JP6584738B1 - How to build a tunnel support - Google Patents

Abstract

A tunnel support construction method provided along an inner wall surface of a tunnel, including a frame structure arrangement step (S125, S150) in which a frame structure (135) is arranged at a predetermined position, and along the inner wall surface of the tunnel. The base support construction process (S115, S120, S140, S145) for forming the base support construction (110, 120) on the base, and the shrinkable part by spraying the concrete material to the frame structure (135) arranged at a predetermined position A retractable part forming step (S140, S155) for forming (130), and the predetermined position is such that the frame structure (135) crosses the base support (110, 120) in the tunnel radial direction. It is the position to be placed.

Description

  The present invention relates to a method for constructing a tunnel support.

  Conventionally, when excavating a mountain tunnel using the NATM method, etc., the natural ground exposed by the tunnel excavation is supported by supporting works to stabilize the natural ground. There is a risk that a large pressure acts on the support work.

  In JP2018-40147A, a tunnel support is provided in which a shrinkable member made of a cement-based hardened body including a porous body is disposed in a slit formed in a part of the support work, and the deformation of the natural ground is absorbed by the shrinkable member. The work is disclosed.

  However, since the retractable member is heavy, it takes time to arrange the retractable member in the slit of the tunnel support work. For this reason, the tunnel support construction method described in JP2018-40147A has a problem that the work efficiency of tunnel support construction is poor.

  An object of this invention is to improve the work efficiency of construction of a tunnel support construction.

According to an aspect of the present invention, there is provided a method for constructing a tunnel support provided along an inner wall surface of a tunnel, the frame structure arranging step of arranging a frame structure at a predetermined position, and an inner wall surface of the tunnel. A base support forming process for forming a base support so as to follow, and a retractable part forming process for forming a contractible part by spraying a concrete material to the frame structure disposed at the predetermined position, wherein the predetermined position is the position der to frame structure is arranged so as to cross the base支保Engineering tunnel radially is, the frame structure is formed of a resin material.
Further, according to an aspect of the present invention, there is provided a tunnel support construction method provided along an inner wall surface of a tunnel, the framework structure arranging step of arranging the framework structure at a predetermined position, and the inside of the tunnel A base support work forming step for forming a base support work along the wall surface, and a retractable part forming step for forming a retractable part by spraying a concrete material onto the frame structure arranged at the predetermined position. And the predetermined position is a position where the frame structure is disposed so as to cross the base support in the tunnel radial direction, and the frame structure includes a plurality of base frame structures including a plurality of rod-shaped elements. Being done.

FIG. 1 is a longitudinal sectional view of a tunnel, showing a cross section taken along line II in FIGS. 2A and 2B. 2A is a cross-sectional view of the tunnel, showing a cross section taken along line IIA-IIA in FIG. 2B is a cross-sectional view of the tunnel, showing a cross section taken along line IIB-IIB in FIG. FIG. 3A is a diagram illustrating a frame structure including a base frame structure having a hexahedral shape (cuboid shape). FIG. 3B is a diagram showing a skeleton structure including a tetrahedral base skeleton structure. FIG. 4 is a diagram for explaining an example of the procedure of the tunnel support construction method according to the present embodiment. FIG. 5 is a diagram illustrating the stress-strain characteristics of the contractible portion according to the present embodiment. FIG. 6 is a diagram for explaining the support function of the tunnel support work according to the present embodiment. FIG. 7 is a diagram for explaining an example of the procedure of the tunnel support construction method according to the first modification of the present embodiment. FIG. 8 is a diagram illustrating a procedure for forming the first support structure according to the fourth modification of the present embodiment.

  With reference to the drawings, a tunnel support construction method according to an embodiment of the present invention will be described.

  First, with reference to FIG. 1, FIG. 2A, and FIG. 2B, the structure of the tunnel support construction 100 is demonstrated. As shown in FIG. 1, FIG. 2A and FIG. 2B, the tunnel support 100 is provided along the inner wall surface of a tunnel (excavation mine) excavated in the natural ground 1. The tunnel support 100 includes a steel support 110 made of a steel material and a concrete support 120 made of a concrete material. The steel support 110 is a first base support that is arranged at a predetermined interval in the tunnel axis direction. The concrete support 120 is a second base support that is formed by spraying a concrete material toward the inner wall surface of the tunnel (excavation mine), and between the steel support 110 arranged in the tunnel axial direction. It is formed.

  The tunnel support 100 includes a first retractable portion 131 formed so as to cross the steel support 110 in the tunnel radial direction and a second removable portion formed so as to cross the concrete support 120 in the tunnel radial direction. And a contraction unit 132.

  The steel support 110 is formed of, for example, an H-shaped steel. The steel support 110 has a pair of straight portions 111 extending linearly upward from the bottom surface of the tunnel, and a curved portion 112 bent into an arc shape. The bending portion 112 may be a single member or may be formed by combining a plurality of members.

  Both ends of the bending portion 112 are disposed at a predetermined interval from the upper ends of the pair of linear portions 111. Thereby, a slit (predetermined space) 119 is formed between the end portion of the bending portion 112 and the upper end portion of the linear portion 111. In the slit 119, a frame structure 135 to be described later is disposed, and a concrete material is sprayed on the frame structure 135, whereby the first retractable portion 131 is formed. By arranging the straight portion 111, the first retractable portion 131, and the curved portion 112 continuously in the tunnel circumferential direction, an arch-shaped first support structure 101 mainly made of a steel material is formed.

  The concrete support 120 may include a primary sprayed concrete 121 formed by spraying a concrete material on the inner wall surface of the tunnel, and a secondary sprayed concrete 122 sprayed on the primary sprayed concrete 121. Good. The shotcrete is finally formed to have a thickness of 0.1 m to 0.25 m.

  The secondary shotcrete 122 has a pair of straight portions 122a extending linearly upward from the bottom surface of the tunnel, and an arcuate curved portion 122b.

  Both ends of the curved portion 122b are formed at a predetermined interval from the upper ends of the pair of linear portions 122a. Thereby, a slit (predetermined space) 129 is formed between the end portion of the curved portion 122b and the upper end portion of the linear portion 122a. In the slit 129, a frame structure 135 to be described later is disposed, and a concrete material is sprayed onto the frame structure 135, whereby the second contractible portion 132 is formed. By forming the straight portion 122a, the second retractable portion 132, and the curved portion 122b continuously in the tunnel circumferential direction, an arch-shaped second support structure 102 mainly made of a concrete material is formed.

  In the present embodiment, the first retractable portion 131 and the second retractable portion 132 have the same configuration, and hence both will be collectively referred to as the retractable portion 130 below. The contractible portion 130 is formed by spraying a concrete material onto a frame structure 135 formed of a synthetic resin material, and curing the sprayed concrete material. The contractible portion 130 can be deformed larger than the steel support 110 and the concrete support 120 when a predetermined load is applied, and has a predetermined load resistance after the deformation converges. Therefore, it is preferable that the material of the frame structure 135 has a low strength against a load as compared with a steel material or a concrete material and is easily deformed.

  The contractible portion 130 has, for example, a width (tunnel axial length) of 0.1 m to 0.3 m, a thickness (tunnel radial length) of 0.1 m to 0.3 m, and a height of 0.2 to 0. .5m rectangular parallelepiped shape. The first retractable part 131 is formed in the slit 119 of the steel support member 110. For this reason, the width of the first retractable portion 131 is set to be substantially the same as the width of the steel support 110 or slightly longer than the width of the steel support 110. A plurality of second retractable portions 132 are disposed between the steel support members 110 along the tunnel axis direction. For this reason, the width | variety of the 2nd contraction part 132 can provide the 2nd contraction part 132 of the predetermined number (this embodiment 5 pieces) 2nd contraction part in the tunnel axial direction between the steel supporters 110. Is set as follows.

  With reference to FIG. 3A and FIG. 3B, the frame structure 135 which comprises the shrinkable part 130 is demonstrated. As shown in FIGS. 3A and 3B, the frame structure 135 (135A, 135B) has, for example, a width (tunnel axial length) of 0.1 m to 0.3 m and a thickness (tunnel radial length) of 0. It is formed in a rectangular parallelepiped shape with a height of 0.1 to 0.3 m and a height of 0.2 to 0.5 m. The width, thickness, and height of the frame structure 135 are not limited to be within the above numerical range, but are set to be within a weight that can be carried by one or two workers. Note that the framework structure 135 is formed of a resin material and can be easily reduced in weight, and thus the flexibility in setting the width, thickness, and height of the framework structure 135 is high.

  The frame structure 135 (135A, 135B) is formed by connecting a plurality of base frame structures 134 (134A, 134B) including a plurality of rod-shaped elements 133. Although various structures can be adopted for the frame structure 135, two types of frame structures 135 (135A and 135B) will be mainly described below.

  The base frame structure 134A constituting the frame structure 135A shown in FIG. 3A includes a plurality of linear rod-shaped elements 133 and is formed in a hexahedron shape (cuboid shape). A base frame structure 134B constituting the frame structure 135B shown in FIG. 3B includes a plurality of linear rod-shaped elements 133 and is formed in a tetrahedron shape (triangular pyramid shape).

  As shown in FIGS. 3A and 3B, the base frame structure 134 (134A, 134B) has a space in which a concrete material can be filled. That is, the space formed in the base frame structure 134 is set to a size that allows the aggregate contained in the sprayed concrete material to pass through.

  The frame structure 135 is formed so that the internal space of each base frame structure 134 communicates. Therefore, when the concrete material is sprayed from the outside of the frame structure 135, the concrete material reaches every corner of the frame structure 135. The framework structure 135 is formed by, for example, a 3D printer (three-dimensional modeling apparatus).

  The skeleton structure 135 is not limited to the example shown in FIGS. 3A and 3B, and can have various shapes formed by combining a plurality of rod-shaped elements 133. Further, the base frame structure 134 constituting the frame structure 135 is not limited to one type of shape. For example, the frame structure 135 may be formed by combining the base frame structure 134A illustrated in FIG. 3A and the base frame structure 134B illustrated in FIG. 3B. Therefore, the contractible portion 130 formed by filling the frame structure 135 with the concrete material can adjust the deformation performance by adjusting the shape, number, arrangement, and the like of the base frame structure 134 constituting the frame structure 135. Is possible.

  With reference to FIG. 4, the construction method of the tunnel support construction 100 is demonstrated. FIG. 4 is a diagram for explaining an example of the procedure of the method for constructing the tunnel support 100. The construction method of the tunnel support 100 includes an excavation process S110, a primary spraying process S115, a steel support construction forming process S120, a first frame structure placing process S125, a secondary spraying process S140, It includes an artificial concrete slit forming step S145, a second framework structure arranging step S150, and a second retractable portion forming step S155, and the steps S110 to S155 are repeatedly performed in this order for each predetermined length. . That is, the tunnel support 100 is formed by repeating the construction cycle having the steps S110 to S155. Hereinafter, an operation after at least one first support structure 101 has already been formed will be described.

<Drilling process>
In the excavation step S110, blast excavation for excavation is performed by crushing the natural ground 1 using explosives, and earth and sand generated by excavation are carried out of the tunnel. In excavation process S110, you may perform machine excavation which excavates natural ground 1 using a work machine. In the excavation step S110, the natural ground 1 is excavated for a predetermined length (for example, 1 to 3 m). Here, the predetermined length is a length from the tunnel end surface 1a in the vicinity of the existing first support structure 101 before excavation work to a position where the next first support structure 101 can be formed after excavation. That's it. That is, the predetermined length is a length corresponding to an installation interval of the first support structures 101 (a distance between the centers of two adjacent first support structures 101). In excavation step S110, when excavation of a predetermined length is completed, the process proceeds to primary spraying step S115.

<Primary spraying process>
In the primary spraying step S115, concrete material is sprayed onto the inner wall surface of a tunnel (excavation mine) of a predetermined length formed in the natural ground 1 by a concrete material spraying device (not shown). The primary sprayed concrete 121 is formed by hardening the sprayed concrete material. The primary shotcrete 121 is formed from the ceiling surface of the tunnel to both side surfaces, and is also formed on the tunnel end surface 1a. Mortar may be adopted as the concrete material. In the operation of spraying the concrete material, a rapid setting agent or fiber reinforcement may be used in order to accelerate the hardening or increasing the strength of the sprayed concrete material. If primary spray concrete 121 is formed in primary spraying process S115, it will progress to steel support construction forming process S120.

<Steel support formation process>
In the steel support construction forming step S120, a steel support 110 is formed in the vicinity of the tunnel end face 1a along the inner wall surface of the tunnel. That is, the steel support work forming step S120 is a first base support work forming process for forming the first base support work (steel support work 110). In the steel support construction forming step S120, after installing the pair of straight portions 111, the curved portion 112 is held by a support assembly device (not shown), whereby the end portion of the curved portion 112 and the upper end portion of the straight portion 111. A slit 119 is formed between the two. That is, the steel support work forming step S120 includes a steel support work slit forming process in which the steel support work 110 forms a slit 119 that traverses in the tunnel radial direction. When the slit 119 is formed between the pair of straight portions 111 and the curved portion 112 in the steel support forming step S120, the process proceeds to the first framework structure arranging step S125.

<First framework structure arrangement step>
In the first frame structure arrangement step S125, the frame structure 135 is arranged in the slit 119 of the steel support 110 formed in the steel support formation step S120. In the first frame structure arrangement step S125, when the arrangement of the frame structure 135 in the slit 119 is completed, the process proceeds to the secondary spraying step S140.

<Secondary spraying process>
In the secondary spraying step S140, the existing first support structure 101 formed in the previous construction cycle and the new steel support 110 formed in the steel support formation step S120 in the current construction cycle. In the meantime, it is laminated on the primary sprayed concrete 121 and sprayed with concrete material. Moreover, concrete material is sprayed on the frame structure 135 arrange | positioned in the slit 119 of the steel support 110. FIG.

  When the sprayed concrete material is hardened, the secondary shotcrete 122 is formed along the inner wall surface of the tunnel, and the first retractable portion 131 is formed in the slit 119 of the steel support 110. . The secondary shotcrete 122 is formed so as to be substantially flush with the steel support 110 or slightly depressed. By forming the first retractable portion 131 in the slit 119 of the steel support 110, the first support structure 101 is newly formed. As described above, the secondary spraying step S140 includes the first contractible part 131 that forms the first contractible part 131 by spraying the concrete material onto the frame structure 135 disposed in the slit 119 of the steel support 110. Forming step. If the secondary spray concrete 122 and the 1st support structure 101 are formed in secondary spraying process S140, it will progress to shotcrete slit formation process S145.

<Spring concrete slit forming process>
In the shotcrete slit forming step S145, a slit 129 that traverses in the tunnel radial direction is formed in the secondary shotcrete 122 formed in the secondary shot step S140. The slit 129 is formed so as to be adjacent to the slit 119 of the steel support 110 in the tunnel axis direction. Thereby, the concrete support 120 having the slit 129 is formed.

  The slit 129 may be formed by forming a secondary shotcrete 122 and then using a cutting machine (not shown), or a rectangular parallelepiped mold (not shown) at a position corresponding to the slit 129. The secondary shotcrete 122 may be formed after arranging the illustrated shape, and then the mold may be removed.

  Thus, the concrete support 120 is formed along the inner wall surface of the tunnel by performing the primary spraying step S115, the secondary spraying step S140, and the sprayed concrete slit forming step S145. That is, the second base support work forming process for forming the second base support work (concrete support work 120) includes the primary spraying process S115, the secondary spraying process S140, and the shot concrete slit forming process S145. And having. When the slit 129 is formed in the shotcrete slit forming step S145, the process proceeds to the second frame structure arranging step S150.

<Second frame structure arrangement step>
In the second frame structure arranging step S150, the frame structure 135 is arranged in the slit 129 of the secondary shotcrete 122 formed in the shotcrete slit forming step S145. In the present embodiment, five frame structures 135 are arranged for one slit 129. In the second skeleton structure arrangement step S150, when the arrangement of the skeleton structure 135 in the slit 129 is completed, the process proceeds to the second retractable portion forming step S155.

<Second retractable portion forming step>
In the second contractible portion forming step S155, a plurality of second contractible portions 132 are formed by spraying a concrete material onto the plurality of frame structures 135 disposed in the slits 129 of the secondary shotcrete 122. The second support structure 102 is formed by forming the plurality of second retractable portions 132 in the slit 129 of the secondary shotcrete 122.

  In the present step S155, the example in which the plurality of second contractible portions 132 are formed by spraying the concrete material onto the plurality of frame structures 135 disposed in the one slit 129 has been described. It is not limited to. The plurality of frame structures 135 may be connected by a concrete material. That is, in this step S155, the concrete material may be sprayed so that one second contractible portion 132 having a plurality of frame structures 135 is formed in one slit 129.

  After the second support structure 102 is formed, a plurality of lock bolts (not shown) are installed. The installation of the lock bolt is performed as follows, for example. First, a hole extending in the radial direction from the inner peripheral wall of the secondary shotcrete 122 is formed, and a filler is injected into the hole and a lock bolt (not shown) is inserted. For example, mortar is employed as the filler. The lock bolt may be inserted after the filler is injected into the hole, or may be inserted before the filler is injected into the hole. Moreover, you may perform the installation operation | work of a lock bolt, before the 2nd support structure 102 is formed. For example, the installation work of the lock bolt may be performed together with the installation work of the steel supporter 110. When the work in the second retractable part forming step S155 is completed, the process returns to the excavation process S110, and excavation is performed by a predetermined length in the tunnel axis direction.

  As described above, the tunnel support 100 (see FIG. 1) is formed along the tunnel axis direction by repeatedly performing the construction cycle including the steps S110 to S155 for each predetermined length. In addition, after a predetermined construction cycle is repeatedly performed, lining concrete (not shown) having a predetermined thickness is formed inside the steel support 110 and the concrete support 120 that constitute the tunnel support 100. .

  Here, the case where the retractable part 130 is formed in advance in a factory or the like, the retractable part 130 is transported to the work site, and installed in the slits 119 and 129 will be considered. Since the retractable part 130 having a concrete material is heavy, there is a problem that it takes time to carry it and place it in the slits 119 and 129, and the work efficiency of construction of the tunnel support 100 is poor.

  On the other hand, in the construction method of the tunnel support 100 according to the present embodiment, the framework structure arranging step (S125, S150) in which the lightweight framework structure 135 is arranged at a predetermined position as compared with the retractable portion 130 which is a completed body. And a retractable portion forming step (S140, S155) for forming the retractable portion 130 in the slits 119 and 129 by spraying a concrete material onto the frame structure 135 disposed at a predetermined position. Here, the predetermined position is a position where the frame structure 135 is arranged so as to cross the base support (steel support 110 and concrete support 120) in the tunnel radial direction. That is, in this embodiment, the predetermined position refers to a position in a predetermined space (slits 119, 129) that traverses the base support (steel support 110 and concrete support 120) in the tunnel radial direction.

  As described above, in this embodiment, the lightweight frame structure 135 is transported from the factory or the like to the work site, and the lightweight frame structure 135 is disposed in the slits 119 and 129. It can be improved. And since the contractible part 130 can be formed using the concrete material constructed on the inner wall surface of the tunnel, it is not necessary to transport a concrete material dedicated for forming the contractible part 130. Therefore, according to this embodiment, the work efficiency of the construction of the tunnel support 100 is improved.

  FIG. 5 is a diagram illustrating the stress-strain characteristics of the retractable portion 130 according to the present embodiment. The horizontal axis represents strain, and the vertical axis represents stress. In FIG. 5, the stress-strain characteristic of the contractible portion 130 according to the present embodiment is indicated by a solid line, and the stress-strain characteristic of a shotcrete block that does not have the frame structure 135 is indicated by a one-dot chain line.

  In a high earth covered tunnel or an expansive ground, a large pressure may act on the tunnel support 100 toward the inside of the tunnel. As shown in FIG. 5, a shotcrete block that does not have the frame structure 135 is deformed by the application of a predetermined pressure. The strain increases as the stress acting on the shotcrete block increases, and cracks occur at the strain εu at which the stress reaches its maximum value.

  Similarly, the strain of the retractable portion 130 according to the present embodiment increases as the stress acting on the retractable portion 130 increases, but the slope of the curve is smaller than that of the shotcrete block. That is, the contractible portion 130 has a characteristic that can be largely deformed compared to a shotcrete block that does not have the frame structure 135. For example, the strain ε1 of the contractible portion 130 at the predetermined stress σ0 is larger than the strain ε0 of the shotcrete block at the predetermined stress σ0 (ε1> ε0). For this reason, when a big pressure acts on the tunnel support work 100, the contraction | shrink part 130 will shrink | contract greatly to a tunnel circumferential direction (illustrated up-down direction). For this reason, the tunnel support 100 is deformed following the deformation of the natural ground 1.

  Thus, in this embodiment, in the base support work (steel support work 110 and concrete support work 120), the contractible part which can be contracted following the deformation of the natural ground 1 so as to cross the tunnel radial direction. 130 is provided. Thereby, since deformation of the natural ground 1 is allowed to some extent, the pressure (ground pressure) of the natural ground 1 is relieved. And the tunnel support work 100 supports the natural ground 1 firmly, after permitting a certain amount of deformation.

  The effect by providing the contractible part 130 according to the present embodiment will be described in comparison with a comparative example of the present embodiment. In the comparative example of the present embodiment, the contractible portion 130 and the slits 119 and 129 are not provided. That is, the 1st support structure which concerns on the comparative example of this embodiment is comprised by the steel support work which does not have the slit 119, and the 2nd support structure is comprised by the concrete support work which does not have the slit 129. Has been.

  FIG. 6 is a diagram illustrating the support function of the tunnel support 100 according to the present embodiment. FIG. 6 illustrates the support characteristic N1 of the tunnel support 100 according to the present embodiment, the support characteristic N0 of the tunnel support according to the comparative example of the present embodiment, and the ground characteristics GL and GH of the natural ground 1. Yes.

  The natural ground 1 with the natural ground characteristic GH has a higher earth covering height than the natural ground 1 with the natural ground characteristic GL. As shown in the figure, the natural ground 1 has a characteristic that the earth pressure increases as the earth covering height increases, and the earth pressure decreases as the displacement increases. Further, as shown in the figure, in the tunnel support, the stress acting on the tunnel support increases as the displacement increases.

  The support state of the natural ground 1 of the natural ground characteristic GL by the tunnel support 100 according to the present embodiment is represented by the intersection PL1 of the curve representing the natural support characteristic N1 and the curve representing the natural ground characteristic GL. The support state of the natural ground 1 of the natural ground characteristic GH by the tunnel support 100 according to the present embodiment is represented by the intersection PH1 of the curve representing the natural support characteristic N1 and the curve representing the natural ground characteristic GH. The support state of the natural ground 1 of the natural ground characteristic GL by the tunnel support according to the comparative example of the present embodiment is represented by the intersection PL0 of the curve representing the natural support characteristic N0 and the curve representing the natural ground characteristic GL.

  As can be seen from the intersections PL0 and PL1, the tunnel support according to the comparative example of the present embodiment does not include the retractable portion 130, and therefore, the deformation of the natural ground 1 with respect to the natural ground 1 of the natural ground characteristic GL It is possible to suppress and support the natural ground 1 in a high ground pressure state as compared with the present embodiment. However, there is no intersection between the curve representing the support characteristic N0 and the curve representing the natural ground characteristic GH. This indicates that the tunnel support according to the comparative example of the present embodiment cannot withstand the ground pressure of the natural ground 1 having the natural ground characteristic GH. That is, the tunnel support according to the comparative example of the present embodiment cannot be used for the natural ground 1 having the natural ground characteristic GH.

  On the other hand, in the tunnel support 100 according to the present embodiment, as can be seen from the intersections PL0 and PL1, the contractible portion 130 contracts to effectively reduce the ground pressure, which is lower than the comparative example. It is possible to support the natural ground 1 that has been in a pressurized state. Furthermore, in this embodiment, since the deformation of the natural ground 1 is greatly permitted as compared with the comparative example, it is possible to support the natural ground characteristic GH having a high earth covering height (see the intersection PH1). Therefore, the tunnel support 100 according to the present embodiment can cope with a wide range of ground characteristics.

  According to embodiment mentioned above, there exists the following effect.

  In the construction method of the tunnel support 100 according to the present embodiment, a lightweight frame structure 135 formed of a resin material is disposed at a predetermined position of the base support (steel support 110 and concrete support 120). Then, the contractible portion 130 is formed by spraying a concrete material onto the frame structure 135. Here, the predetermined position is a position where the frame structure 135 is arranged so as to cross the base support (steel support 110 and concrete support 120) in the tunnel radial direction. That is, in this embodiment, it is not necessary for the worker to lift the retractable portion 130, which is a heavy object, and place it in a predetermined position. The worker can form the retractable portion 130 at the position where the frame structure 135 is arranged by spraying the concrete material after placing the lightweight frame structure 135 at a predetermined position. Therefore, according to this embodiment, the work efficiency of the construction of the tunnel support 100 is improved.

  The following modifications are also within the scope of the present invention, and it is possible to combine the structure shown in the modification and the structure described in the above embodiment, or to combine the structures described in the following different modifications. It is.

<Modification 1>
The procedure of the construction method of the tunnel support 100 is not limited to the procedure described in the above embodiment (see FIG. 4). For example, the tunnel support 100 may be constructed according to the procedure shown in FIG. In the first modification, steps S230 and S240 are performed instead of steps S140, S145, S150, and S155 shown in FIG. As shown in FIG. 7, in the construction method of the tunnel support 100 according to the first modification, in the first frame structure placement step S125, the frame structure 135 (hereinafter referred to as the first frame structure 135S) in the slit 119 is used. When the arrangement of (also referred to as) is completed, the process proceeds to the second frame structure arrangement step S230.

<Second frame structure arrangement step>
In the second frame structure arrangement step S230, the new steel support 110 installed in the steel support formation step S120 in the current construction cycle from the existing first support structure 101 formed in the previous construction cycle. A plurality of frame structures 135 (hereinafter also referred to as second frame structures 135C) are arranged along the tunnel axis direction.

  The second frame structure 135C is arranged in advance at a predetermined position so as to cross the secondary spray concrete 122 formed in the secondary spraying step S240 in the subsequent process in the tunnel radial direction. The second frame structure 135C may be held at a predetermined position by a holding device (not shown) having a holding tool, or may be held at a predetermined position by a holding structure (not shown) temporarily installed in the tunnel. . Further, the second frame structure 135C may be held at a predetermined position by connecting one side surface of the second frame structure 135C to the primary shotcrete 121. In the second frame structure arrangement step S230, when the arrangement of the second frame structure 135C is completed, the process proceeds to the secondary spraying step S240.

<Secondary spraying process>
In the secondary spraying step S240, the existing first support structure 101 formed in the previous construction cycle and the new steel support 110 formed in the steel support formation step S120 in the current construction cycle. In the meantime, it is laminated on the primary sprayed concrete 121 and sprayed with concrete material. Further, the concrete material is sprayed onto the second frame structure 135 </ b> C held at a predetermined position between the existing first support structure 101 and the new steel support 110. Further, the concrete material is sprayed onto the first frame structure 135S disposed in the slit 119 of the steel support 110.

  When the sprayed concrete material is hardened, the secondary spray concrete 122 is formed along the inner wall surface of the tunnel, and the second retractable portion 132 is formed at a predetermined position. As a result, a second support structure 102 is newly formed. In addition, a first retractable portion 131 is formed in the slit 119 of the steel support 110. As a result, the first support structure 101 is newly formed.

  In addition, in this process S240, the example which forms the some 2nd contractible part 132 and the 1st 1st contractible part 131 by spraying concrete material to the some frame structure 135 currently hold | maintained in the predetermined position is demonstrated. However, the present invention is not limited to this. The plurality of frame structures 135 may be connected by a concrete material. That is, in this process S240, the one shrinkable part which has the some frame structure 135 arrange | positioned so that the concrete support 120 may be crossed, and the frame structure 135 arrange | positioned so that the steel support 110 may be crossed The concrete material may be sprayed so that 130 is formed.

  As described above, the secondary spraying step S240, which is one step of the concrete support forming step according to the first modification, is performed with the concrete material toward the inner wall surface of the tunnel and the second frame structure 135C disposed at a predetermined position. The 2nd contractible part formation process which forms the 2nd contractable part 132 with the concrete support work 120 by spraying is included. Further, in the secondary spraying step S240, the first retractable part is formed by spraying the concrete material onto the first frame structure 135S disposed in the slit 119 of the steel support 110. Forming step.

  According to such a modification, the base support (concrete support 120) and the second retractable portion 132 can be formed in one step (secondary spraying step S240). Furthermore, the base support (concrete support 120) and the first retractable part 131 can be formed in one step (secondary spraying step S240). For this reason, the work efficiency of construction of the tunnel support construction 100 can be further improved.

<Modification 2>
Although the said embodiment demonstrated the example which arrange | positions the frame structure 135 in the slit 119 after forming the slit 119 of the steel support 110, this invention is not limited to this. A steel support 110 is formed to perform a frame structure placement step of placing the frame structure 135 at a predetermined position, and then to form a steel support 110 adjacent to the frame structure 135 arranged at the predetermined position in the circumferential direction of the tunnel. You may make it perform an engineering formation process.

<Modification 3>
In the above embodiment, the example in which the concrete material used for the secondary shotcrete 122 is the same as the concrete material used for the retractable portion 130 has been described, but the present invention is not limited to this. The concrete material used for the secondary shotcrete 122 may be different from the concrete material used for the retractable portion 130. For example, the frame structure 135 is disposed at a predetermined position, and then the secondary shotcrete 122 is formed using the first concrete material so as to be adjacent to the frame structure 135 disposed at the predetermined position in the circumferential direction of the tunnel. In addition, after that, the second contractible portion 132 may be formed by spraying the second concrete material onto the frame structure 135. In other words, the deformation performance of the second retractable portion 132 may be adjusted by forming the second retractable portion 132 with a dedicated concrete material.

<Modification 4>
As shown in FIG. 8, a guide portion 117 that guides the end portion of the bending portion 112 when the retractable portion 130 contracts may be provided around the retractable portion 130 of the first support structure 101. The guide part 117 can be formed by excising one side of a rectangular short tube, for example.

  FIG. 8 is a diagram illustrating a procedure for forming the first support structure 101. First, in step S41, the pair of straight portions 111 are installed on the bottom surface of the tunnel, and the process proceeds to step S42. In step S42, the rectangular flat plate material 116 is fixed to the upper end of the straight portion 111, and the process proceeds to step S43. In step S43, the lower end portion of the guide portion 117 is put on the upper end portion of the straight portion 111, the lower end portion of the guide portion 117 is fixed to the straight portion 111, and the process proceeds to step S44.

  In step S44, the skeleton structure 135 is inserted inside the guide portion 117, placed on the plate member 116, and the process proceeds to step S45. In step S <b> 45, the end portion of the bending portion 112 is inserted into the upper end portion of the guide portion 117. In the present modification, the end of the curved portion 112 is formed in a straight line, and a rectangular flat plate material 116 is fixed in advance.

  The bending portion 112 is held by a support assembly device (not shown). In this state, the concrete material is sprayed onto the frame structure 135 through the side opening of the guide portion 117. When the concrete material is hardened, a rectangular parallelepiped contractible portion 130 is formed, and an arch-shaped first support structure 101 in which the straight portion 111, the retractable portion 130, and the curved portion 112 are continuous is formed. .

  According to such a modification, when a large earth pressure acts on the first support structure 101 from the natural ground 1, the contractible portion 130 contracts and the end portion of the curved portion 112 extends in the longitudinal direction of the guide portion 117. Slide down along. Thereby, according to the deformation | transformation of the natural ground 1, the curved part 112 can be moved appropriately.

<Modification 5>
Although the said embodiment demonstrated the example which forms the concrete support 120 with the primary shotcrete 121 and the secondary shotcrete 122, this invention is not limited to this. Further, a concrete support may be formed by spraying a concrete material with three or more concrete layers. Moreover, you may form the concrete support 120 by a single concrete layer, without dividing into a plurality of concrete layers. For example, in the above embodiment, the concrete material spraying step S115 (see FIG. 4) may be omitted.

<Modification 6>
Although the said embodiment demonstrated the example which provides the shrinkable part 130 which sprays concrete material to the resin-made frame structure 135 in each of the steel support work 110 and the concrete support work 120, this invention is limited to this. Not. The concrete support 120 may be provided with the retractable portion 130, and the steel support 110 may not be provided with the retractable portion 130. In this case, the steel support 110 is provided with a known retractable support in place of the retractable portion 130. The contractible support work is configured by, for example, a plurality of steel materials having a U-shaped cross section, and end portions of adjacent steel materials are overlapped with each other by a predetermined length so as to be slidable with a U bolt or the like.

<Modification 7>
In the embodiment described above, the framework structure 135 is disposed in the slit 119 of the steel support 110, and then the contractible portion 130 is formed by spraying the concrete material, and the framework structure is formed in the slit 129 of the concrete support 120. Although the example which forms the contractible part 130 by spraying concrete material after arrange | positioning 135 was demonstrated, this invention is not limited to this. In any one of the slit 119 of the steel support 110 and the slit 129 of the concrete support 120, the contractible portion 130 formed in advance in a factory or the like may be arranged. In other words, the retractable portion 130 may be formed by spraying concrete material after disposing the frame structure 135 in at least one of the slit 119 of the steel support 110 and the slit 129 of the concrete support 120. Even in such a case, the work efficiency of the construction of the tunnel support 100 is improved as compared with the case where the retractable portion 130 formed in advance in a factory or the like is arranged for both the slits 119 and 129. be able to.

<Modification 8>
In the above embodiment, the example in which the cross section of the tunnel support 100 is arched has been described, but the present invention is not limited to this. The present invention can also be applied to the case where the cross section of the tunnel support 100 is circular. Further, the number of the contractible units 130 is not limited to the above embodiment. For example, three or more retractable portions 130 may be provided at predetermined intervals in the circumferential direction of the tunnel within a predetermined cross section of the tunnel support 100, or one retractable portion 130 is provided. You may do it.

<Modification 9>
In the above embodiment, an example in which the framework structure 135 is formed of a resin material has been described, but the present invention is not limited to this.

  The embodiment of the present invention has been described above. However, the above embodiment only shows a part of application examples of the present invention, and the technical scope of the present invention is limited to the specific configuration of the above embodiment. Absent.

Claims (7)

A tunnel support construction method provided along an inner wall surface of a tunnel,
A frame structure arrangement step of arranging the frame structure in a predetermined position;
A base support work forming step for forming a base support work along the inner wall surface of the tunnel;
A retractable portion forming step of forming a retractable portion by spraying a concrete material onto the frame structure disposed at the predetermined position, and
Wherein the predetermined position is Ri position der to said frame structure is arranged so as to cross the base支保Engineering tunnel radially,
The framework structure is formed of a resin material;
How to build a tunnel support.   A tunnel support construction method provided along an inner wall surface of a tunnel,
  A frame structure arrangement step of arranging the frame structure in a predetermined position;
  A base support work forming step for forming a base support work along the inner wall surface of the tunnel;
  A retractable portion forming step of forming a retractable portion by spraying a concrete material onto the frame structure disposed at the predetermined position, and
  The predetermined position is a position where the frame structure is arranged so as to cross the base support in the tunnel radial direction,
  The frame structure is formed by combining a plurality of base frame structures including a plurality of rod-shaped elements.
  How to build a tunnel support. A construction method of a tunnel support according to claim 1 or 2 ,
In the base support work forming step, in the base support work, a slit that traverses in the tunnel radial direction is formed,
In the frame structure arrangement step, the frame structure is arranged in the slit of the base support formed in the base support formation step,
In the shrinkable part forming step, the shrinkable part is formed by spraying a concrete material onto the frame structure disposed in the slit of the base support work.
How to build a tunnel support. A construction method of a tunnel support according to claim 1 or 2 ,
In the base support work forming step, the base support work is formed so as to be adjacent to the framework structure disposed at the predetermined position.
How to build a tunnel support. A construction method of a tunnel support according to claim 1 or 2 ,
The base support includes a steel support disposed at a predetermined interval in the tunnel axial direction.
How to build a tunnel support. A construction method of a tunnel support according to claim 1 or 2 ,
The base support work includes a concrete support work in which a concrete material is sprayed toward the inner wall surface of the tunnel.
How to build a tunnel support. A tunnel support construction method according to claim 6 ,
The base support work forming step includes the shrinkable part forming step, and sprays a concrete material toward the inner wall surface of the tunnel and the frame structure disposed at the predetermined position, thereby the base support work and the base support work. Forming a shrinkable part,
How to build a tunnel support.

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