JPH01299999A - On-site concrete lining construction method - Google Patents

Abstract

PURPOSE:To make shielded concrete bear the propulsion reaction force of a shield drilling machine via an inner mold frame through the monolithic construction of the frame and the concrete, and enable the reduction of inner mold frame length. CONSTITUTION:A shear connector A comprising comprising a mounting plate 2 studded with a bolt 3 and a long nut 4 is fitted to the internal surface of an inner mold frame in such a way that another bolt 5 inserted from the opposite surface of an inner mold frame B is screwed to the aforesaid long nut 4. When concrete is filled in an annular space between the tail plate 6 of a shield drilling machine and the inner mold frame B, this inner mold frame B and the concrete are integrated due to the curing of the concrete. The shield drilling machine is propelled to an existing shielded concrete part C on a reaction force on the integrated inner mold frame B via the shear connector A.

Description

DETAILED DESCRIPTION OF THE INVENTION (Field of Industrial Application) The present invention relates to a cast-in-place concrete lining method applied to a tunnel construction method.

(Conventional technology) Conventionally, this type of cast-in-place concrete lining construction method
It went like this:

(1) Existing concrete lining inside the tunnel hole excavated by a shield excavator) Reinforcing bars (b) are placed in the concrete lining in front of (a), and steel inner formwork (C) is installed. , and connect the valve and concrete supply pipe (5) to the concrete supply port (f) attached to the press ring plate (e) of the inner formwork or concrete press-fitting jack (d). (Fig. 4) (Reference) (ii) Extend the concrete press-fitting jack mounted on the shield excavator to the end side of the annular space 0) formed between the tail plate (i) and the inner formwork, and Set the temporary press ring.

(iii) Next, the pulp connected to the concrete supply port of the inner formwork or the press ring plate of the concrete press-fitting jack is opened to supply concrete (k) into the annular space. (See Figure 4B) CI ■) After the supply of concrete into the annular space is completed, the valve is closed, and the tail plate moving jack (+1) mounted on the shield excavator is moved back and the tail plate (i ) is moved forward, and at the same time as the tail plate is moved forward, the concrete press-fitting jack is extended, and the press ring of the concrete press-fitting jack is used to pressurize and fill the void created by the movement of the tail plate with concrete. (Refer to Figure 4C) (v) After the strength of the pressurized concrete has been developed, remove the concrete supply pipe, move back the concrete press-fitting jack, and remove the press ring plate of the concrete press-fitting jack. Thereafter, the shield excavator resumes excavation while extending the propulsion jack mounted on the shield excavator using the inner formwork as a reaction force. (See Figure 4D) (vi) After the required excavation by the shield excavator is completed, the tunnel is constructed by lining the inside of the tunnel hole with concrete while repeating the above (i) to (v).

(Problems to be Solved by the Invention) However, this type of construction method has the following problems.

(1) The shield excavator was propelled by a method in which a propulsion jack mounted on the shield excavator was set in the inner formwork, and the propulsion jack was extended using the inner formwork as a reaction force.

However, the method of applying reaction force to the inner formwork uses the frictional force between the inner formwork and the existing lining concrete to transmit the propulsive reaction force to the concrete of the same layer, but the frictional force is Since it is relatively small, in order to fully bear the propulsion reaction force on the lining concrete, the length of the inner form must be made considerably long (so that the frictional force becomes larger than the propulsive reaction force). However, a huge area of formwork is required.

The present invention has been proposed in view of the problems of the prior art, and its purpose is to reduce the propulsion reaction force of a shield excavator by integrating the inner formwork and lining concrete. The object of the present invention is to provide a cast-in-place concrete lining construction method that allows sufficient load to be placed on the lining concrete through the inner formwork, thereby significantly reducing the length of the inner formwork.

(Means for Solving the Problems) In order to achieve the above object, the cast-in-place concrete lining construction method according to the present invention includes a shell in which stud bolts and long nuts are planted on the mounting plate on the inner peripheral surface of the inner formwork. The connector is fixed via a bolt inserted from the opposite side of the inner formwork and screwed onto the long nut, and concrete is pressurized and filled into the inner formwork, and after the concrete hardens, the bolt is fixed. After removing and propelling the shield excavator by taking the reaction force from the inner formwork which is integrated with the existing concrete lining part adjacent to the rear via the shear connector, the inner formwork and shear connector are bolted together again. It is characterized by being fixed through.

(Function) According to the present invention, as described above, a shear connector having a stud bolt and a long nut planted on the mounting plate is attached to the inner peripheral surface of the inner formwork, and the bolt is inserted from the opposite side of the inner formwork. When concrete is supplied into the annular space formed between the tail plate of the shield excavator and the inner formwork by screwing it onto the long nut, the concrete hardens and the inner formwork If the frame and concrete are simply integrated, and the concrete has sufficient strength, the propulsion reaction force of the shield excavator can be sufficiently borne through the inner formwork.

In addition, when propelling the shield excavator, first remove the bolts that are fixed to the inner formwork of the newly lined concrete part, and then attach the propulsion jack installed on the shield excavator to the inner formwork. was set, and the propulsion reaction force due to the elongation of the jack was borne by the same-layer e-concrete through the inner formwork that was integrated with the existing lining concrete adjacent to the rear via a shear connector. ,
The newly lined concrete portion is not affected by any reaction force during propulsion.

(Example) The present invention will be described below with reference to the illustrated embodiments.

(A) is a shear connector, with a stud bolt (3) attached to a steel mounting plate (2) with a foamed resin material (1) layered on the back side.
It is constructed by planting long nuts (4). (Second
(See Figures and Figure 3) Then, insert the bolt (5) inserted from the opposite side of the shear connector (A) into the inner peripheral surface of the inner formwork (B) with the long nut (
4) Attach by screwing to the inner formwork (B)
is assembled in the front part of the existing lining concrete (C) in the tail plate (6) of the shield excavator, and the reinforcing bars (7) are assembled inside the inner formwork (B) (see Figure 1A). Concrete supply port (8) of formwork (B)
Connect the concrete supply pipe (9) to the end of the annular space formed between the tail plate (6) and the front of the existing concrete lining (C) in the inner formwork (B). Set the press ring plate (11) of the concrete engineering jack (10), open the valve (12) of the concrete supply pipe (9), and pour concrete into the annular space.
- (13) is supplied. (See Figure 1B) After the supply of concrete (13) is completed, the valve (12) is closed, the tail plate (6) is moved forward via the tail plate moving jack, and at the same time the concrete press-fitting jack (10) is moved forward. is expanded and filled with concrete (13) under pressure. (See Figure 1C) When the concrete (13) hardens, remove the concrete supply pipe (9) and use the concrete engineering jack (10).
) and then remove the bolts (5) from the inner formwork (B).
Remove the shield jack (14) of the shield excavator from the inner formwork (B), and set it on the front end surface of the inner formwork (B).
The propulsion jack (14) takes the reaction force on the inner formwork (B) which is integrated with the existing lining concrete (C) part behind the concrete (13) part via the shear connector (^).
) to resume excavation by the shield excavator. (See Figure 1D) At this time, the bolt (5) has been removed and the shear connector (A) is no longer fixed to the formwork (B) of the concrete (13) pouring area, so the shear connector ( A propulsive reaction force is applied to ^),
There is no problem that the concrete (13) is adversely affected by the propulsion reaction force.

After the required amount of excavation was done by the shield excavator,
Retract the propulsion jack (14) and repeat the above steps. (See Fig. 1E) '(Effects of the Invention) According to the present invention, as described above, a shear connector with stud bolts and long nuts set on the mounting plate is attached to the inner peripheral surface of the inner mold. By inserting it from the opposite side of the frame and fixing it through the bolt screwed to the long nut, a hole is formed between the inner formwork, the tail plate of the shield excavator, and the front surface of the existing lining concrete. The concrete and the inner formwork are integrated, and the propulsion reaction force of the shield excavator can be sufficiently borne through the inner formwork,
As a result, the length of the inner formwork is significantly reduced.

In addition, as mentioned above, when a shear connector is attached to the inner formwork and concrete is pressurized into the inner formwork and the shield excavator is propelled, the mounting bolts of the shear connector are removed and the propulsion reaction force is transferred to the rear. By having the inner formwork integrated into the existing lining concrete part via a shear connector, the concrete pressurized and filled into the inner formwork will not be adversely affected by the propulsion reaction force. This is Nishuruchino.

[Brief explanation of the drawing]

1A to 1E are vertical sectional views showing steps of an embodiment of the cast-in-place concrete lining method according to the present invention; FIG. Figure 3 is a plan view of the shear connector, Figure 4
Figures A to 4E are longitudinal sectional views showing the steps of the conventional cast-in-place concrete lining method. (A) - Shear connector, (B) - Inner formwork, (C
) - Existing concrete lining, (2) - Mounting plate, (3) - Stud bolts,
(4) - Length nut, (5) - Bolt, (6)
- tail plate, (13) - concrete, (14)
Propulsion jack. Agent: Patent attorney Shige Okamoto (2 persons) Figure 2 Figure 3

Claims (1)

[Claims] (1) Concrete is pressurized and filled into the annular space formed between the inner formwork assembled in the tunnel hole dug by the shield excavator, the tail plate, and the front surface of the existing lining concrete, and the inner form In the cast-in-place concrete lining construction method in which the shield excavator is propelled by a digging jack mounted on the shield excavator by taking reaction force from the frame, stud bolts and long nuts are attached to the mounting plate on the inner peripheral surface of the inner formwork. The planted shear connector is fixed via a bolt inserted from the opposite side of the inner formwork and screwed onto the long nut, and concrete is filled under pressure into the inner formwork, and the concrete is solidified. After removing the bolts, the shield excavator is propelled by the reaction force against the inner formwork integrated with the existing concrete lining part adjacent to the rear via the shear connector, and then the inner formwork and shear are connected again. A cast-in-place concrete lining construction method that is characterized by fixing the connector with bolts.