KR101269597B1 - Underground structure construction method - Google Patents

Abstract

According to the present invention, when pushing the box-shaped loop and pushing the concrete box together, the diagonal cut-out soil is extruded together with the box-shaped loop at the same time as the propulsion of the box, so that the work of digging the diagonal-cutting part does not need to be performed separately. Cost savings and shorter construction periods can be avoided, and the excavation work of the diagonal cuts that carry risks can be omitted, improving safety and distributing the reaction resistance to propel the enclosure, thus eliminating the need for large-scale facilities.

To this end, according to the present invention, the box-shaped loop 6 is woven to correspond to the outer shape of the concrete enclosure 9 to be pushed, press-fitted into the ground from the oscillation shaft 3, and then concrete at the end of the box-shaped loop 6. The tip of the enclosure 9 is arranged to extrude the earth and sand of the diagonal cut surrounded by the box-like loop together with the box-like loop 6 simultaneously with the propulsion and towing of the concrete enclosure 9.

Underground Structure, Oscillation Gang, Underground, Diagonal Cutting Section, Soil, Earth Steel Plate, Reach Gang, Box Loop, Precushion Cutter Plate, Reaction Wall

Description

Underground structure construction method

BRIEF DESCRIPTION OF THE DRAWINGS The longitudinal side view which shows embodiment of the underground structure construction method of this invention.

2 is a sectional view taken along the line A-A in Fig.

3 is a front view illustrating an arrangement state of a box loop.

4 is a longitudinal side view of a first step showing an embodiment of the underground structure construction method of the present invention.

5 is a longitudinal sectional side view of a second step illustrating an embodiment of the underground structure construction method of the present invention.

Fig. 6 is a longitudinal sectional side view of a third step showing an embodiment of the underground structure construction method of the present invention.

7 is a longitudinal sectional side view of a fourth step showing an embodiment of the underground structure construction method of the present invention.

8 is a longitudinal sectional side view of a fifth step showing an embodiment of the underground structure construction method of the present invention.

9 is a longitudinal sectional side view of a completion step showing an embodiment of the underground structure construction method of the present invention.

10 is a longitudinal sectional side view showing a first step of a conventional underground structure construction method.

11 is a longitudinal side view showing a second step of the conventional underground structure construction method.

12 is a longitudinal sectional side view showing a third step of the conventional underground structure construction method.

13 is a front view of the box loop.

Fig. 14 is a front view showing the arrangement of the box loops.

* Explanation of symbols on main parts of drawings *

1: upper traffic 2: earthenware market

3: rash gang 4: reach gang

5: propeller 6: box loop

6a, 6b: Hook-shaped seam 7: precushion cutter plate

8: reaction wall 9: concrete enclosure

10: Wonak Jack 11: Day Entrance

12: Small Jack 13: Supporting Material

14: stop member 15: pedestal

16: strut 17: relief material

18: tie rod material 19: earth member

20: oscillation table 21: reaction body

22: reaction resistance 23: reaction wall

24: tow jack 25: tow cable

26: fixing device 27: temporary fixing member

28: pressure 29: earth and sand

The present invention relates to an underground structure construction method that can be constructed without disturbing the upper traffic when the construction of large underground structures in the transverse direction in the underground, such as railroads, roads.

In order to excavate large underground structures in the transverse direction in underground areas such as railroads and roads, a protective hole for supporting upper traffic is required, and a method of installing a pipe loop for horizontally paralleling steel pipes and the like can be given.

However, the first to form a pipe loop in a separate construction and excavate it to build an underground structure, or to allow the underground structure to be excavated under the pipe loop, so that the toffee is thick enough to exist.

In addition, the protective work of the pipe roof construction consists of the main construction and the separate construction of the underground structure, the construction cost is increased, the construction period is increased.

In order to eliminate such incompatibility, there is conventionally an underground structure construction method as shown in Figs. 10 to 12 (see, for example, the following patent document).

As shown in Fig. 10, the earthquake slab 2 is placed outside the upper traffic 1 such as a railroad to build the oscillation shaft 3 and the arrival shaft 4, and the oscillation shaft 3 By installing the thruster 5 in the inside), the box-shaped loop 6, which is a cylinder for a loop, is press-fitted toward the arrival shaft.

Literature Information of the Prior Art : Special place 55 Publication -19312

Fig. 13 is a front view of the box-shaped loop 6, which is a box-shaped cylinder having a substantially square cross-section, and has hooked joints 6a and 6b in the longitudinal direction continuously formed on the side, and on the upper surface a precushion cutter plate. (7) is installed.
The box-shaped loop 6 can be sequentially connected in the longitudinal direction and buried as long as necessary, and it is made to continuously and parallel in a longitudinal direction through the hook-shaped joints 6a and 6b. Fig. 14 shows the case where the parallel lines are in a U-shape.

The propeller 5 has an extrusion mechanism by a jack of the box loop 6 or the like and an internal drilling mechanism of the box loop 6 by auger or the like.

As shown in FIG. 11, an underground structure by the reaction force wall 8 and the concrete enclosure 9 is set in the oscillation shaft 3, and a pressure jack is provided between the reaction force barrier 8 and the concrete enclosure 9. (10) is installed, the blade inlet (11) is formed at the tip of the concrete enclosure (9) and a small jack (12) is interposed between the tip of the concrete enclosure (9) and the box-shaped loop (6). Let's do it.

13 is a support member of the box-shaped loop 6, 14 is a stop member of the pre-cushion cutter plate 7, and they are installed on the oscillation shaft 3 side, while a pedestal ( 15) Install.

When the small jack 12 is elongated and the box case 6 is sequentially pushed forward one by one while leaving the precushion cutter plate 7 with the reaction force of the concrete enclosure 9, and the box loop 6 is advanced by as many times as possible. The small jack 12 is shortened, and then the pressure jack 10 is extended to excavate the concrete enclosure 9.

16 shows the strut interposed between the hydraulic jack 10 and the concrete enclosure 9.

In this way, while moving forward of the box loop 6 and advancing of the concrete enclosure 9 alternately, the box loop 6 which came out of the arrival shaft 4 is removed sequentially.

And when the front end of the concrete enclosure 9 reaches the arrival shaft 4, the blade inlet 11 etc. are removed, and appropriate backfill grout is performed and a construction is completed.

In the above-described construction method, the box-type loop 6 extends the small jacks 12 one by one to sequentially push the box-type loop 6, and it takes time and effort until the box-type loop 6 is advanced and finished.

In addition, after advancing the box loop 6, the diagonal housing is excavated, and then the concrete housing 9 is advanced.
Therefore, there is a process of digging a diagonal cutting part between the advancement of the box-shaped loop 6 and the advancement of the concrete enclosure 9, and requires an excavation work that is separate from the propulsion of the concrete enclosure 9. have.
For this reason, not only the construction cost becomes large, but also the construction period becomes that long.

In addition, the excavation work of the diagonal cuts involves risks of diagonal cut collapse, and it is also necessary to improve the ground such as stabilization for diagonal cut stability.

The object of the present invention is to eliminate the inadequacies of the prior art, and to push the box-shaped loop and to push the concrete box together, to push the box together with the box-shaped loop at the same time as the propulsion of the box. This eliminates the need for digging diagonal cuts, saves costs and shortens the construction period, and also eliminates the risk of digging diagonal cuts, thereby improving safety. In addition, by distributing the reaction resistance to propel the enclosure, the construction of underground structures without the need for large-scale facilities is provided.

The present invention described in claim 1 for achieving the above object is to arrange the box-shaped loop in a rectangular shape so as to correspond to the outer shape of the housing to be propelled, press-fitted into the ground from the oscillation shaft, and then the tip of the box to the box-loop end. The main purpose of the arrangement is to push together the box loop and the soil of the diagonal cut surrounded by the box loop at the same time as the propulsion and towing of the enclosure.

According to the present invention as set forth in claim 1, since the earth and sand of the diagonal cut portion is extruded to the tip of the enclosure at the same time as the box loop, the propulsion of the box loop and the propulsion and towing of the box are simultaneously performed. Excavation process of the diagonal cutting part existing between the process of propulsion can be skipped, and reduction of construction cost and construction period are aimed at.
In addition, the safety of the construction is improved by eliminating the digging operation of the diagonal cutting portion accompanying the risk.

In addition, the earth and sand cutouts of the diagonal cuts surrounded by the box loops are extruded together with the box loops at the same time as the propulsion and towing of the box, so that a reaction force resistance for moving the enclosure is compared with the case of only pushing or pulling the box. It can disperse | distribute and the reaction force in one place is good on a small scale.
As a result, an auxiliary method such as ground improvement required in the case of insufficient resistance to earth pressure is unnecessary, and the cost and the number of days for construction of the auxiliary method are reduced.

According to the present invention described in claim 2, the propulsion of the enclosure is performed by the propulsion force of the primary pressure jack by disposing a jack and strut as a propulsion device between the rear of the enclosure and the rear reaction wall of the enclosure, and the towing of the enclosure is carried out by Form a front reaction wall to install a fixing device or towing jack at the rear of the enclosure, and fix the other end of the towing cable that has one end installed on the fixing device or towing jack to a towing jack or fixing device fixed to the reaction wall towing jack. The point is to be done by the traction.

According to the present invention described in claim 2, the propulsion of the enclosure is carried out by the propulsion force of the one-pressure jack with respect to the rear part of the enclosure, and the towing of the enclosure is performed at the rear of the enclosure via the towing cable by the towing of the towing jack, so that neither the propulsion nor the towing is mutual. The rear of the enclosure can be pushed intensively without interference and obstruction of the liver.

This invention of Claim 3 makes it a summary to arrange | position the precushion cutter plate which consists of flat plates on a ground side surface.

According to the invention of claim 3, the box-shaped loop is arranged in a rectangular shape so as to correspond to the outer shape of the enclosure, and when the extrusion is carried out simultaneously with the extrusion of the concrete enclosure, the box-shaped loop and the concrete enclosure and the periphery by the precushion cutter plate. Insulation with earth and sand can be performed.

The present invention described in claim 4 is to provide a earth member at the diagonal cut portion, and the earth and sand extrusion of the diagonal cut portion is performed by extruding the earth member at the tip of the enclosure.

According to the present invention as set forth in claim 4, since the sanding of the diagonal cut portion is carried out through the earthing member, the sanding in the box loop can be easily extruded.

Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.

1 is a longitudinal sectional side view of a state before pushing a concrete enclosure showing an embodiment of an underground structure construction method according to the present invention, FIG. 2 is a cross-sectional view taken along line AA in FIG. 1, and FIGS. The same components are given the same reference numerals.

First, the facility will be described. In Fig. 2, the earth steel plate is used as a sheet pile. This earth steel plate 2 is for building the oscillation shaft 3 and the reaching shaft 4.

6 is a box-shaped loop, and as shown in FIG. 13, it is a box-cylindrical of a substantially square cross section, and it forms the continuous seam 6a, 6b of the continuous shape in the longitudinal direction at the side surface, and also in the upper surface or the side surface. The precushion cutter plate 7 is overlapped.

The box-shaped loop 6 may be formed by joining flanges at the front and rear ends and subsequently connected by bolt fixing in the longitudinal direction to bury the required length, and in the longitudinal and horizontal directions through the hooked joints 6a and 6b. Parallel in succession.

As shown in FIG. 3, the box-shaped loop 6 is disposed in a rectangular shape so as to correspond to the outer shape of the concrete enclosure 9.
At this time, the precushion cutter plate 7 is disposed on the ground side, and can insulate the box-shaped loop 6 and the concrete enclosure 9 and the surrounding soil.

17 is fixed with a tie rod material that bonds the earth steel plate 2 on the oscillation gang 3 side and the earth steel plate 2 on the arrival gang 4 side with a relief material, but this earth steel plate 2 ) Is used as the earth member (19) is a part cut.

The concrete enclosure 9 can arrange them in an appropriate number in a row and can be continuous by fastening with a joining means such as a long bolt.

Reference numeral 21 denotes a reaction force body caused by local acid provided on the arrival shaft 4 side, and 23 indicates a reaction force wall provided in front of the reaction force body 21.

As the propulsion equipment of the concrete enclosure 9, the pressure jack 10 and the strut 16 are disposed behind the concrete enclosure 9. 20 represents the oscillation band.

As a propulsion facility for the concrete enclosure 9, a towing jack 24 is installed on the reaction wall 23, and the other end of the towing cable 25 having one end installed on the towing jack 24 is connected to the concrete enclosure 9. It is fixed to the fixing apparatus 26 installed in the rear part. A center hole jack can be used for the tow jack 24, and the fixing device 25 is made of a cone and a fixing plate, although not shown.

Then, the towing jack 24 and the fixing device 26 are replaced, and the towing jack 24 is installed at the rear of the concrete housing 9, and one end of the towing cable 25 is installed at the towing jack 24. The other end may be fixed to the fixing device 26 fixed to the reaction wall 23.

4 to 9 are views showing the respective steps of the present invention, and in the same manner as the conventional method, as shown in FIG. 4 in the first step, an earthquake steel outside the upper traffic (not shown) such as a railway By placing a commercially available 2, constructing the oscillation shaft 3 and the reach shaft 4, and installing the propeller 5 into the oscillation shaft 3, the box-shaped loop 6 for the loop is reached. Press in toward (4). On the upper surface of the box-shaped loop 6, a conventional pre-cushion cutter plate 7 is provided and extruded simultaneously with the box-shaped loop 6.

In this case, the box-like loop 6 is arranged in a rectangular shape so as to correspond to the outer shape of the concrete enclosure 9 to be propelled, as shown in FIG. 3.

Further, the earth steel plate 2 on the oscillation gang 3 side and the earth steel plate 2 on the reaching gang 4 side are fixed by a tie rod material 18 via a relief material 17.

The diagonal cut portion surrounded by the box-shaped loop 6 is used to cut a part of the earth steel plate 2, and the earth member 19 fixed by the tie rod material 18 is disposed. As shown in FIG. 5, the earth member 19 and the box-shaped loop 6 are fixed by the temporary fixing member 27. The concrete enclosure 9 is installed in the oscillation table 20 of the oscillation shaft 3.

Next, as shown in FIG. 6 of a 3rd process, the pressure jack 10 is arrange | positioned with a propulsion facility between the rear reaction wall 8 of the concrete enclosure 9. In addition, a towing jack 24 fixed to the reaction wall 23 is provided with a fixing device 26 at the rear of the concrete enclosure 9 and the other end of the towing cable 25 provided with one end of the towing jack 24. Settle in).

Then, the precushion cutter plate 7 is fixed to the oscillation shaft 3 side by the stop member 14. The precushion cutter plate 7 insulates the box loop 6 and the concrete enclosure 9 from the surrounding soil.

As shown in Fig. 7, between the box loop 6 and the front end of the concrete enclosure 9, for example, a press-piece 28 woven in H-shaped steel in a square is disposed, and subsequently extruded in advance. The tip of the concrete enclosure 9 is joined or abutted to the rear end of the box-shaped loop 6.

As shown in FIG. 7 by the 4th process, the pressure jack 10 is extended, the traction jack 24 is operated simultaneously, and the concrete enclosure 9 is reached from the oscillation shaft 3 with the traction cable 25. FIG. Tow toward (4) to extrude the concrete enclosure (9) to the front.

At the same time as the concrete enclosure 9 is extruded, the box loop 6 is also extruded, and at the same time as the extrusion of the box loop 6, the digging of the diagonal cut is not carried out. By extruding the discharged earth member 19, the soil sand 29 in front of it is also extruded simultaneously. In this case, since the box-type loop 6 and the concrete enclosure 9 and the surrounding soil are insulated by the precushion cutter plate 7, the box-loop 6 and the concrete enclosure 9 are smooth. Is promoted.

At the same time as the concrete enclosure 9 is advanced, the strut 16 is disposed between the rear reaction wall 8 of the concrete enclosure 9 to secure the propulsion length of the primary pressure jack 10.

Thus, as shown in FIG. 8 by the 5th process, when the box | seat loop 6 and the earth-like sand 29 enclosed and simultaneously extruded by this box-shaped loop 6 reach | attain the arrival shaft 4, an arrival shaft In (4), the box-shaped loop 6 is removed, and the soil sand 29 is excavated and disposed of.

The second concrete enclosure 9 is connected to the rear of the advanced first concrete enclosure 9, and as shown in FIG. 9, the tip of the concrete enclosure 9 propels up to the reaching shaft 4. The full length propulsion of the concrete enclosure 9 is completed.

As described above, when the underground structure construction method of the present invention is pressed into the box-shaped loop, when the concrete housing is pushed, the earth and sand of the diagonal cut enclosed by the box-like loop is pushed together with the box-shaped loop at the same time as the propulsion of the housing. In addition, it is not necessary to carry out the digging work of the diagonal cutting part, which can reduce the cost and shorten the construction period. In addition, the safety can be improved by omitting the digging work of the diagonal cutting part that carries the risk. By distributing the reaction resistance to propel, it does not require large-scale equipment.

Claims (4)

The box-shaped loop is arranged in a rectangular shape to correspond to the outer shape of the box to be propelled, press-fitted into the ground from the oscillation shaft, and the tip of the box is placed at the end of the box-shaped loop, and the box loop is simultaneously pushed and pulled. Underground construction method, characterized in that the excavated diagonal soil cut out together with the box loop. The method of claim 1, The propulsion of the enclosure is carried out by the propulsion force of the hydraulic jack by arranging the jack and strut as a propulsion facility between the rear of the enclosure and the rear reaction wall of the enclosure, and the towing of the enclosure forms the front reaction wall of the enclosure. Underground structure that is installed by towing the towing jack by installing a fixing device or towing jack at the rear of the fixing device, and fixing the other end of the towing cable having one end of the fixing device or towing jack fixed to a towing jack or a fixing device fixed to the reaction wall. Construction method. The method of claim 1, The box-shaped loop is a basement construction method for placing a pre-cushion cutter plate consisting of a flat plate on the side of the ground. The method of claim 1, An earth structure construction method is provided by disposing a earth member at the diagonal cut portion, and extruding the soil sand at the diagonal cut portion is performed by extruding the earth member to the distal end portion of the enclosure.

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