;
A fifth step of removing the upper end of the support structure exposed to the top by a predetermined depth;
A sixth step of lowering, by the descending induction member, the vertical sphere wall to a predetermined depth into the vertical sphere; And
Construction method of a vertical sphere structure using a top-down construction method comprising a seventh step in which the fourth to sixth steps are repeated until the vertical sphere wall reaches a target depth. delete The method of claim 1,
The fifth step is a step in which the upper end of the concrete pile exposed to the top is cut through a cutter machine, and each time the upper end of the concrete pile exposed to the top is removed, the lifting member of the corresponding lowering guide member descends to the cut top surface of the concrete pile. Steps supported on are sequentially performed for each concrete pile;
The sixth step is a method of constructing a vertical ball structure using a top-down method including the step of raising all the lowered lifting members. delete delete delete delete The method of claim 1,
The elevating member is a construction method of a vertical sphere structure using a top-down method, characterized in that the hydraulic cylinder. The method of claim 1,
Construction method of a vertical ball structure using a top-down construction method further provided with a height adjustment block for adjusting the height so that all the lifting members are located on the same horizontal line at the upper end of the support structure. delete delete delete delete

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