KR101514222B1 - The Tunnel Sturucture for None Open Cut Type Tunnel Pressing - Google Patents

Abstract

More particularly, the present invention relates to a tunnel structure for a non-detachable tunnel, and more particularly, to a tunnel structure formed by a tunnel structure and a tunnel structure, and a tunnel can be pressed in a desired direction by using a direction adjustment head of the tunnel structure. And a tunnel structure for non-excavation type tunnel excavation having excellent direction control and workability to complete the tunnel skeleton with the tunnel assembly by allowing an auger screw to be installed inside the end structure to easily discharge the gravel to the outside of the tunnel. As a matter of fact,
A tunnel structure for a non-detachable tunnel excavation comprising a tunnel structure and a tunnel structure, the tunnel structure comprising: a structure body having a predetermined length formed according to a tunnel shape; A direction adjusting head installed in front of the body and being press-fitted into the ground together with the body; A plurality of direction-regulating hydraulic jacks positioned behind the direction-regulating head to fix the position of the direction-regulating head; A hydraulic jack for propulsion located behind the direction-regulating hydraulic jack for press-fitting the body and the direction adjusting head into the ground; And an auger screw unit for carrying the gravel inside the direction adjusting head to the outside, wherein the tunnel assembly includes a reaction force beam installed inside the end structure and receiving a reaction force of the hydraulic jack for propulsion; A support beam mounted at a predetermined distance from the reaction force beam; And a soil plate assembled between the reaction beam and the support beam. The present invention also provides a tunnel structure for non-detachable tunneling.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a tunnel structure for non-

More particularly, the present invention relates to a tunnel structure for a non-detachable tunnel, and more particularly, to a tunnel structure formed by a tunnel structure and a tunnel structure, and a tunnel can be pressed in a desired direction by using a direction adjustment head of the tunnel structure. And a tunnel structure for non-excavation type tunnel excavation having excellent direction control and workability to complete the tunnel skeleton with the tunnel assembly by allowing an auger screw to be installed inside the end structure to easily discharge the gravel to the outside of the tunnel. .

Generally, an open trench construction method has been used as a method of constructing tunnel structures such as underpasses and tunnels.

This open trench method is a method to completely construct the tunnel to construct the tunnel structure and then to cover the tunnel with the installed gravel to cover the tunnel construction.

However, this open trench construction method has a problem that construction of a tunnel is carried out in a state where the ground is opened when the tunnel is constructed, and the construction site is restricted by the road or the building on the ground.

In order to solve such a problem, the applicant of the present invention proposed an invention for constructing a tunnel by continuously pushing a tunnel structure in Patent Registration No. 10-0562121. However, in the proposed invention, the roof pipe alone is press- In order to solve problems such as an increase in construction time and an increase in construction time, the present applicant has proposed a tunnel structure for constructing a tunnel structure in a non-installation manner as disclosed in Japanese Patent No. 10-1021867, A main frame provided at the front of the structure for guiding the pressurization of the tunnel structure into the ground, the main frame having a plurality of through holes for forming a loop structure outside the tunnel structure; A soil inflow preventing plate fixed to a rear end of the main frame and having a predetermined length inserted into the tunnel structure to prevent the infiltration of the soil into the tunnel structure; A plurality of forward press-fitting jacks, one side of which is fixedly coupled to a predetermined position of the main frame, the other side of which is adjacent to a front surface of the tunnel structure, and which presses the main frame forward with respect to the tunnel structure; And the tunnel structure is provided on the outer side of the tunnel infiltration prevention plate and the tunnel structure, and the front side of the tunnel is connected to the through hole of the main frame by a predetermined length and is prevented from falling out of the through hole at a predetermined position sandwiched by the through- A loop structure including a plurality of pipes on which a latching jaw is formed; And a press-in blade provided along an outer surface of a front side of the main frame.

However, the above-described techniques have a problem in that it is difficult to adjust the direction of the tunnel structure, and it is difficult to salvage the soil within the tunnel and the work efficiency of forming the skeleton of the tunnel is decreased.

The present invention has been conceived in order to solve the above problems, and it is an object of the present invention to provide a tunnel structure capable of adjusting a tunnel structure in a desired direction, The tunnel structure of the present invention.

It is another object of the present invention to provide a tunnel structure capable of easily forming a skeleton of a tunnel with a tunnel assembly, thereby reducing work efficiency and construction time.

According to an aspect of the present invention, there is provided a tunnel structure for a non-detachable tunnel excavation comprising a tunnel structure and a tunnel structure, wherein the tunnel structure includes: a tunnel structure; A head body disposed in front of the body and being press-fitted into the ground together with the body, and a head shoe formed on the front of the head body; A cylinder rod driven forward and backward in the cylinder, and a direction adjusting head fixing part attached to the front of the cylinder rod, wherein a plurality of Hydraulic jack for direction adjustment; A hydraulic jack for propulsion located behind the direction-regulating hydraulic jack for press-fitting the body and the direction adjusting head into the ground; And an auger screw unit for carrying the gravel inside the direction adjusting head to the outside, wherein the tunnel assembly includes a reaction force beam installed inside the end structure and receiving a reaction force of the hydraulic jack for propulsion; A support beam mounted at a predetermined distance from the reaction force beam; And a current plate assembled between the reaction beam and the support beam, wherein the direction adjusting head fixing unit comprises: a fixed body on which an inclined surface is formed; A plurality of bolt grooves formed on the inclined surfaces in a pair; Guide grooves formed on both side surfaces of the inclined surfaces; A fixing table having both ends thereof inserted into the guide grooves and being moved along the inclined surfaces and the rear end of the direction adjusting head being fixedly supported; And a bolt that is fixed to the bolt groove through a bolt hole formed in the fixing table and adjusts an angle of a direction of the direction adjusting head according to a position where the bolt hole is fastened to the bolt groove. For example a tunnel structure.

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In the present invention, the auger screw portion includes a front pipe, a rear pipe connected to the front pipe by a hinge, a front auger screw installed inside the front pipe, a rear auger screw installed inside the rear pipe, A universal joint connecting the auger screw and the rear auger screw, and a motor connected to the rear auger screw to rotate the front and rear auger screws.

In the present invention, a groundwater inflow preventing sheet is further provided on the outside of the soil plate.

As described above, the tunnel structure for non-detachable tunnel excavation according to the present invention can adjust the tunnel structure in a desired direction, and can easily carry out the soil inside the tunnel structure to the outside, thereby improving the direction control and the work efficiency .

In addition, the present invention has an effect that it is possible to easily form a skeleton of a tunnel with a tunnel assembly, thereby reducing work efficiency and construction time.

1 is a perspective view of a tunnel structure according to the present invention;
2 is a sectional view of a tunnel structure according to the present invention.
3 is a perspective view of a direction adjusting head fixing unit according to the present invention;
4 is an exploded perspective view of a direction adjusting head fixing unit according to the present invention;
5 is a cross-sectional view of the structure body viewed from line AA 'of FIG. 2;
6 is a cross-sectional view of the structure body viewed from line BB 'of FIG. 2;
7 is a perspective view of an auger screw section according to the present invention.
8 is a perspective view of an auger screw in a bent state according to the present invention.
9 is a sectional view of an auger screw portion according to the present invention in a bent state.
10 is a perspective view of a tunnel assembly according to the present invention.
11 is an assembled perspective view of the dust pan according to the present invention.
12 is a sectional view of a tunnel assembly according to the present invention.
13 is another embodiment of the tunnel structure according to the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS The present invention will now be described more fully with reference to the accompanying drawings, in which exemplary embodiments of the invention are shown. In the description of the embodiments, the same names and symbols are used for the same components, and further description thereof will be omitted.

2 is a cross-sectional view of a tunnel structure according to the present invention, FIG. 3 is a perspective view of a direction adjusting head fixing part according to the present invention, FIG. 4 is a perspective view of a direction FIG. 5 is a cross-sectional view of the structure body viewed from line AA 'of FIG. 2, FIG. 6 is a cross-sectional view of the structure body viewed from line BB' of FIG. 2, 9 is a sectional view of the auger screw portion according to the present invention in a bent state, and Fig. 10 is a perspective view of the tunnel assembly according to the present invention. Fig. 9 is a perspective view of the auger screw portion, 12 is a sectional view of a tunnel assembly according to the present invention, and FIG. 13 is another embodiment of a tunnel structure according to the present invention.

1 and 2, a tunnel structure 10 according to the present invention includes a tunnel structure 100 and a tunnel structure 200. The end structure 100 is composed of a structure body 101 and a direction adjusting head 110 formed inside the structure body 101. A hydraulic jack 120 for direction adjustment for fixing the direction of the direction adjusting head 110 and a hydraulic jack 130 for pushing forward the front structure 100 forward are installed inside the structure body 101, Is installed. The direction-controlling hydraulic jack 120 and the propelling hydraulic jack 130 are installed one above the other.

2 to 4, the direction-controlling hydraulic jack 120 includes a hydraulic cylinder 121, a cylinder rod 122 mounted on and driven by the hydraulic cylinder 121, And a direction adjusting head fixing portion. The direction adjusting head fixing unit includes a fixed body 123 and a fixing table 126. A pair of bolt grooves 124 are formed on the inclined surface, and guide grooves 125 are formed on both sides of the inclined surface. The guide 129 formed on the fixing table 126 moves along the inclined surface along the guide groove 125. A bolt hole 127 is formed in the fixing table 126 so that the bolt 128 can be fixed to the bolt groove 124. A bolt 128 passing through the bolt through hole 127 is formed in the bolt groove 124, And the fixing table 126 is fixed. Since the rear end of the direction adjusting head 110 is fixed to the fixing table 126 and the hydraulic jack 140 for driving is driven, the direction adjusting head 110 is fixedly supported by the direction controlling hydraulic jack 120, The direction adjusting head 110 is pressed into the ground. The direction adjusting head 110 is composed of a head body 111 and an end shoe 112 formed at the front end of the stop. The direction adjusting head fixing unit can change the position of the fixing table 126 and change the position of the fixing table 126 by forming the inclined surface on the fixed body 123 and forming the bolt hole 124 on the inclined surface, The position of the end of the adjustment head 110 is changed so that the direction of the tunnel can be adjusted. That is, when the user wants to move downward, the fixing base 126 of the upper direction adjustment fixing unit is fixed to the front side of the inclined surface and the fixing base of the lower direction adjusting fixing unit is fixed to the back side, Direction, and thus the tunnel can proceed downward. If it is desired to move upward, the fixing table 126 may be fixed to the opposite direction. In the case of moving in the left and right directions, the left fixing table 126 is fixed to the rear side of the inclined surface, and when the right fixing table 126 is fixed to the front side of the inclined surface, the direction of the direction adjusting head 110 is directed to the left . Further, as shown in FIG. 2, the work plate 160 may be further formed on the auger screw portion 140. The work board 160 is designed to allow the worker, the construction machine, and the like to smoothly carry out the work. The working plate 160 is formed with a front soil inflow hole 161 for allowing the soil to flow into the auger screw unit 140 and an auger screw unit 140 for moving up and down the auger screw unit 140 A hole 162 is formed. A front auger 146 is protruded from the front end of the work plate 160 and a soil inflow preventing plate 163 connected to the working plate 160 is installed at an angle other than the auger screw 140, Thereby preventing the soil from flowing around the Auger screw portion 140. By installing the soil inflow prevention plate 163, the soil can be taken out through the auger screw unit 140.

5 and 6 show support members for supporting the hydraulic jacks installed inside the structure body 101 of the end structure. 5 is a front supporting member 102 for supporting the direction controlling hydraulic jack 120. A hydraulic jack supporting hole 103 for direction adjustment is formed at the upper and lower portions of the front supporting member 102, At the center, a work tool 104 through which an operator and a work vehicle can pass is formed. And an auger screw portion support groove 105 on which the auger screw portion 140 is seated is formed at the lower portion. 6 is a rear support member 106 for supporting the hydraulic jack 130 for propulsion and has a hydraulic jack support hole 107 for pushing for supporting the hydraulic jack 130 for propulsion at the upper and lower parts, A work tool 108 through which a work vehicle or the like can pass can be formed. And an auger screw portion support groove 109 on which the auger screw portion 140 is seated is formed at the lower portion.

Figs. 7 to 9 are views of the auger screw portion. The auger screw portion 140 includes a front pipe 141, a rear pipe 144 connected to the front pipe 141 and the hinge portion 143, and a front auger 146 A rear auger screw 148 provided inside the rear pipe 144, a universal joint 147 connecting the front auger 146 and the rear auger 148, a rear auger screw 148, And a motor 150 connected to the front and rear auger screws to rotate the front and rear auger screws. The auger screw part 140 is used to take out the gravel to the outside, and is used to take out the gravel excavated by a construction machine such as a fork crane, as shown in Fig. The front end of the front pipe 141 is opened to carry the gravel to the outside and the gravel inlet hole 142 may be further formed in the front pipe 141 so that the gravel can be introduced into the upper portion. The front pipe 141 and the rear pipe 144 are connected to the hinge 143. Since the hinge portion 143 is formed, it is possible to rotate up and down at a predetermined angle. The rear pipe 144 is formed to have a greater diameter than the rear pipe 144 so that the front pipe 141 can be inserted into the rear pipe 144. The front auger screw 146 and the rear auger screw 148 are connected to each other by a universal joint 147 inside the pipe. Since they are mutually connected by the universal joint, the rear pipe can rotate up and down at a predetermined angle. The rear auger screw 148 is connected to the motor unit 150 by a joint 153. The motor unit 150 includes a motor and a motor shaft 152. The motor 151 uses a bolt 144 And is fixedly mounted to the rear pipe 144.

Figures 10-12 are views of a tunnel assembly. 10, the tunnel assembly 200 includes a reaction force beam 210 acting as a reaction force wall of the hydraulic jack for propulsion, a support beam 220 installed at a predetermined distance from the reaction force beam 210, A soil plate 202 mounted between the beam 210 and the support beam 220 and an underground water inflow prevention sheet 201 installed outside the soil plate 202 for preventing inflow of groundwater. The soil plate 202 is for preventing the ingress of gravel, and metal or wood can be used. The shape may be the same as the embodiment shown in the drawings, but the shape may have various shapes. It is also possible to use a circular or square wood such as a pipe. It is also possible to use a shearing iron sheet, which is a metallic material, as a soil board. In the case of the reaction beam 210 or the support beam 220, the beam is shown as a straight line in the present embodiment, but in the case of a cylindrical tunnel, the beam is formed into a cylindrical shape. In the case of a tunnel having an arcuate upper portion, A beam is formed in an arcuate shape. Further, in the case of an elliptical shape, the beam is formed into an elliptical shape. The shape of the beam can be freely deformed according to the shape of the tunnel.

FIG. 13 shows another embodiment of the tunnel structures 10 ', 10''and10''' according to the shape of the tunnel. As shown in Fig. 13, any type of tunnel, round, oval or arcuate, as well as a rectangular tunnel is possible.

While the invention has been shown and described with reference to certain preferred embodiments thereof, it will be understood by those skilled in the art that various changes and modifications may be made therein without departing from the spirit and scope of the invention as defined by the appended claims. Therefore, the above description does not limit the scope of the present invention, which is defined by the limitations of the following claims.

10, 10 ', 10 ", 10 "': Tunnel structure
100: end structure 101: structure body
102: front support member 103: hydraulic jack support hole for adjusting the direction
104: Work assembly 105: Auger screw support groove
106: rear support member 107: hydraulic jack support hole for propelling
108: Work assembly 109: Auger screw support groove
110: direction adjusting head 111: head body
112:
120: Hydraulic jack for direction adjustment 121: Hydraulic cylinder
122: cylinder rod 123: fixed body
124: bolt groove 125: guide groove
126: fixed base 127: bolt hole
128: Bolt 129: Guide
130: Hydraulic jack for propulsion
140: Auger screw portion 141: Front pipe
142: a soil inflow hole 143: a hinge section
144: rear pipe 145: soil discharge hole
146: front auger screw 147: universal joint
148: rear auger screw 150: motor part
151: motor 152: motor rotation axis
153: joint 154: motor fixing bolt
160: Working plate 161: Earth-filled hole
162: rear pipe penetration hole 163:
200: Tunnel assembly 201: Groundwater inflow prevention sheet
202:
210: Reaction beam 220: Support beam

Claims (6)

A tunnel structure for non-detachable tunnel excavation comprising a tunnel structure and a tunnel structure,
The end structure includes:
A structure body having a predetermined length formed according to a tunnel shape; A head body disposed in front of the body and being press-fitted into the ground together with the body, and a head shoe formed on the front of the head body; A cylinder rod driven forward and backward in the cylinder, and a direction adjusting head fixing part attached to the front of the cylinder rod, wherein a plurality of Hydraulic jack for direction adjustment; A hydraulic jack for propulsion located behind the direction-regulating hydraulic jack for press-fitting the body and the direction adjusting head into the ground; And an auger screw portion for carrying the gravel inside the direction adjusting head to the outside,

The tunnel assembly includes:
And an elastic member provided on the inner side of the end structure,
A reaction force beam for receiving a reaction force of the hydraulic jack for propulsion; A support beam mounted at a predetermined distance from the reaction force beam; And a current plate assembled between the reaction beam and the support beam,
The direction adjusting head fixing unit includes: a fixed body on which an inclined surface is formed; A plurality of bolt grooves formed on the inclined surfaces in a pair; Guide grooves formed on both side surfaces of the inclined surfaces; A fixing table having both ends thereof inserted into the guide grooves and being moved along the inclined surfaces and the rear end of the direction adjusting head being fixedly supported; And a bolt that is fixed to the bolt groove through a bolt hole formed in the fixing table and adjusts an angle of a direction of the direction adjusting head according to a position where the bolt hole is fastened to the bolt groove. Dragon tunnel structure.
delete delete delete The method according to claim 1,
The auger screw portion
A rear pipe connected to the front pipe by a hinge; a front auger screw installed inside the front pipe; a rear auger screw installed inside the rear pipe; and a front auger screw and a rear auger screw, And a motor connected to the rear auger screw to rotate the front and rear auger screws. 2. The non-detachable tunnel structure according to claim 1,
The method according to claim 1,
And a groundwater inflow preventing sheet is further provided on the outside of the soil plate.

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