RU2003807C1 - Process of construction of tunnel and tunnel shield for its implementation - Google Patents

Abstract

Usage: the construction of tunnels with combined lining. The inventive sealing material is fed into the annular gap after installing the block ring in the design position, and the compression of the block ring is carried out when pressing the sealing material by the relative displacement of the sealing ring and the shield The latter is provided with longitudinal guides in the rear part, in which the sealing ring with its extension cylinders. Longitudinal guides are made with channels having lateral branches at one end. The other ends of the channels are connected s with pipelines for supplying sealing material 2 s and 4 zpf-ly. 11 silt

Description

The invention relates to underground construction and can be used in the construction of tunnels with combined lining.

There is a known method of constructing a tunnel, including the development of a slab, moving the tunneling shield to the next run, assembling the block lining ring, setting the block ring in the design position, supplying the concrete mixture to the annular gap, pressing the concrete mixture and filling it with the finishing gap (V.Kh. Klorik n and V.A. Khodosh, M. Nedra, 1977, p. 20, fig. 2.6, b).

The disadvantages of this method are the complexity of the technology, due to the need to use additional tools to install and hold the block ring lining concentrically to the tail of the shield, as well as the reduced construction speed of the tunnel, since operations to move the tunneling shield and pressing the concrete mixture are carried out, as a rule at different times. In such cases, the shield is moved after sufficient strength of the concrete mixture has been set. In this case, the use of hydraulic shield jacks for pressing the concrete mixture into the closing gap and for moving the shield reduces the quality of the lining, since the force required to move the shield can exceed the force required for pressing, which can lead to the destruction of the compacted concrete mixture and the collapse of the block ring .

The closest in technical essence and the achieved result to the proposed one is a method of constructing a tunnel, including developing a face, moving the shield for the next entry with hydraulic shield jacks, assembling the block lining ring, feeding the sealing material into the annular gap, installing the block ring in the design position, pressing the sealing material displacement of the sealing ring in the longitudinal direction by hydraulic jacks for its extension, compression of the block ring of the lining (ed. St. USSR No. 1268733, class E 21 D 11 / 00.1985).

This method allows you to speed up the construction of the tunnel by combining the operations of moving the shield, installing the block ring in the design position and pressing the sealing material. In this case, the block ring is assembled in the calibration shell of the shield, and the press ring and additional hydraulic jacks are used to press the sealing material

The disadvantage of this method is that it is impossible to compress the block ring simultaneously with the compression of the sealing material, so

as the main cycle of pressing the sealing material takes place in a confined space bounded by a press ring, the tail shell of the shield and the calibration shell. In this case, the sealing material formed in the main part of the pressing cycle takes on a certain shape, and then it comes off under the action of the press ring on the block ring and rock mass. At

5, under the constant efforts of the press ring, the molded volume of the sealing material must be reshaped and fill the free volumes formed due to the thicknesses

0 tail and gauge shells of the shield, as well as fill voids and pores in the rock mass and leaks at the joints of the block lining.

It is known that the reforming of pressed compaction materials due to their changing properties, for example, the extraction of liquid phases from concrete mixtures, a sharp change in temperature for thermoplastic materials, etc., leads to

0 in the best case, to crack formation, and more often to complete structural destruction of volumes formed by primary pressing. In addition, injection and molding of the sealing material in a rigid

5, the system formed by the tail of the shield and the gauge sheath degrade shield maneuverability and increase the effort required to move the shield. All this complicates the construction of the tunnel,

0 shield design and reduces the quality of the lining of the tunnel.

The aim of the invention is to simplify the technology of construction of the tunnel, the design of the shield and a significant increase

5 quality tunnel lining.

The goal is achieved in that the sealing material is fed directly to the outer surface of the block ring after it is installed in

0 design position in the sealing ring, and the compression of the block ring is carried out when pressing the sealing material by the relative displacement of the sealing ring and the tunnel shield.

5 The width of the annular gap between the tail shell of the shield and the outer surface of the block ring before feeding the sealing material is regulated depending on the properties and type of sealing material.

The operation mode of the tunnel shield with this device can be considered normal if the volumes of voids and leaks generated by the shield displacement are equal to the volume of sealing material required to fill these voids and leaks and pushed out by the sealing ring. Then the ratio of the speed of movement of the tunnel shield relative to the block ring to the speed of movement of the sealing ring is determined by the following expression

Ky Ky (R22 -Ri2) vy Ksc (R3 2 - Ra 2)

where reed is the speed of movement of the tunnel shield (relative to the block ring);

Vy is the speed of movement of the sealing ring;

RI is the outer radius of the block ring;

R2 is the inner radius of the tail of the tunnel shield;

Нз - outer radius of the tail of the tunnel shield;

KU - coefficient taking into account the increased volume of the ejected sealing material to fill leaks at the joints of the block ring;

Rf is the coefficient of increased consumption of sealing material to fill voids and pores in the rock mass.

To carry out the method, the sinking shield is provided with longitudinal guides in which a sealing ring is mounted. Longitudinal guides have channels with side openings at one end, and the other ends are connected to pipelines for supplying sealing material.

To achieve this goal, a combination of essential features is required.

The supply of sealing material to the annular gap between the tail of the shield and the block ring after the block ring is placed in the design position directly on the outer surface of the block ring allows filling and sealing gaps and leaks in the lining at the same time as squeezing the block ring, and also seal the rock mass, improving contact him with a lining.

Adjusting the width of the annular gap allows you to suppress the sealing material in small portions, reducing the force on the block ring (in the radial

fifty

5

0

5

0

fifty.

5

0 5

direction) during compression, or to ensure the construction of the lining when changing the direction of penetration.

The implementation of longitudinal guides in the tunnel shield, on which the sealing ring is movably mounted, allows the sealing ring to be used as a calibration shell when assembling the block lining ring and setting it to the design position. The execution in these guide channels with side openings allows the pipelines of the supply of sealing material to be placed in the shield motionless. The sealing ring, blocking or opening the side openings in the guides, is a shutter that automatically adjusts the supply of sealing material depending on the required volume until the cavities are filled when the shield moves.

All this improves the tunnel construction technology, increases reliability and simplifies the design of the shield.

When conducting patent research, no technological solutions were found that coincided with the distinguishing features of the claimed technical solution.

Figure 1 shows a tunnel shield for implementing a tunnel construction method; figure 2 - section aa in fig. 1; Fig. 3 shows the position of the sealing ring after installing the block ring in the design position and feeding the sealing material; Fig. 4 is the same after pressing the sealing material in the intermediate position of the shield hydraulic jacks; Fig. 5 shows the position of the sealing ring and shield hydraulic jacks during the next supply of sealing material; Fig. 6 is the same, after pressing the sealing material over the entire stroke length of the shield hydraulic jacks; Fig.7 is the same in the assembly process of the block ring; in Fig.Z - section bB in Fig.2; figure 9 is a section bb in figure 2; in FIG. 10 - section GG in Fig.9; in FIG. 11 is a section DD in Fig.9.

The tunnel construction method is carried out using a tunneling shield comprising a housing 1 with a knife part 2 and a tail part 3, a working body 4, and hydroshield panels 5.

A sealing ring 7 with hydraulic jacks 8 for its extension is installed in the tail part 3 with longitudinal guides 6. Longitudinal guides b have channels 9 with side openings 10 at one end. The other ends 11 are connected

with pipelines 12 for supplying sealing material.

Shield hydraulic jacks 5 with persistent shoes 13 are located in the support ring 14 of the housing 1 of the tunnel shield.

The hydraulic jacks 8 for extending the sealing ring 7 are mounted on the housing 1 through the brackets 15, and attached to the sealing ring 7 through the brackets 16, The side holes 10 are made on the back, exceeding the length of the sealing ring 7 in the initial position with the retracted rods of the hydraulic jacks 8 by value of AS. The length of the sealing ring 7 in the extended position over the entire stroke length of the hydraulic jacks 8, its extension is less than the length of the tail part 3 by the amount D1, which ensures guaranteed overlap of the flashing gap (for example, from the breakthrough of groundwater into the tail section of the tunneling shield).

The method is as follows.

After assembling the block lining ring in the sealing ring 7 and installing the block ring 17 in the design position, an annular material is fed directly to the outer surface of the block ring 19 between the tail portion 3 and the block ring 17. The supply of sealing material is carried out through pipelines 12, channels 9 and through side openings 10.

After supplying the sealing material, the pressing of the material begins by the relative displacement of the sealing ring 7 and the driving shield, for which the rods of the hydraulic jacks 8 of the extension of the sealing ring 7 and the rods of the shield hydraulic jacks 5 are simultaneously extended, while the installed ring 17 is pressed against the previous rings 19 of the block lining. When the piston rods 8 extend the sealing ring 7, the lateral holes 10 are blocked by the sealing ring 7 and the supply of the sealing material to the annular gap 18 is stopped. Simultaneously with the pressing of the sealing material, the block ring 17 is crimped and the sealing gap is filled with the sealing material 20.

After extending the sealing ring 7 over the entire stroke length of the hydraulic jacks 8 by pulling in the hydraulic jack rods 8, the sealing ring 7 is returned to its original position and the sealing material is fed along the stroke length of the shield hydraulic jacks 5. The feed is made repeatedly by adjusting the width of the annular gap 18 depending on the properties of the sealing material and the direction of penetration (if you change the direction of penetration after each cycle of feeding the sealing material, you must move the tunneling shield).

The movements of the tunnel shield and the sealing ring are carried out while maintaining

the equality of the volume of filling with the sealing material 20 of the annular gap 21. formed by the displacement of the tunneling shield, and the volume 22 generated from the pressing of the sealing material

O-ring 7, i.e.

twenty

,

(3rR32- YAKa2) Sui,

(ttR22- # Rl2) Sy,

vi is the volume of filling with the sealing material of the annular gap forming — with when the tunnel shield is displaced;

va is the volume generated from the compression of the sealing material by the sealing ring;

 - the outer radius of the block ring lining;

R2 is the inner radius of the tail of the shield;

Pz - the outer radius of the tail of the shield;

Zsch - shift of the shield relative to the lining of the tunnel towards the side;

Sy is the displacement of the sealing ring relative to the lining of the tunnel toward the tail;

Ku is a coefficient taking into account the increased volume of the ejected sealing material to fill the leaks at the joints of the block ring;

Kg - coefficient of increased consumption of sealing material to fill voids and pores in the rock mass.

If

then

Kz (nLaz-K22) (7rR22-Ri2) -Sy.

Sut.Ky ()

Sv Km (R32-R22) The speed of movement of the shield and o-ring is determined by the formula

Uh

 W

Vy

 Eu

t

where t is the time of movement of the shield and the sealing ring.

In this way

USCH Ky (R2 (R22 -Ri2) vy Ksc (R3 2 - Ra 2)

If necessary, depending on the properties of the sealing material, it is possible to perform multiple pressing of the sealing material while the tunnel shield is stationary. To do this, the rods of the shield hydraulic jacks 5 are retracted, the sealing ring 7 is withdrawn towards the side, the sealing material is fed into the annular gap 18 again and the sealing ring 7 is extended and the sealing material is pressed onto the side of the tail part of the shield, while the block ring M is held in the design position by compressing the sealing material in the sealing ring 7 and by the emphasis of the shoes 13 of the shield hydraulic jacks 5.

After pressing the sealing material and extending the shield hydraulic jacks 5, the entire stroke is retracted

the rods of the shield hydraulic jacks 5 and the rods of the hydraulic jacks 8 of the extension of the sealing ring 7, returning it to its original position. Then they begin to simultaneously develop the face and assemble the next block ring 17 lining.

The proposed invention in comparison with the prototype allows to simplify and

to improve the construction technology of the tunnel with combined lining due to the ability to crimp the block ring simultaneously with the pressing of the sealing material, to repeatedly pressurize the sealing material when the tunnel shield is stationary, which improves the quality of the constructed lining and tunnel while maintaining the tunnel construction speed and

exceptions to the sediment of the earth's surface.

(56) Mining and oilfield engineering. Mechanized sinking shields. M .: VINITI, 1971. Copyright certificate No. 1268733, class. E21 D 11/00, 1985.

Claims (6)

1. A method of constructing a tunnel, including the development of the face, moving the tunneling shield for the next approach with shield hydraulic jacks, assembling the block lining ring, supplying the sealing material to the annular gap, installing the block ring in the design position, pressing the sealing material by shifting the sealing ring in the longitudinal direction with hydraulic jacks moving, crimping the block ring of the lining, characterized in that, in order to simplify the technology and improve the quality of the constructed tunnel, tighten The laminar material is fed into the annular gap on the outer surface of the block ring after its installation and the design position in the sealing ring, and the compression of the block ring is performed when pressing the sealing material by the relative displacement of the sealing ring and the tunnel shield. 2. The method according to claim 1, characterized in that the displacement of the tunnel shield and the sealing ring is determined while maintaining the equality of the volume of filling the ductile material of the annular gap formed when the tunnel shield is displaced and the volume formed from sealing the pliable material with a sealing ring. 3. The method according to claims 1 and 2, characterized in that the ratio of the speed of movement of the tunneling shield and the speed of displacement of the sealing ring is determined by the formula USCH KyfR2. - R2,) at Ksch (Rz - R2) where USh is the speed of movement of the tunnel shield relative to the lining of the tunnel towards the side; Vy is the speed of movement of the sealing ring relative to the lining of the tunnel and to the side of the tail; Rt is the outer radius of the block ring; R2 - inner radius of the tail sinking shield, RP - the outer radius of the tail sinking shield; Ku is a coefficient taking into account the increased volume of the ejected sealing material to fill the leaks at the joints of the block ring; Rf is the coefficient of increased consumption of sealing material to fill voids and pores in the rock mass. 4. The method according to claim 1, characterized in that the pressing of the sealing material is carried out by displacing the sealing ring while the tunnel shield is stationary. 5. The method according to claim 1, characterized in that the pressing of the sealing material is carried out by simultaneously shifting the sealing ring towards the tail end and the tunnel shield towards the side. 6. A driving shield, including a housing with a knife and tail parts, work the body, shield hydraulic jacks, a sealing ring with hydraulic jacks for moving it and pipelines for supplying sealing material, characterized in that the tail part of the shield is provided with longitudinal guides in which the sealing ring is installed, while the longitudinal guides have channels with lateral branches on one ends, and the other ends connected to the piping supply of the sealing material. 0W./ D ± YG I I crs I to - oh oh so CD about -J fc R N : N Ј, K2 totti