CN113565539B

CN113565539B - Construction method for preventing primary support side rebound of tunnel cantilever type cast-in-situ side wall

Info

Publication number: CN113565539B
Application number: CN202110865321.8A
Authority: CN
Inventors: 齐如见; 陈磊; 杨海航; 刘盛; 刘龙卫; 蔡建刚; 陈真; 王卓; 胡英姿; 刘运发; 王旭; 龚博; 高鑫凯; 王邹渝; 江明锋
Original assignee: China Railway Tunnel Group Co Ltd CRTG; China Railway Tunnel Group Yichu Co Ltd
Current assignee: China Railway Tunnel Group Co Ltd CRTG; China Railway Tunnel Group Yichu Co Ltd
Priority date: 2021-07-29
Filing date: 2021-07-29
Publication date: 2023-12-15
Anticipated expiration: 2041-07-29
Also published as: CN113565539A

Abstract

The invention discloses a construction method for preventing primary support side rebound of a tunnel cantilever type cast-in-situ side wall, which comprises the following steps of A, binding a tunnel lining side wall reinforcement cage, wherein the construction method comprises the steps of lining outer side annular main ribs, lining inner side annular main ribs, lining outer side longitudinal skeleton ribs, lining inner side longitudinal skeleton ribs, tie anchor rods and radial ribs, the lining outer side annular main ribs on the left side and the right side are connected into a ring at a tunnel arch part, the outer side ends of the tie anchor rods are welded and fixed with the top of the tunnel lining side wall reinforcement cage, the inner side ends are vertically driven into a tunnel rock soil layer, and one ends of the radial ribs, which are close to the lining outer side annular main ribs, are bent to be 7-shaped; step B, positioning a side wall template trolley; step C, cutting off exposed sections of tie anchor rods of the tunnel lining side wall reinforcement cage; and D, pouring side wall lining concrete, wherein the top of the formed side wall lining concrete is a plane, and a row of hemispherical grooves are formed at equal intervals along the longitudinal direction. The cantilever type side wall reinforcement cage is prevented from rebounding to the primary support side, and good stability of the side wall reinforcement cage is ensured.

Description

Construction method for preventing primary support side rebound of tunnel cantilever type cast-in-situ side wall

Technical Field

The invention belongs to the technical field of tunnel concrete lining construction, and particularly relates to a construction method for preventing primary support side rebound of a tunnel cantilever type cast-in-situ side wall.

Background

The traditional construction process of the second lining of the tunnel adopts full-ring steel bar binding, and then combines with a full-hydraulic lining trolley to perform full-ring second lining concrete pouring in a mode of injecting concrete into vertical pouring holes at the top hole by hole. The traditional construction process utilizes the principle that concrete gravity automatically fills the space of the second lining, but because the fluidity of the concrete is difficult to reach an ideal state, after the concrete is poured into a tunnel vault, the whole pouring longitudinal section is basically distributed in an isosceles triangle shape, the isosceles sides of the isosceles triangle change along with the size of the pouring opening spacing, and the larger the pouring opening spacing is, the longer the isosceles side of the isosceles triangle is, which means that the back of the second lining is more hollow. The phenomenon can also change along with the pressure of the concrete pouring pump, the void phenomenon can be reduced when the pouring pressure is larger, the void phenomenon can be increased when the pouring pressure is smaller, and meanwhile, the air between the two vault pouring holes is difficult to completely empty, so that the vault cavitation phenomenon is unavoidable.

In order to solve the problem that the arch part of the back of the second lining is empty, the project group provides that the second lining of the tunnel is divided into side walls and tunnel arches at the left side and the right side, the side walls are cast in situ firstly, then the prefabricated arch duct pieces outside the tunnel are transported into the tunnel, and the side walls are arranged on the cast-in-situ side walls for assembly, so that the construction of the second lining is completed. As shown in fig. 1 and 2, the tunnel lining side wall reinforcement cage is formed by lining an outer side annular main rib 1, lining an inner side annular main rib 2, lining an outer side longitudinal skeleton rib 3 and lining an inner side longitudinal skeleton rib 4, the lining outer side annular main rib 1 and the lining inner side annular main rib 2 are respectively connected in series through the lining outer side longitudinal skeleton rib 3 and the lining inner side longitudinal skeleton rib 4 after being bound, and the inner layer and the outer layer are connected in a opposite-pulling mode through radial ribs 6, and the joint is bound and formed. The arch part is needed to be cut off by the side wall reinforcement cage, so that the two side wall reinforcement cages on the left side and the right side are respectively in a cantilever state, rebound to the primary support side is easy, and the stability requirement of the cantilever reinforcement cage cannot be met.

Disclosure of Invention

The invention aims to provide a construction method of a tunnel cantilever type cast-in-situ side wall, which can prevent a cantilever type side wall reinforcement cage from rebounding to a primary support side and ensure good stability of the side wall reinforcement cage.

The technical scheme adopted by the invention is as follows: a construction method for preventing primary support side rebound of a tunnel cantilever type cast-in-situ side wall comprises the following steps:

step A, binding a tunnel lining side wall reinforcement cage;

the tunnel lining side wall reinforcement cage comprises lining outer side annular main ribs, lining inner side annular main ribs, lining outer side longitudinal skeleton ribs, lining inner side longitudinal skeleton ribs, tie anchor rods and radial ribs, wherein the lining side wall reinforcement cages on the left side and the right side are bound at the same time, the lining outer side annular main ribs on the left side and the right side are connected into a ring at a tunnel arch part, the lining inner side annular main ribs on the left side and the right side are matched with the tunnel side wall in height, the tie anchor rods are hollow arch foot anchor rods, the outer side ends of the tie anchor rods are welded and fixed with the top of the tunnel lining side wall reinforcement cage, the inner side ends of the tie anchor rods are vertically driven into a tunnel rock layer, one ends of the radial ribs, which are close to the lining outer side annular main ribs, are bent to be 7-shaped, and bent parts are arranged along the lining outer side annular main ribs in parallel;

step B, positioning a side wall template trolley;

step C, cutting off exposed sections of tie anchor rods of the tunnel lining side wall reinforcement cage;

and D, pouring side wall lining concrete, wherein the top of the formed side wall lining concrete is a plane, and a row of hemispherical grooves are formed at equal intervals along the longitudinal direction.

As an optimization of the scheme, the tunnel lining side wall reinforcement cage further comprises a reinforcing reinforcement bar, wherein the reinforcing reinforcement bar is arranged at the upper part of the tunnel lining side wall reinforcement cage so as to strengthen the strength of a top splicing position, and the reinforcing reinforcement bar is a net structure surrounded by an n-shaped outer side annular reinforcement bar, an n-shaped inner side annular reinforcement bar, a radial reinforcement bar and a longitudinal reinforcement bar; the outer side annular reinforcing ribs of the 'n' shape are bound on the lining outer side annular main rib, the top ends of the outer side annular reinforcing ribs of the 'n' shape extend to the upper side of the lining outer side annular main rib, the inner side annular reinforcing ribs of the 'n' shape are bound on the lining inner side annular main rib, and the top ends of the inner side annular reinforcing ribs of the 'n' shape extend to the upper side of the lining inner side annular main rib, so that an 'n' -shaped lug is formed on the inner side and the outer side of the hemispherical groove of the tunnel lining side wall reinforcement cage respectively, and the inner side 'n' -shaped lug is higher than the outer side 'n' -shaped lug. The joint of the top of the side wall and the prefabricated segment of the arch part is stressed complicated and is easy to collide in the construction process, and reinforcing bars are additionally arranged in a certain range of cast-in-situ side wall reinforcement cages at the joint so as to enhance the strength at the splicing position; the reinforcing ribs adopt a net structure formed by surrounding an n-shaped outer circumferential reinforcing rib plus an n-shaped inner circumferential reinforcing rib plus a radial reinforcing rib plus a longitudinal reinforcing rib, and an n-shaped lug is formed on the inner side and the outer side of the hemispherical groove of the tunnel lining side wall reinforcement cage respectively, so that the splicing strength of the hemispherical groove position is further enhanced.

Further preferably, the outer side end of the tie anchor rod is welded and fixed with an n-shaped lug on the inner side of the reinforcing bar and is positioned above the n-shaped lug on the outer side. On the basis that main ribs on an outer ring are connected into a ring, the outer side end of the tie anchor rod is welded with an n-shaped lug on the inner side of the reinforcing rib to form a crossed stress structure for pulling the outer rib in the circumferential direction and the inner rib in the radial direction, and the stability of the reinforcement cage in the vertical mold is better.

Further preferably, the lining outer side annular main rib of the tunnel lining side wall reinforcement cage is gradually inclined towards the tunnel wall, so that the width of the upper part of the tunnel lining side wall reinforcement cage is gradually increased. The width of the top of the reinforcement cage is increased, the annular main ribs outside the lining are limited to incline towards the tunnel wall gradually, the annular main ribs inside the lining are unchanged, and the stability of the whole structure is better.

Further preferably, the longitudinal spacing of the lining outer side annular main rib, the lining inner side annular main rib and the tie anchor rod is 2m, and the annular spacing of the lining outer side longitudinal skeleton rib, the lining inner side longitudinal skeleton rib and the radial rib is 2m; the diameters of the lining outer side annular main ribs and the lining inner side annular main ribs are phi 25mm, and the diameter of the tie anchor rod is phi 32mm; the lining outer side longitudinal skeleton rib, the lining inner side longitudinal skeleton rib and the reinforcing reinforcement rib are all made of steel bars with phi 10 mm.

The invention has the beneficial effects that:

(1) The tunnel lining side wall reinforcement cage adopts a fixing mode that an outer side annular main reinforcement is completely annular, an inner side annular main reinforcement is disconnected, an outer side longitudinal skeleton reinforcement and a radial reinforcement are bent to form a 7 shape, and a tie anchor rod is adopted, so that the stability of the reinforcement in a cantilever state during the binding of side wall lining reinforcement is ensured, and the construction safety is ensured; the side wall reinforcement cage can be ensured not to rebound to the primary support side, so that the side wall reinforcement cage is accurately positioned, and the thickness of the side wall reinforcement protection layer is ensured to meet the design requirement;

(2) The side wall reinforcement cages on the left side and the right side are connected into a ring only through the main ribs on the outer ring, the main ribs on the inner ring are disconnected respectively, so that the stability of the side wall reinforcement cages on the left side and the right side can be ensured, enough space can be vacated for assembling the arch prefabricated pipe pieces, and the arch prefabricated pipe pieces are installed in a lifting mode from bottom to top;

(3) After the casting of the side wall is finished, a row of hemispherical grooves are formed in the top of the cast side wall along the longitudinal direction, the distance between two adjacent hemispherical grooves is equal to the thickness of a single prefabricated arch duct piece, and the prefabricated arch duct pieces are assembled in a regrouping mode; correspondingly, hemispherical bulges are arranged on the arch prefabricated pipe piece, the arch prefabricated pipe piece and the side wall are assembled in a hemispherical mode, and compared with an L-shaped assembling mode, the novel arc prefabricated pipe piece can effectively reduce working stress, effectively slow down abrasion and reduce negative conditions of bending, cracking and fracture of components.

Drawings

Fig. 1 is a schematic structural view of a side wall reinforcement cage before modification.

Fig. 2 is a partial enlarged view of fig. 1.

Fig. 3 is a schematic structural view of the improved side wall reinforcement cage.

Fig. 4 is a partial enlarged view of fig. 3.

Fig. 5 is a schematic structural view of the radial rib.

Detailed Description

The invention is further illustrated by the following examples in conjunction with the accompanying drawings:

according to the construction method for preventing primary support side rebound of the tunnel cantilever type cast-in-situ side wall shown in fig. 3 to 5, the construction method comprises the following steps:

and step A, binding a tunnel lining side wall reinforcement cage.

The tunnel lining side wall reinforcement cage mainly comprises lining outer side annular main ribs 1, lining inner side annular main ribs 2, lining outer side longitudinal skeleton ribs 3, lining inner side longitudinal skeleton ribs 4, tie anchor rods 5 and radial ribs 6. The lining side wall reinforcement cages on the left side and the right side are bound simultaneously, the lining outer side annular main ribs 1 on the left side and the right side are connected into a ring at the arch part of the tunnel, and the lining inner side annular main ribs 2 on the left side and the right side are matched with the tunnel side wall in height. The circular main ribs on the inner sides of the lining on the left side and the right side are respectively disconnected to vacate the space on the inner ring for assembling the prefabricated segment of the arch part.

The tie anchor rod 5 adopts a hollow arch foot anchor rod, the outer side end of the tie anchor rod 5 is welded and fixed with the top of a tunnel lining side wall reinforcement cage, and the inner side end of the tie anchor rod is vertically driven into a tunnel rock soil layer. One end of the radial rib 6, which is close to the lining outer side annular main rib 1, is bent to be 7-shaped, and the bent part is arranged along the lining outer side annular main rib 1 in a parallel line manner so as to increase the strength of the lining outer side annular main rib 1.

And B, positioning the side wall template trolley, and pouring after sealing the mold by adopting the side wall template trolley.

And C, cutting off exposed sections of the tie anchor rods of the tunnel lining side wall reinforcement cage.

And D, pouring side wall lining concrete, wherein the top of the formed side wall lining concrete is a plane, a row of hemispherical grooves 7 are formed at intervals along the longitudinal direction at equal intervals, each hemispherical groove 7 is correspondingly provided with an arch prefabricated segment, and the distance between two adjacent hemispherical grooves 7 is equal to the thickness of a single arch prefabricated segment. The arch prefabricated segment is prefabricated and formed outside the tunnel hole.

Preferably, the tunnel lining side wall reinforcement cage further comprises reinforcing bars. The reinforcing bars are arranged on the upper part of the tunnel lining side wall reinforcement cage so as to strengthen the strength of the splicing position of the top. The reinforcing rib is a net structure surrounded by an n-shaped outer circumferential reinforcing rib 8, an n-shaped inner circumferential reinforcing rib 9, a radial reinforcing rib 10 and a longitudinal reinforcing rib 11. The n-shaped outer circumferential reinforcing rib 8 is bound on the lining outer circumferential main rib 1, the top end of the n-shaped outer circumferential reinforcing rib 8 extends to the upper side of the lining outer circumferential main rib 1, the n-shaped inner circumferential reinforcing rib 9 is bound on the lining inner circumferential main rib 2, and the top end of the n-shaped inner circumferential reinforcing rib 9 extends to the upper side of the lining inner circumferential main rib 2, so that an n-shaped lug is formed on the inner side and the outer side of the hemispherical groove 7 of the tunnel lining side wall reinforcement cage, and the n-shaped lug on the inner side is higher than the n-shaped lug on the outer side.

In addition, the outer side end of the tie anchor rod 5 is welded and fixed with the n-shaped lugs on the inner side of the reinforcing ribs and is positioned above the n-shaped lugs on the outer side.

The lining outer circumferential main rib 1 of the tunnel lining side wall reinforcement cage gradually inclines towards the tunnel wall, so that the width of the upper portion of the tunnel lining side wall reinforcement cage is gradually increased.

Preferably, the longitudinal spacing of the lining outer side annular main rib 1, the lining inner side annular main rib 2 and the tie anchor rods 5 is 2m, and the circumferential spacing of the lining outer side longitudinal skeleton rib 3, the lining inner side longitudinal skeleton rib 4 and the radial rib 6 is 2m; the diameters of the lining outer side annular main ribs 1 and the lining inner side annular main ribs 2 are phi 25mm, and the diameter of the tie anchor rod 5 is phi 32mm; the lining outer side longitudinal skeleton rib 3, the lining inner side longitudinal skeleton rib 4 and the reinforcing reinforcement are all made of steel bars with phi 10 mm.

In the actual construction process, the step-assembled structural form of the side wall and the prefabricated segment of the arch part is also tried, as shown in fig. 1. In the practical application process, the construction quality control difficulty of the structural form of the step assembly is high, and the analysis reasons are as follows:

1) Because of factors such as template positioning accuracy, concrete shrinkage deformation, whole convergence deformation of the side wall and the like, the cast-in-situ side wall has a corner at the step position, and the construction accuracy cannot meet the design requirement, so that gaps exist in contact when the prefabricated arch duct pieces are assembled, the contact surfaces along the radial direction of the lining rings cannot be contacted or locally (point) contacted, the side wall and the prefabricated arch duct piece lining cannot transmit axial force, and the structural stability of the side wall is affected.

2) The vibration of the top of the cast-in-situ side wall is problematic, because the top of the side wall has corner steps, the requirement on forming precision is high, the concrete injection of the top of the side wall is difficult to deepen, the quality defect of the concrete at the joint of the top of the side wall is caused, in the injection process, coarse aggregate is caused to sink if a vibrator is adopted, and the joint casting is not full if an attached vibrator is adopted;

3) The corner step cover die is easy to be blocked in the process of removing, the proper die removing time of the side wall is difficult to be mastered, the concrete corner is easy to be broken due to early removal time (strength is not reached), and the die plate is easy to adhere to the concrete after the removal time, so that the die removing difficulty is increased. Even if the first plate side wall lining strength reaches 13MPa and then the cover mould is removed, part of the concrete surface is damaged during demoulding, and the mould removing strength is controlled at 15-20MPa to ensure the integrity of the concrete surface, but the mould removing difficulty is increased;

4) When the prefabricated arch duct pieces are assembled after the side wall pouring is completed, the prefabricated arch duct pieces are adjusted to be aligned due to the existence of the corner steps, and collision damage is very easy to occur.

Therefore, the corner steps are optimized to be hemispherical joints on the basis of splicing the prefabricated segments of the arch part and the cast-in-situ side wall lining. Compared with the corner step, the hemispherical joint greatly reduces friction between the prefabricated arch duct piece and the cast-in-situ side wall during installation, the installation speed is faster than that of the corner step, collision between lining concrete is reduced, the unfilled edges and the corners are reduced, the hemispherical joint is compact, axial force of the side wall and the prefabricated arch duct piece can be effectively transferred, the side wall is stable in structure, the difficulty that axial force cannot be transferred between the corner step side wall and the prefabricated arch duct piece, the structural stability of the side wall is affected is overcome, the structural form is reasonable in stress, good in stability and economical and feasible, the secondary lining defect of the arch in the driving limit range of the whole railway tunnel is eliminated, and the novel requirements of national assembly type component development can be met.

Claims

1. The construction method for preventing primary support side rebound of the tunnel cantilever type cast-in-situ side wall is characterized by comprising the following steps of:

step A, binding a tunnel lining side wall reinforcement cage;

the tunnel lining side wall reinforcement cage comprises lining outer side annular main ribs (1), lining inner side annular main ribs (2), lining outer side longitudinal skeleton ribs (3), lining inner side longitudinal skeleton ribs (4), tie anchor rods (5) and radial ribs (6), wherein the lining side wall reinforcement cage on the left side and the lining outer side is bound at the same time, the lining outer side annular main ribs (1) on the left side and the lining outer side are connected to form a ring at a tunnel arch part, the lining inner side annular main ribs (2) on the left side and the lining outer side are matched with the tunnel side wall in height, the tie anchor rods (5) are hollow arch foot anchor rods, the outer side ends of the tie anchor rods (5) are welded and fixed with the tops of the tunnel lining side wall reinforcement cages, the inner side ends of the tie anchor rods are vertically driven into a tunnel rock soil layer, one ends, close to the lining outer side annular main ribs (1), of the radial ribs (6) are bent to be 7-shaped, and bent parts are arranged along the parallel lines of the lining outer side annular main ribs (1);

step B, positioning a side wall template trolley;

and D, pouring side wall lining concrete, wherein the top of the formed side wall lining concrete is a plane, and a row of hemispherical grooves (7) are formed at equal intervals along the longitudinal direction.

2. The construction method for preventing primary support side rebound of the tunnel cantilever type cast-in-situ side wall according to claim 1, wherein the construction method comprises the following steps: the tunnel lining side wall reinforcement cage further comprises a reinforcing reinforcement bar, wherein the reinforcing reinforcement bar is arranged at the upper part of the tunnel lining side wall reinforcement cage so as to strengthen the strength of a top splicing position, and the reinforcing reinforcement bar is a net structure surrounded by an n-shaped outer side annular reinforcement bar (8), an n-shaped inner side annular reinforcement bar (9), a radial reinforcement bar (10) and a longitudinal reinforcement bar (11); the n-shaped outer side annular reinforcing ribs (8) are bound on the lining outer side annular main rib (1), the top ends of the n-shaped outer side annular reinforcing ribs (8) extend to the upper portion of the lining outer side annular main rib (1), the n-shaped inner side annular reinforcing ribs (9) are bound on the lining inner side annular main rib (2), and the top ends of the n-shaped inner side annular reinforcing ribs (9) extend to the upper portion of the lining inner side annular main rib (2), so that an n-shaped lug is formed on the inner side and the outer side of the hemispherical groove (7) of the tunnel lining side wall reinforcement cage, and the n-shaped lugs on the inner side are higher than the n-shaped lugs on the outer side.

3. The construction method for preventing primary support side rebound of the tunnel cantilever type cast-in-situ side wall according to claim 2, wherein the construction method comprises the following steps: the outer side end of the tie anchor rod (5) is welded and fixed with an n-shaped lug on the inner side of the reinforcing bar and is positioned above the n-shaped lug on the outer side.

4. The construction method for preventing primary support side rebound of the tunnel cantilever type cast-in-situ side wall according to claim 2, wherein the construction method comprises the following steps: the lining outer side annular main rib (1) of the tunnel lining side wall reinforcement cage gradually inclines towards the tunnel wall, so that the width of the upper portion of the tunnel lining side wall reinforcement cage is gradually increased.

5. The construction method for preventing primary support side rebound of the tunnel cantilever type cast-in-situ side wall according to claim 2, wherein the construction method comprises the following steps: the longitudinal spacing between the lining outer side circumferential main rib (1), the lining inner side circumferential main rib (2) and the tie anchor rods (5) is 2m, and the circumferential spacing between the lining outer side longitudinal skeleton rib (3), the lining inner side longitudinal skeleton rib (4) and the radial rib (6) is 2m; the diameters of the lining outer side annular main ribs (1) and the lining inner side annular main ribs (2) are phi 25mm, and the diameter of the tie anchor rod (5) is phi 32mm; the lining outer side longitudinal skeleton rib (3), the lining inner side longitudinal skeleton rib (4) and the reinforcing reinforcement are all made of steel bars with the diameter of 10 mm.