JP2016118040A - Tunnel support structure and steel supporting - Google Patents

Abstract

The present invention proposes a tunnel support structure and a steel support structure excellent in workability and economy. A tunnel support structure 1 includes a steel support 2, a lock bolt 3, and shotcrete 4. The steel support 2 has a leg portion on the face side of the tunnel or on the wellhead side. A bolt fixing portion 5 fixed so as to project outward is formed, and the head of the lock bolt 3 is fixed to the bolt fixing portion 5 with the shaft portion passing through the bolt fixing portion 5. [Selection] Figure 3

Description

  The present invention relates to a tunnel support structure and a steel support structure.

In mountain tunnels such as the NATM tunnel, the natural ground exposed by tunnel excavation is blocked early by supporting works to stabilize the natural ground.
In general tunnel support works, shotcrete and steel support works are used.

In tunnel construction on soft ground, stress due to earth pressure or the like concentrates on the steel support leg (hereinafter referred to as “support leg”), and the support leg may sink. When the support leg sinks, the tunnel will be displaced.
For this reason, many measures for preventing settlement of the support leg have been developed.

For example, in Patent Document 1, a cone-shaped member is fixed to a leg portion (base end portion) of a steel support, and after the steel support is built, shotcrete is filled into the cone-shaped member. Thus, a reinforcing structure for increasing the ground contact area of the support leg is disclosed.
Patent Document 2 discloses a reinforcing structure in which a base plate having an area larger than a base end surface of a steel support is installed under the steel support.

Japanese Patent Laid-Open No. 07-097899 JP 2012-112104 A

Since the conventional reinforcing structure needs to increase the amount of extra digging at the support leg, it takes time for construction.
Moreover, since the reinforcement structure of patent document 1 increases the placement amount (spraying amount) of shotcrete, it takes time and effort, and construction cost also increases.
Furthermore, in the reinforcement structure of patent document 2, it is necessary to remove the base plate which is a temporary member, and this removal work takes time.

  From such a viewpoint, an object of the present invention is to propose a tunnel support structure and a steel support structure that are superior in workability and economically as compared with a conventional reinforcing structure.

In order to solve the above problems, the tunnel support structure of the present invention includes a steel support and a lock bolt, and the steel support is provided with a bolt fixing portion. The head is fixed to the bolt fixing portion.
The bolt fixing portion may be formed by fixing a steel plate in which a through hole is formed to a leg portion of a steel support so as to project toward the face of the tunnel or the wellhead side.

According to the tunnel support structure of the present invention, since the lock bolt is fixed to the steel support, the steel support can be prevented from sinking due to the shearing force acting on the lock bolt.
Moreover, since the lock bolt used as one of the usual support works is utilized, a new construction equipment is not required and the amount of surplus digging does not increase. Therefore, it is excellent in workability and economy.

Further, the steel supporter of the present invention is characterized in that the steel plate in which the through hole is formed is fixed to the leg portion so as to protrude toward the face of the tunnel or toward the wellhead.
According to such a steel support, the sinking of the support leg can be suppressed by driving the lock bolt so as to be inserted through the through hole of the steel plate.

  According to the tunnel support structure and the steel support structure of the present invention, it is possible to construct a tunnel displacement control structure excellent in workability and economy.

It is a cross-sectional view which shows the tunnel support structure of embodiment of this invention. It is a perspective view which shows the steel support construction of the tunnel support structure. It is a partial expansion perspective view which shows the detail of a tunnel support structure.

  Embodiment of this invention demonstrates the tunnel support structure 1 formed in order to close the ground ground exposed by excavating the tunnel T at an early stage (refer FIG. 1). This embodiment demonstrates the case where the tunnel support structure 1 is employ | adopted for the upper half part of a tunnel.

As shown in FIG. 1, the tunnel support structure 1 includes a steel support 2, a lock bolt 3, and shotcrete 4.
The tunnel support structure 1 may be appropriately set according to the support pattern according to the natural ground conditions, but an auxiliary method such as a pre-receiving method may be added as necessary.

The steel supporter 2 is a steel material built along the natural ground surface, and is assembled in an arch shape in the tunnel mine.
As shown in FIG. 2A, the steel support 2 includes a main body portion 21 processed in an arc shape according to a cross-sectional shape of the tunnel T, and attachment portions 22 and 22 fixed to both ends of the main body portion 21. It has.

The main body 21 is made of H-section steel. The dimensions and shape of the main body 21 are appropriately set according to the support pattern, the planned cross section of the tunnel, and the like.
The attachment portion 22 is made of a steel plate having a larger area than the outer shape of the main body portion 21. A bolt hole 23 is formed in the mounting portion 22 for connection to another steel support 2.

A bolt fixing portion 5 is fixed to the leg portion of the steel support 2.
The bolt fixing portion 5 is made of a steel plate. As shown in FIG. 2B, one end portion of the bolt fixing portion 5 is overlapped with the flange of the main body portion 21, and the other portion projects from the flange of the main body portion 21.

  In this embodiment, the bolt fixing portion 5 is fixed to the leg portion of the steel support 2 so as to protrude toward the tunnel entrance, but the bolt fixing portion 5 is extended toward the face of the tunnel. Also good.

  The bolt fixing portion 5 is fixed to the flange with bolts 6 and nuts that pass through the flanges of the bolt fixing portion 5 and the main body portion 21 in a state where the bolt fixing portion 5 is overlapped with the surface on the inner space side of the flange. In addition, the fixing method of the bolt fixing | fixed part 5 is not limited, For example, you may weld to a flange. Moreover, you may fix the bolt fixing | fixed part 5 in the state piled up on the surface of the natural ground side of a flange. Moreover, the number and arrangement | positioning of the volt | bolt 6 for fixing the volt | bolt fixing | fixed part 5 are not limited.

  A through-hole 51 through which the lock bolt 3 (see FIG. 3) can be inserted is formed in a portion of the bolt fixing portion 5 protruding from the steel support 2 (flange). In the present embodiment, the through hole 51 is circular, but the shape of the through hole 51 is not limited. The size of the through hole 51 is not limited as long as the shaft portion 32 of the lock bolt 3 can be inserted and the head 33 of the lock bolt 3 can be locked to the opening edge of the through hole 51.

As shown in FIG. 1, a plurality of lock bolts 3 are provided in the circumferential direction of the tunnel T. The installation interval, member dimensions, and the like of the lock bolt 3 are set by a support pattern according to the natural ground condition.
In the present embodiment, as shown in FIG. 3, in addition to the pattern lock bolt 30 determined by the support pattern, a leg reinforcement lock bolt 31 is provided.

The leg reinforcing lock bolt 31 is fixed to the bolt fixing portion 5.
The shaft portion 32 of the leg portion reinforcing lock bolt 31 is inserted into the through hole 51 of the bolt fixing portion 5 and the hole formed in the ground, and the head portion 33 of the leg portion reinforcing lock bolt 31 is the bolt fixing portion. 5 is fixed (locked) to the inner space side surface.

  In the present embodiment, a material having the same specifications as the pattern lock bolt 30 is used as the leg portion reinforcing lock bolt 31. In addition, the specification of the lock bolt 31 for leg part reinforcement does not need to be the same as the pattern lock bolt 30, For example, a dimension smaller than the pattern lock bolt 30 may be sufficient.

As shown in FIG. 3, the shotcrete 4 is sprayed on the ground exposed by tunnel excavation.
What is necessary is just to set the thickness etc. of shotcrete 4 according to a support pattern. Moreover, you may abbreviate | shoot shotcrete 4 depending on a natural ground condition.

Construction of the tunnel support structure 1 is performed for each excavation cycle.
That is, when a predetermined extension (for example, 1 m) is dug, the steel support 2 is assembled and the shot concrete 4 is sprayed to install the lock bolt 3.

The steel support 2 is connected to the existing steel support 2 via a horizontal connecting material (not shown).
In addition, after assembling the steel support 2, the spray concrete 4 may be applied to the exposed surface of the natural ground around the steel support 2, or the primary spray before the steel support 2 is assembled. After performing, after assembling the steel support 2, the remaining spraying (secondary spraying) may be performed to construct the shotcrete 4.

After the shotcrete 4 is constructed, the ground is drilled and the pattern lock bolt 30 is installed.
The shaft portion 32 of the pattern lock bolt 30 is inserted into a hole formed by drilling a natural ground together with the solidified material, and the head of the pattern lock bolt 30 is fixed to the surface of the shotcrete 4.

Further, along with the construction of the pattern lock bolt 30, the leg portion reinforcing lock bolt 31 is installed.
The lock bolt 31 for reinforcing the leg portion is installed by drilling a natural ground with a drill through which the through hole 51 of the bolt fixing portion 5 is inserted. The leg reinforcing lock bolt 31 is inserted into the through hole 51 of the bolt fixing portion 5 and the shaft portion 33 is inserted into the hole drilled together with the solidifying material, and the head portion 33 is fixed to the bolt fixing portion 5.

  According to the tunnel support structure 1 of the present embodiment, since the leg reinforcement lock bolt 31 is fixed to the leg portion of the steel support work 2, the shear force acting on the leg reinforcement lock bolt 31 causes the steel to Sinking of the support work 2 can be prevented.

  Since the leg reinforcing lock bolt 31 uses the lock bolt 3 having the same dimensions as the pattern lock bolt 30, no new construction equipment is required and the amount of surplus digging does not increase. That is, the tunnel support structure 1 is more economical than the conventional reinforcement structure of the support legs.

Moreover, according to the tunnel support structure 1, since the setup change etc. at the time of reinforcing the leg part of the steel support work 2 are not required, it can be constructed easily and quickly.
Moreover, since the fixing | fixed part of the lock volt | bolt 3 is a structure which only fixes the steel plate in which the through-hole 51 was formed to the steel supporter 2, it can form easily and is cheap.

Here, the settlement suppression effect when a lock bolt having a tensile strength of 290 kN is used for the leg reinforcement lock bolt 31 will be examined.
The shear strength of the lock bolt 3 having a tensile strength of 290 kN is 167.4 kN (= tensile strength / √3 = 290 / √3) according to the theory of von Mises.

  On the other hand, the settlement suppression force of the reinforcing structure using the conventional cone-shaped member (inner diameter: 670 mm) is 105.6 kN as shown below when the bedrock at the installation location is soft rock. According to the tunnel support structure 1, the settlement of the steel support work 2 can be suppressed.

Cone-shaped member bottom area = 0.335 × 0.335 × π≈0.352 m ²
Allowable bearing capacity of bedrock (soft rock) = 300kN / m ²
(Japan Society of Civil Engineers, "Auxiliary Construction Method for Mountain Tunnels-2009 Edition", p. 100)
Settlement inhibition force = 300 × 0.352 = 105.6 kN

Although the embodiment of the present invention has been described above, the present invention is not limited to the above-described embodiment, and the above-described components can be appropriately changed without departing from the spirit of the present invention.
In the above-described embodiment, the case where the tunnel support structure of the present embodiment is employed when constructing the upper half of the tunnel T has been described. However, the tunnel excavation method to which the tunnel support structure of the present invention can be applied is limited. Instead, for example, it may be used for full-section excavation.

In the above-described embodiment, the case where one bolt fixing portion 5 is formed on one leg portion of the steel support 2 has been described, but a plurality of bolt fixing portions 5 are formed on one leg portion. May be. For example, the two bolt fixing portions 5 may be protruded toward the face side and the wellhead side of the tunnel of the steel support for each leg portion. Moreover, you may form the bolt fixing | fixed part 5 of several steps up and down with respect to one leg part.
The configuration of the bolt fixing portion 5 is not limited, and may be formed by a jig or the like that is gripped by the head 32 of the lock bolt 3.

  In the said embodiment, although the bolt fixing | fixed part 5 shall be formed in the leg part of the steel supporter 2, the formation location of the bolt fixing part 5 is not limited to the leg part of the steel supporter 2. For example, the bolt fixing portion 5 may be formed on the top end or shoulder portion of the steel support 2 and the lock bolt 3 may be fixed to the bolt fixing portion 5. By doing so, the displacement of the steel support 2 (inside the tunnel) may be suppressed by the sewing effect of the lock bolt 3 and the natural ground and the pull-out strength of the lock bolt 3.

Further, in the embodiment, the leg portion reinforcing lock bolt 31 is driven separately from the pattern lock bolt 30. However, a part of the pattern lock bolt 30 is fixed to the bolt fixing portion 5 so as to reinforce the leg portion. The lock bolt 31 may be used.
In addition, the pattern lock bolt 30 may be omitted when an auxiliary method such as a pre-receiving method, an AGF method, or a pipe roof method is applied.

DESCRIPTION OF SYMBOLS 1 Tunnel support structure 2 Steel support 3 Lock bolt 30 Pattern lock bolt 31 Lock bolt for leg reinforcement 32 Head 4 Shotcrete 5 Bolt fixing part 51 Through-hole

Claims (4)

A tunnel support structure comprising a steel support and a lock bolt,
The steel support is formed with a bolt fixing part,
A tunnel support structure, wherein a head of the lock bolt is fixed to the bolt fixing portion.   The tunnel support structure according to claim 1, wherein the bolt fixing portion is formed on a leg portion of the steel support. The bolt fixing part is a steel plate fixed to the steel support so as to project toward the face side or the wellhead side of the tunnel,
The tunnel support structure according to claim 1, wherein a through hole is formed in the steel plate.   A steel support, wherein a steel plate having a through hole is fixed to a leg portion so as to project toward a face of a tunnel or a pit side.

Images