JP6692203B2 - Setup method for setup reinforcement structure for tunnel and steel reinforcement for lining concrete - Google Patents

Description

  The present invention relates to a setup bar structure for a tunnel and a method for installing a reinforcing bar for a lining concrete.

  Conventionally, the method of installing reinforced concrete reinforcing bars is to make holes in the waterproof sheet of the part that covers the support work embedded in the lining and fix the anchor bars for attaching setup bars to the internal support work. Along with this, there has been known a method of covering the holes of the waterproof sheet with washers having a sealing material to stop water. However, since there is a possibility that water resistance may be impaired due to deterioration or damage of the sealing material, in recent years, there has been a tendency to adopt a construction method in which setup bars or the like are arranged without forming holes in the waterproof sheet (for example, patents). References 1 and 2).

  In the construction method of Patent Document 1, first, a sandwiched member is attached to the inner peripheral surface of the support work embedded in the primary lining concrete, and the support work and the primary lining concrete are covered with a waterproof sheet. After that, the sandwiched member covered with the waterproof sheet is sandwiched by sandwiching metal fittings, and the anchor line is fixed to the sandwiching member. Then, set-up bars and main reinforcing bars are attached to the anchor bars. If the anchor streak is installed in the waterproof sheet without forming a hole by such a process, it is possible to prevent the water from the natural ground from entering the secondary lining concrete.

  In the construction method of Patent Document 2, first, at least two sets of arch-shaped set-up bars are attached to the scaffold beam via a reinforcing bar fixing tool. Then, two sets of arch-shaped main reinforcing bars are arranged on the center side of the tunnel of the arch-shaped set-up bars, and two arch-shaped set-up bars and two arch-shaped main bars are connected by connecting metal fittings. To form arched columns. After that, a long set-up bar and a reinforcing bar are arranged in the extending direction of the tunnel on the arch-shaped column, and further an arch-shaped main reinforcing bar is arranged. Then, after attaching the support fitting to the connecting fitting, the reinforcing bar fixing tool is removed. According to such a process, even if the reinforcing bar fixture is removed, both side portions of the arch-shaped column do not expand outward, so that it is possible to prevent deformation of the top end sinking. As a result, the arch reinforcing bars can be made independent without making holes in the waterproof sheet.

JP, 2004-150117, A Japanese Patent No. 5461210

The method of Patent Document 1 has a problem that the waterproof sheet is easily broken when the waterproof sheet is sandwiched by the sandwiching metal fittings. In addition, it is necessary to attach a member to be clamped to the support work, which causes an increase in construction work.
In the construction method of Patent Document 2, since two set-up streaks are used as a set, there is a problem that the structure is complicated and the cost is increased.

  From such a point of view, it is an object of the present invention to provide a setup bar structure for tunnels and a method for installing reinforcing bars for lining concrete that can be easily constructed with a simple structure.

A first aspect of the present invention for solving the above-mentioned problems is a tunnel setup bar structure for installing reinforcing bars to be reinforced in the lining concrete of the upper half of the tunnel, and the upper half of the inner peripheral surface of the tunnel. Arch-shaped setup streaks extending along the waterproof sheet laid in the section, spacers attached to the setup streaks, and arch-shaped main arches arranged between the setup streaks adjacent in the tunnel axial direction. Reinforcing bars, distribution bars that are fixed to the setup bars and the arch-shaped main reinforcing bars on the ground side and extend in the tunnel axial direction, axial rebars attached to the tip of the spacer, and fixed to the axial rebars And an inner arch-shaped rebar that is formed, the end of the setup bar is fixed to the upper end of the invert concrete in the lower half of the tunnel, and the setup bar is a plurality of arc-shaped rebars and the circumferential direction of the tunnel. Next to A length adjusting member that connects the arc-shaped reinforcing bars that fit together, the spacer extends along a thickness direction of the lining concrete, and an outer end portion of the spacer has the waterproof sheet. It is a setup muscle structure for a tunnel characterized by being in contact with.

  In the present invention, the "upper end portion of invert concrete" also includes a rising wall integrally formed on the invert concrete. The "length adjusting member" is a member such as a turnbuckle that can adjust the interval between the arcuate reinforcing bars. According to the above configuration, the setup streak can have a simple structure. When the length adjusting member is extended, the arch-shaped setup streak expands to the outside and the spacer abuts on the inside of the waterproof sheet, so that the position can be easily adjusted. Further, since the spacer only contacts the waterproof sheet from the inside, it is not necessary to make a hole in the waterproof sheet. Therefore, the waterproof performance is high, and the waterproofing is possible even when the water pressure of the natural ground is high.

  Further, in the tunnel setup muscle structure according to the present invention, the spacer includes a screw rod and a gripping member that grips the setup muscle, and the gripping member is a nut portion screwed to the screw rod. And a grip portion that can rotate relative to the nut portion. With such a configuration, the position of the reinforcing bar can be adjusted by rotating the nut portion and moving the screw rod in the axial direction.

  Further, in the setup muscle structure for tunnel according to the present invention, a plurality of the setup muscles are arranged in parallel at intervals in the tunnel axial direction, and a bar-shaped member is bridged between the adjacent setup muscles. Preferably. With such a configuration, it is possible to maintain a constant interval between the setup streaks adjacent to each other in the tunnel axis direction with a simple configuration.

The second aspect of the present invention for solving the above-mentioned problems is a method of installing a reinforcing bar for lining concrete that installs a reinforcing bar to be reinforced inside the lining concrete, inside the waterproof sheet laid in the upper half of the tunnel. There is a setup bar forming step of connecting a plurality of arc-shaped reinforcing bars with a length adjusting member to form an arch-shaped setup bar, and a setup bar that fixes the setup bar to the upper end of the inverted concrete in the lower half of the tunnel. A fixing step, a spacer attaching step of attaching a spacer extending along the thickness direction of the lining concrete to the setup streak, and extending the length adjusting member so that the tip end portion of the spacer is the waterproof sheet. and setup muscle position adjusting step of contact with the inner peripheral surface, the setup muscle and the spacer, and a reinforcing bar fixing step of fixing the various rebar, in the reinforcing bar fixing step, the tunnel axis direction The arch-shaped main rebar on the ground side is arranged between the setup rebars adjacent to each other, and the force distribution bar extending in the tunnel axial direction is fixed to the setup rebar and the main rebar on the ground side arch, and the tip of the spacer A method of installing a reinforcing bar for lining concrete, characterized in that an axial reinforcing bar is attached to the portion, and an inner arch reinforcing bar is fixed to the axial reinforcing bar.

  According to such a method, when the length adjusting member is extended and the arch-shaped setup streak is expanded outward, the spacer comes into contact with the inside of the waterproof sheet, and the position of the setup streak is adjusted. Further, since the spacer only contacts the waterproof sheet from the inside, it is not necessary to make a hole in the waterproof sheet. Therefore, the waterproof performance is high, and the waterproofing is possible even when the water pressure of the natural ground is high.

  In the method for installing a reinforcing bar for lining concrete according to the present invention, in the step of fixing the set-up bar, a plurality of the set-up bars are arranged in parallel at intervals in the tunnel axial direction, and a bar-shaped member is bridged between the adjacent set-up bars. It is preferable to adjust the distance between the setup streaks. According to such a method, the interval between the setup streaks adjacent to each other in the tunnel axis direction can be easily and reliably kept constant.

  According to the present invention, construction can be easily performed with a simple structure.

It is a perspective view showing the setup muscle structure for tunnels concerning an embodiment of the present invention. (A) is the front view which showed the setup bar, (b) and (c) are the enlarged views which showed the connection part of a reinforcing bar. It is the perspective view which showed the spacer. It is an exploded perspective view showing a spacer. It is a figure for demonstrating the installation method of the steel reinforcement for lining concrete which concerns on embodiment of this invention, Comprising: It is the perspective view which showed the state before installation of the setup reinforcement. It is a perspective view showing the fixed state of the lower end of the setup muscle. It is a perspective view showing the state where the rod-shaped member was bridged between the adjacent setup lines. It is the perspective view which showed the state which attached the spacer to the setup streak. It is the front view which showed the state which extended the turnbuckle and made the spacer contact the inner peripheral surface of the waterproof sheet. It is the perspective view which showed the connection part of a setup streak, a spacer, and the connection part of reinforcing bars. FIG. 3 is a perspective view showing a state in which a ground-side arched main reinforcing bar and a reinforcing bar are arranged. It is the perspective view which showed the state which attached the axial direction reinforcing bar to the front-end | tip part of a spacer. It is the perspective view which showed the state which attached the inner arch-shaped main rebar.

  Hereinafter, a method of installing a setup bar structure for a tunnel and a reinforcing bar for a lining concrete according to an embodiment of the present invention will be described with reference to the accompanying drawings. First, the configuration of the setup muscle structure for a tunnel will be described. As shown in FIG. 1, the tunnel setup rebar structure 1 according to the present embodiment is for installing rebars to be laid in the lining concrete in the upper half of the tunnel, and is an arch-shaped setup bar. 10 and a spacer 30. A waterproof sheet 2 is laid on the upper half of the inner surface of the tunnel.

  The set-up streak 10 has an arch shape extending along the waterproof sheet 2. As shown in FIG. 2, the setup bar 10 is provided with a plurality of arc-shaped reinforcing bars 11, 11, ..., A length adjusting member 12, and a connecting member 13.

  The arc-shaped reinforcing bar 11 is a reinforcing bar for forming the setup reinforcing bar 10, and is formed by bending a deformed reinforcing bar, for example. The arcuate reinforcing bar 11 has a curvature along the upper half of the inner peripheral surface of the tunnel.

  The length adjusting member 12 is a member that connects the arc-shaped reinforcing bars 11, 11 that are adjacent to each other in the tunnel circumferential direction so as to be able to approach and separate from each other. That is, the length adjusting member 12 adjusts the distance between the arcuate reinforcing bars 11 and 11, and can adjust the entire length of the setup reinforcing bar 10. The length adjusting members 12 are provided at two locations, an upper left portion and an upper right portion. As shown in FIG. 2B, the length adjusting member 12 of the present embodiment is composed of a turnbuckle. The turnbuckle includes a body portion 14 having opposite female thread portions formed at both ends, and a pair of screw members 15a and 15b screwed into the respective female thread portions. By rotating the body portion 14, The screw members 15a and 15b are adapted to come close to or separate from each other. One screw member 15a is welded to one arc rebar 11 of the adjacent arc rebars 11 and 11, and the other screw member 15b is welded to the other arc rebar 11. The shape of the turnbuckle is an example, and other shapes may be used. The length adjusting member 12 is not limited to the turnbuckle and may be another jig.

  The connecting member 13 is a member that connects the arc-shaped reinforcing bars 11, 11 adjacent to each other in the tunnel circumferential direction. The connecting member 13 is composed of, for example, a tubular coupler. As shown in (c) of FIG. 2, the coupler includes a metal tubular portion 16 and a bolt 17. Bolt holes extending in a direction orthogonal to the axial direction are formed in the cylindrical portion 16. One end of one arc-shaped reinforcing bar 11 of the adjacent arc-shaped reinforcing bars 11 is inserted into one end of the tubular portion 16 and welded. The other end of the arc-shaped reinforcing bar 11 is inserted into the other end of the tubular portion 16 and is fixed by a bolt 17. Specifically, the bolt 17 is screwed into the bolt hole, and the tip end of the bolt 17 is pressed against the side surface of the arc-shaped reinforcing bar 11 inserted into the inside of the tubular portion 16 to be fixed. Note that the shape of the connecting member 13 is an example, and may have another shape.

  As shown in FIG. 1, a plurality of setup muscles 10 are arranged in parallel at intervals in the tunnel axis direction. A bar-shaped member 20 is bridged between the setup streaks 10 and 10 that are adjacent to each other in the tunnel axis direction. As shown in FIG. 7, the bar-shaped member 20 is for keeping the distance between the setup streaks 10 and 10 constant and arranging the setup streaks 10 and 10 in parallel with each other. It has been extended. A plurality of rod-shaped members 20 are arranged at predetermined intervals along the longitudinal direction of the setup streak 10. The rod-shaped member 20 is formed in a U-shape when viewed from the front by bending both ends of the reinforcing bar into an L-shape. The bent tip ends of both ends of the rod-shaped member 20 are inserted into a pipe 21 (sheath pipe) welded to a predetermined position of the setup muscle 10, so that the rod-shaped member 20 is locked to the setup muscle 10. The rod-shaped members 20, 20 adjacent to each other in the tunnel axis direction are arranged in a staggered manner. Specifically, the bar-shaped members 20 that are adjacent to each other in the tunnel axial direction are arranged substantially in the middle of the height positions of the two bar-shaped members 20, 20 that are arranged at intervals in the longitudinal direction of the setup streak 10.

  The shape of the rod-shaped member 20 is not limited to the above configuration. Brackets may be respectively provided at predetermined positions of the end portion of the rod-shaped member and the set-up streak and fixed by bolts or pins.

  The spacer 30 is a positioning member for arranging the setup streak 10 at a predetermined distance from the waterproof sheet 2 on the inner peripheral surface of the tunnel, and is attached to the setup streak 10. The spacer 30 extends in the thickness direction of the lining concrete. The spacer 30 includes a screw rod 31 and a gripping member 41 that grips the setup streak 10.

  As shown in FIGS. 3 and 4, the screw rod 31 is attached to the base portion 32. The base portion 32 includes, for example, a concrete column 33 having a circular cross section, and a nut 34 embedded in the surface portion of the concrete column 33. The screw rod 31 is erected on the base portion 32. The end of the screw rod 31 is screwed into the nut 34. A tightening nut 35 is screwed onto the base end of the screw rod 31 (end on the base 32 side). The tightening nut 35 is fastened to the nut 34. The shape and material of the base 32 are not limited to those in the present embodiment, and may be another material such as a metal plate or a resin block. The screw rod 31 has a length that extends from the vicinity of the inner peripheral surface of the waterproof sheet 2 of the tunnel to the vicinity of the inner surface of the lining concrete. When the thickness of the lining concrete is large, a plurality of screw rods may be coaxially connected using a connection nut.

  The grip member 41 includes a nut portion 42 and a grip portion 43. As shown in FIG. 4, the nut portion 42 includes a nut body 44 and a cylindrical portion 45 attached to the nut body 44. The nut body 44 is screwed onto the screw rod 31. By rotating the nut body 44, the entire grip member 41 moves along the axial direction of the screw rod 31. The nut body 44 is located closer to the tip of the screw rod 31 than the cylindrical portion 45. The nut body 44 is a nut with a washer. The cylindrical portion 45 is welded to the end surface of the nut body 44 on the washer 44a side. The cylindrical portion 45 has an inner diameter through which the screw rod 31 can be inserted. The cylindrical portion 45 is arranged coaxially with the nut body 44. The outer diameter of the cylindrical portion 45 is smaller than the outer diameter of the washer 44a portion of the nut body 44. The washer portion of the nut body 44 constitutes a flange portion at one end portion of the cylindrical portion 45 (end portion on the nut body 44 side). A washer 46 is attached to the other end of the cylindrical portion 45. The outer diameter of the washer 46 is larger than the outer diameter of the cylindrical portion 45. The washer 44a (collar portion) is locked to one end portion of an outer cylindrical portion 47 described later. The washer 46 is locked to the other end of the outer cylinder portion 47.

  The grip portion 43 includes an outer cylinder portion 47 and a grip fitting 48. The outer cylinder portion 47 is arranged so as to surround the cylindrical portion 45. That is, the grip member 41 has a double pipe structure including the outer cylinder portion 47 and the cylinder portion 45. The outer tubular portion 47 has a tubular shape with a square cross section, and is rotatable relative to the cylindrical portion 45. The outer cylinder portion 47 is located between the washer 44 a and the washer 25, and is prevented from falling off from the cylindrical portion 45.

  The grip fitting 48 is welded to the side surface of the outer tubular portion 47. The grip fitting 48 is a fitting for sandwiching the reinforcing bar, and includes a main body 49 having a C-shaped cross section, and a bolt 50 screwed to the main body 49. A reinforcing bar passage space 49s is formed at an inner corner of the main body 49. The bolt 50 is screwed into a screw hole (not shown) formed in the main body 49. The bolt 50 is arranged so as to project and retract toward the side surface of the reinforcing bar passing through the reinforcing bar passing space 49s. When the tip of the bolt 50 is pressed against the side surface of the reinforcing bar by rotating the bolt 50, the reinforcing bar is sandwiched between the inner peripheral surface of the main body 49 and the tip of the bolt 50.

  According to the grip member 41 having the above-described configuration, it is possible to rotate only the nut portion 42 without rotating the grip portion 43. That is, even when the grip portion 43 grips the reinforcing bar (fixed state), the screw rod 31 is moved relative to the grip member 41 (moved in the axial direction of the screw rod 31) by rotating the nut portion 42. Can be made

  Next, the operation and effect of the installation method of the tunnel setup wire structure 1 and the lining concrete reinforcing bar will be described while explaining the installation method of the lining concrete rebar including the tunnel setup wire structure 1 having the above-described configuration. 7, 8 and 11 to 13 are perspective views of the setup streak 10 and the like as seen from the ground side, and illustration of the tunnel wall surface and the waterproof sheet 2 is omitted.

  Fig. 5 shows a state before the reinforcing steel for lining concrete is reinforced. As shown in the figure, an invert concrete 3 is constructed in the lower half of the tunnel, and a road surface 4 is formed inside the invert concrete 3. Anchor bars 5 are provided at a predetermined pitch on the upper end surface of the invert concrete 3. A waterproof sheet 2 is laid on the upper half of the tunnel.

(Setup line forming process)
When arranging the reinforcing steel for lining concrete, first, a plurality of arc-shaped reinforcing bars 11, 11, ... Are connected by a turnbuckle (length adjusting member 12) and a connecting member 13 to form an arch-shaped setup bar 10. (See (a) of FIG. 2). At this time, the turnbuckle has a short length so that it can be extended later. Further, a pipe 21 for locking the rod-shaped member 20 is welded to a predetermined position of the setup streak 10 in advance.

(Setup muscle fixing process)
Then, as shown in FIG. 6, the lower end of the setup bar 10 is fixed to the upper end of the invert concrete 3. Specifically, the angle member 51 is bridged over the two anchor bars 5 and 5 rising from the upper end of the invert concrete 3. Two bolt insertion holes (not shown) are formed at both ends in the length direction of the angle member 51 at positions corresponding to the anchor bars 5 and 5. While the anchor muscle 5 is surrounded by the U-shaped bolt 52, the pair of shaft portions of the U-shaped bolt 52 are inserted into the bolt insertion holes and tightened with the nut 53. Thereby, the angle member 51 is fixed to the anchor bar 5. Two bolt insertion holes are formed in the central portion of the angle member 51 in the length direction. The lower end of the setup streak 10 is installed at a position corresponding to the central bolt insertion hole, and while the setup streak 10 is surrounded by the U-shaped bolt 52, the pair of shaft portions of the U-shaped bolt 52 are inserted into the bolt insertion hole. Tighten with the nut 53. As a result, the setup reinforcement 10 is fixed to the angle member 51, and the lower end of the setup reinforcement 10 is fixed to the upper end of the invert concrete 3.

  In the present embodiment, the anchor bar 5 rises from the upper end of the invert concrete 3, but the anchor bar may rise from a rising wall integrally formed on the invert concrete. This integral riser wall is also included at the top of the invert concrete.

  As shown in FIG. 7, a plurality of setup muscles 10 are arranged in parallel at intervals in the tunnel axis direction. The rod-shaped member 20 is bridged between the adjacent setup streaks 10 and 10. By inserting the bent tips of both ends of the rod-shaped member 20 into the pipe 21, the rod-shaped member 20 is locked to the setup streak 10. A plurality of rod-shaped members 20 are provided at predetermined intervals along the inner circumference of the tunnel. As a result, the distance between the setup streaks 10 is adjusted, and the setup streaks 10 are arranged in parallel with each other. Furthermore, since the arch-shaped set-up bar 10 is connected three-dimensionally by connecting the bar-shaped members 20, the rigidity of the lining concrete reinforcing bar can be increased.

(Spacer mounting process)
Next, as shown in FIGS. 8 and 9, the spacer 30 is attached to the predetermined position of the setup streak 10. This work is performed from a work trolley or an aerial work vehicle installed in the tunnel. In the spacer 30, the position of the nut portion 42 with respect to the screw rod 31 is adjusted in advance, and the distance from the position of the grip member 41 to the end surface of the base portion 32 becomes equal to the distance between the setup streak 10 and the waterproof sheet 2 at the desired position. It is configured as follows. Specifically, as shown in FIG. 10, the gripping portion 43 of the gripping member 41 is covered on the setup bar 10, and the setup bar 10 is positioned in the reinforcing bar passage space 49s. Then, the bolt 50 is rotated to press the tip end portion of the bolt 50 against the side surface of the setup streak 10. Thereby, the spacer 30 is fixed to the setup muscle 10.

(Setup muscle position adjustment process)
When the set-up streak 10 is installed, the set-up streak 10 is bent downward due to its own weight, and therefore it is necessary to remove the bending. Therefore, the length adjusting member 12 is extended to remove the bending. That is, by increasing the total length of the setup muscle 10, the arch-shaped setup muscle 10 spreads outward. In other words, the setup streak 10 and the spacer 30 are spread toward the surface of the tunnel to remove the bending. At the same time, the end portion of the spacer 30 on the base portion 32 side contacts the inner peripheral surface of the waterproof sheet 2, so that the setup streak 10 is arranged at a predetermined position from the inner peripheral surface of the tunnel. As a result, the position of the setup streak 10 is adjusted.

  When there is a base 32 that is not partially in contact with the waterproof sheet 2 among the bases 32 of the plurality of spacers 30, the inner peripheral surface of the tunnel (the surface of the waterproof sheet 2) has irregularities (unevenness). This is the case. At this time, the screw rod 31 is moved in the axial direction by rotating the nut portion 42 (relatively rotating with respect to the grip portion 43 that grips the setup muscle 10). By doing so, the floating base portion 32 can be brought into contact with the waterproof sheet 2 with the spacer 30 fixed to the setup muscle 10. As a result, it is possible to absorb the irregularities (unevenness) on the inner peripheral surface of the tunnel (surface of the waterproof sheet 2).

(Reinforcing bar fixing process)
In the reinforcing bar fixing step, various reinforcing bars such as main reinforcing bars for lining concrete are fixed to the setup bar 10 and the spacer 30. As shown in FIG. 10 and FIG. 11, first, the ground-side arch main rebars 55, 55 are arranged between the adjacent setup rebars 10, 10 so that the setup rebar 10 and the ground-side arch main rebar 55 are inside the tunnel. Then, a force distribution muscle 56 extending in the tunnel axial direction is arranged. The distribution muscles 56 are fixed at the intersections with the setup reinforcements 10 and the intersections with the ground-side arch-shaped main rebars 55 with the number lines. At this time, the distribution muscles 56 are arranged inside the setup muscles 10 and the ground-side arched main reinforcing bars 55, so that the distribution muscles 56 are easily installed and the distribution muscles 56 are less likely to contact the waterproof sheet 2. Thereby, damage to the waterproof sheet 2 can be prevented.

  Next, as shown in FIGS. 10 and 12, the axial reinforcing bar 63 is attached to the tip of the spacer 30 inside the tunnel (the tip of the screw rod 31). Note that, in FIG. 12 and FIG. 13 below, in order to prevent complication of the drawing, the illustration of the main arch-side main reinforcing bar 55, the force distribution bar 56, and the bar-shaped member 20 is omitted. The axial reinforcing bar 63 is fixed to the screw rod 31 via a known connecting jig 60 (see FIG. 10). The connection jig 60 is a jig for fixing mutually orthogonal reinforcing bars, and includes a U-shaped main body portion 61 and a bolt 62. The side surface of the body 61 is provided with a notch into which the axial reinforcing bar 63 is inserted. The axial rebar 63 is fixed to the spacer 30 by pressing the side surface of the axial rebar 63 inserted in the notch with the tip of the bolt 62. The axial reinforcing bars 63 are bridged and supported by the spacers 30, 30, ... Lined up in the tunnel axial direction. The axial reinforcing bars 63 are arranged at intervals in the tunnel circumferential direction.

  After that, as shown in FIG. 13, the inner arch-shaped rebar 64 is arranged inside the tunnel of the axial rebar 63 and fixed to the axial rebar 63. The inner arch-shaped reinforcing bar 64 is fixed by a number line at an intersection with the axial reinforcing bar 63. Through the above steps, the reinforcement of the lining concrete reinforcing bar is completed.

  According to the method for installing the tunnel setup wire structure 1 and the lining concrete rebar according to the present embodiment, the setup bar 10 can have a simple structure and can be easily formed and installed. Further, since the tunnel setup bar structure 1 is a simple structure composed of a small number of reinforcing bars, it bends downward due to its own weight, but the flexure can be removed by providing the length adjusting member 12. The work of removing the bending can be achieved by a simple work of extending the length adjusting member 12.

  Furthermore, since the arch-shaped setup streak 10 spreads outward and the spacer 30 contacts the waterproof sheet 2 only by extending the length adjusting member 12, the position of the setup streak 10 can be easily adjusted. Further, since the spacer 30 only contacts the waterproof sheet 2 from the inside, it is not necessary to make a hole in the waterproof sheet 2. Further, since the reinforcing bars are sequentially installed from the ground side to the inside when the reinforcing bars are arranged, it is possible to prevent the waterproof sheet 2 from being damaged by the interference of the reinforcing bars and the like. Therefore, the waterproof performance is high, and the waterproofing is possible even when the water pressure of the natural ground is high.

  Further, since the spacer 30 can absorb the unevenness (unevenness) of the inner peripheral surface (surface of the waterproof sheet 2) of the tunnel by rotating the nut portion 42 and moving the screw rod 31 in the axial direction, the setup muscles can be absorbed. The position adjustment of 10 can be performed more accurately.

  Further, since the bar-shaped member 20 is bridged between the adjacent setup streaks 10 and 10, the interval between the adjacent setup streaks 10 and 10 can be kept constant. Further, since the setup streaks 10 and 10 are integrated through the plurality of rod-shaped members 20, the rigidity can be increased.

  Further, in the setup wire structure for tunnel 1, since steel support such as H-section steel is not used, it is not necessary to use a special machine such as an erector. Therefore, it is possible to assemble manually on a dolly or an aerial work vehicle.

  Although the embodiments for carrying out the present invention have been described above, the present invention is not intended to be limited to the above embodiments, and design changes can be appropriately made without departing from the spirit of the present invention. For example, in the above-described embodiment, the reinforcing steel for lining concrete is arranged in the tunnel in which the waterproof sheet 2 is laid, but the invention is not limited to this. Even in a tunnel in which a waterproof sheet is not laid, the method for installing the tunnel setup bar structure 1 and the lining concrete rebar can be applied.

1 Tunnel Setup Structure 2 Waterproof Sheet 3 Inverted Concrete 10 Setup Bar 11 Arc Rebar 12 Length Adjusting Member 20 Bar Member 30 Spacer 31 Screw Rod 41 Gripping Member 42 Nut Part 43 Gripping Part

Claims (5)

A setup bar structure for a tunnel for installing reinforcing bars to be reinforced in the lining concrete in the upper half of the tunnel,
Arranged between an arch-shaped setup streak extending along the waterproof sheet laid in the upper half of the inner surface of the tunnel, a spacer attached to the setup streak, and the setup streak adjacent to each other in the tunnel axial direction. A ground-side arched main rebar, a distribution force fixed to the setup bar and the ground-side arched main bar and extending in the tunnel axial direction, and an axial rebar attached to the tip of the spacer. An inner arched rebar fixed to the axial rebar ,
The end of the setup bar is fixed to the upper end of the inverted concrete in the lower half of the tunnel,
The setup bar includes a plurality of arc-shaped reinforcing bars and a length adjusting member that connects the arc-shaped reinforcing bars adjacent to each other in the tunnel circumferential direction,
The set-up bar structure for a tunnel, wherein the spacer extends along a thickness direction of the lining concrete, and an outer end portion of the spacer is in contact with the waterproof sheet. The spacer includes a screw rod and a gripping member that grips the setup muscle,
The setup member structure for a tunnel according to claim 1, wherein the grip member includes a nut portion that is screwed into the screw rod, and a grip portion that is rotatable relative to the nut portion. The setup muscles are arranged in parallel in the tunnel axial direction at intervals.
A rod-shaped member is bridged between the adjacent setup muscles. The setup muscle structure for tunnels according to claim 1 or 2, wherein. Inside the waterproof sheet laid in the upper half of the tunnel, a method of installing reinforcing steel for lining concrete, which comprises installing reinforcing bars to be reinforced in lining concrete,
A setup bar forming step of connecting a plurality of arc-shaped reinforcing bars with a length adjusting member to form an arch-shaped setup bar;
The setup bar fixing step of fixing the setup bar to the upper end of the inverted concrete in the lower half of the tunnel,
A spacer attaching step of attaching a spacer extending along the thickness direction of the lining concrete to the setup streak,
A setup streak position adjusting step of extending the length adjusting member to bring the tip end of the spacer into contact with the inner peripheral surface of the waterproof sheet;
The setup bar and the spacer include a reinforcing bar fixing step of fixing various reinforcing bars,
In the reinforcing bar fixing step, a ground side arch-shaped main reinforcing bar is arranged between the setup bars adjacent to each other in the tunnel axial direction, and a distribution force extending in the tunnel axial direction between the setup bar and the rock side arched main reinforcing bar. A method for installing a reinforcing bar for lining concrete , comprising fixing a reinforcing bar, attaching an axial reinforcing bar to a tip portion of the spacer, and fixing an inner arched reinforcing bar to the axial reinforcing bar. In the step of fixing the setup muscles, a plurality of the setup muscles are arranged in parallel at intervals in the tunnel axial direction, and a rod-like member is bridged between the adjacent setup muscles to adjust the distance between the setup muscles. The method for installing the reinforcing steel for lining concrete according to claim 4.

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