RU2181416C1 - Method of tunnel construction - Google Patents

Abstract

FIELD: construction engineering, particularly, methods of tunnel construction. SUBSTANCE: method is applicable in construction of low-depth tunnels under acting main traffic arteries without interruption of traffic in them, under complicated mining and geological conditions with presence of watered grounds in tunnel base. Method of tunnel construction includes formation of protective screen in ground, injection consolidation of ground in internal space of contemplated tunnel and from outside of it with formation of injection piles under tunnel base, subsequent working of consolidated ground in internal space of contemplated tunnel and tunnel lining. Novelty consists in that consolidation and working of ground are carried out by tiers with formation of leading overlaying bench and, at least, one underlying bench located under overlaying one. In this case, preliminary consolidation of ground in zone of overlaying tier is effected with formation of reinforced structure of ground with compression strength exceeding the compression strength of ground reinforced structure in underlying tier. Technical result ensured by offered invention consists in increased of reliability and safety of working of ground preliminary consolidated by injection in construction of tunnel under main traffic artery without interruption of traffic in it, under complicated mining and geological conditions with presence of loose watered grounds in base of constructed tunnel due to exclusion of development of settling of tunnel base and day surface exceeding permissible values, and also reduced power and material consumption and labor input due to optimization of process of injection consolidation of ground. EFFECT: higher efficiency. 24 cl, 11 dwg

Description

 The invention relates to the field of construction, and in particular to methods of erecting a tunnel, and can be used in the construction of shallow tunnels under existing highways without interruption in difficult mining and geological conditions, including in the presence of flooded soils at the base of the tunnel.

 The closest to the invention in essence and the technical result achieved is a method of erecting a tunnel, including the formation of a protective screen in the soil, injection fixing the soil in the internal volume of the future tunnel and outside it with the formation of injection piles under the base of the tunnel, the subsequent development of fixed soil in the internal volume of the future tunnel and lining construction (see. A. Malinin. Construction of road tunnels in Perm, Underground space of the world, 5, 1999, pp. 23-25).

 However, the known method does not allow reliable enough to build a tunnel in difficult geological conditions, including the presence of weak watered soils at the base of the tunnel, due to possible sediment of the tunnel base during the construction of the tunnel.

 The objective of the present invention is to increase the reliability and safety of work during the construction of the tunnel while reducing the energy consumption of labor and material costs and optimizing the process of fixing the soil before its development.

 The problem is solved due to the fact that in the method of erecting a tunnel, including the formation of a protective screen in the soil, injection fixing the soil in the internal volume of the future tunnel and outside it with the formation of injection piles under the base of the tunnel, the subsequent development of fixed soil in the internal volume of the future tunnel and the construction of lining , according to the invention, the fixing and development of the soil is carried out in tiers with the formation of a leading overlying ledge and at least one, located below the height overlying, the underlying tier, while preliminary injection fixation of the soil in the zone of the overlying tier is performed with the formation of a reinforced soil structure with compressive strength exceeding the compressive strength of the reinforced soil structure of the underlying tier.

 The reinforced soil structure of the overlying layer can be performed with compressive strength exceeding the compressive strength of the reinforced soil structure of the underlying layer by at least 5%.

 Before the construction of the tunnel, start and receiving pits can be made, a micro-shield complex is installed in the starting pit, with the help of which a protective screen is formed in the ground by forcing in the ground at least over the overlap of the tunnel being built from the starting pit to the receiving one, closed or open in cross section extended metal elements with locking joints between adjacent elements, moreover, at the same stage, additional metal elements closed in cross section to support frames supporting the screen, which are installed during the tiered development of pre-fixed soil.

 A protective screen can be formed around the entire perimeter of the tunnel being constructed in a sequence from the bottom up, with the elements of the chute part of the protective screen being pushed in first using a stationary stop, and the punching device is installed directly on the bottom of the launching pit with the inset of the shield into the ground when punching the first screen elements through the concrete retaining wall, and subsequent ones - through a soil wall fixed by piles and a metal sheet, forcing screen elements in the area of walls a tunnel can be inserted with a shield inset into the ground through concrete retaining walls fixed by pipe piles and wooden pick-up, followed by installation of a punching device on an inventory removable frame, which is installed on previously shrunken and extended elements of the protective screen, and the punching of the protective screen elements in the area of the tunnel overlap carried out with the inset of the shield into the ground through the soil retaining wall, fixed with longitudinal metal beams and a wooden block, and the metal ball ki are used as guides for the shield, and the punching device is installed on the site, which is erected on the screen elements previously squeezed in the wall zone with their building.

 The protective shield can be made of metal pipes, mainly circular cylindrical, including rolled, and / or welded, and / or cold drawn, and / or brazed along the seam, and / or seamless, and / or spiral-seam, and the lock joints in the form of a lock welded on two surfaces of adjacent elements of the screen adjacent to each other, two extended elements, one of which is C-shaped in cross section, and the other in the form of a wall wound into it with a broadening located on the free edge exceeding a width exceeding the width C-shaped cross-sectional element.

 After punching in the soil of each element of the screen, the cavity of the element can be filled with hardening material, which can be used as concrete or polymer concrete.

 The filling of the cavity of each element of the protective screen can be performed with reinforcement, and the reinforcement can be performed with frames, and / or individual rods and / or nets, and / or with the inclusion of rolling profiles, and / or using rod structures such as flat or spatial trusses.

 At least some of the surfaces of the screen elements may be coated with a protective coating before being pressed.

 Filling the cavities of the screen elements can be done by layering the material in a low-pressure mode using self-stacking material.

 When concreting the cavities of the screen elements, the concrete or polymer concrete mixture can be pumped to ensure its movement under the influence of gravitational forces and a slope of up to 2%, moreover, a highly thixotropic self-stacking mixture with a standard cone draft of at least 18 cm is used, and when using the concrete mixture superplasticizing agents can be introduced into it and / or water repellent additives.

 When filling the cavities of the screen elements with hardening material with an element length of 20 m or more, the hardening material can be laid in layers with a corresponding increase in the number of layers and the number of nozzles for supplying the hardening material.

 When filling the cavities of the screen elements with hardening material, before the supply of hardening material, the cavities of the screen elements from the ends can be covered with plugs, and, at least from the supply side of the hardening material, the cavity of the element is connected with the atmosphere, and holes for the nozzles are made in the plug on the supply side of the hardening material for supplying hardening material. Moreover, in the plug at the end of the screen element that is remote from the supply side of the hardening material, holes can be made to control the level of filling the cavity with hardening material, the number of holes corresponding to the number of nozzles, and these holes are closed with removable plugs.

 The development of the soil in each tier can be done by approaches with the installation of frames supporting the screen in each approach to the height of the tier and the subsequent development of the lower tier after the penetration and unfastening of the upper tier for the entire length of the tunnel.

 The soil can be fixed by injecting fixing materials, mainly synthetic resins, and / or their solutions, and / or cement mortars, and / or polymer-cement mortars.

 The injection of fixing materials into the soil can be done by impregnation, and / or in the mode of hydraulic fracturing, and / or using inkjet technology.

 The soil of the foundation, at least of the launching pit, before the installation of the micro-shield complex can be fixed by performing a pile foundation, mainly from bored, including cement-cement piles, and during the construction of the lining it may include a screen, reinforcing elements of the frame screen and filling between them.

 Frames can be single-span or multi-span, with racks and beams made in the form of a closed, or open, and / or combined profiles of rolled, and / or bent, and / or welded, and / or tubular elements, and overlap, walls and tray tunnels can be made with a thickness ratio of 1: (0.7-1.2) :( 0.5-0.9), piles with a diameter of 600-1000 mm with a length of 10-16 m, and screen elements with with a diameter of 800-1400 mm.

 At least during the development of the ground, the first calls can monitor the loads perceived by the frame elements providing temporary fastening, while developing the soil in the internal volume of the tunnel, surveying observations of soil deformations and highly accurate leveling of the position of the screen elements at the extreme and middle points of each frame at all stages of soil development, according to monitoring, refine the calculated parameters of the soil and frame elements, and then repeat the calculation modeling of the soil development process and upon receipt of satisfactory results, the adjusted design parameters are taken for further work.

 The technical result provided by the invention is to increase the reliability and safety of the development of previously fixed by injection of soil during the construction of the tunnel under the highway without interruption in difficult mining and geological conditions, including in the presence of weak flooded soils at the base of the tunnel due to exceptions for the development of sediments of the base of the tunnel and day surface to values exceeding permissible values, as well as a decrease in energy intensity, labor and material the cost due to the optimization of the process of injection fixation of the soil.

The invention is illustrated by drawings, where
in FIG. 1 shows a schematic longitudinal section of a soil massif in a tunnel location zone;
in FIG. 2 - cross section of a tunnel with a protective screen and pile base;
in FIG. 3 - section along aa in figure 1, the stage of fixing the soil of the upper tier;
figure 4 is a section along BB in figure 1, the stage of fixing the soil of the lower tier;
figure 5 - node In figure 2;
Fig.6 is a fragment of the screen and its supporting frames in the upper tier, a cross section;
Fig.7 is a view along DD in Fig.6;
on Fig - node supporting the intermediate rack of the frame on additional elements, a cross section;
Fig.9 is a view along EE in Fig.8;
figure 10 - node G in figure 2;
figure 11 is a view along FJ in figure 10.

 The method of erecting the tunnel 1 includes forming a protective screen 2 in the soil, injecting the soil in the internal volume 3 of the future tunnel 1 and outside it with the formation of injection piles 4 under the base 5 of the tunnel 1, the subsequent development of the fixed soil in the internal volume 3 of the future tunnel 1 and building the lining 6. The fastening and development of the soil is done in tiers 7, 8 with the formation of a leading overlying ledge and at least one, located in height below the overlying 7 underlying tier 8, while two injection injection 9 soil fixation in the zone of the overlying layer 7 is performed with the formation of a reinforced soil structure with compressive strength exceeding the compressive strength of the reinforced soil structure of the underlying layer 8.

 The reinforced soil structure of the overlying tier 7 can be performed with compressive strength exceeding the compressive strength of the reinforced soil structure of the underlying tier 8 by at least 5%.

 Before the construction of tunnel 1, start and receiving pits (not shown) can be made, a micro-shield complex (not shown) is mounted in the start pit, with the help of which a protective screen 2 is formed in the ground by forcing in the ground at least over the overlap 10 of the constructed tunnel 1 from the starting pit to the receiving (not shown) closed or open (not shown) in the cross section of extended metal elements with locking joints 12 between adjacent elements 11. At the same stage, it is punched dissolved in the ground within the contour of the tunnel further hollow metal elements 13 that are closed in cross-section for supporting the screen 2 reinforcement frames 14 which are mounted at least a pre-fixed tiered design soil.

 A protective screen 2 can be formed around the entire perimeter of the constructed tunnel 1 in a sequence from the bottom up, with the elements 11 of the chute part 15 of the protective screen 2 being pushed first using a stationary stop (not shown). A squeezing device (not shown) is installed directly on the bottom of the starting pit (not shown) with a shield inset (not shown) into the ground when the first elements 11 of screen 2 are pushed through a concrete retaining wall (not shown), and the subsequent ones through fixed piles (not shown) ) and a metal sheet (not shown) a dirt wall. The pushing of the elements 11 of the screen 2 in the zone of walls 16 of the constructed tunnel 1 is carried out with an inset of a shield (not shown) into the ground through concrete retaining walls (not shown), fixed by piles (not shown) from pipes and a wooden block (not shown), followed by installation of a punching device (not shown) on an inventory changeable frame (not shown in the drawings), which is installed on previously shrunken and extended elements 11 of the protective screen 2. The pushing of the elements 11 of the protective screen 2 in the overlap zone 10 of the tunnel 1 is carried out they are inserted with a shield insert (not shown) into the ground through an earth retaining wall (not shown in the drawings), fixed with longitudinal metal beams (not shown) and a wooden block (not shown). Moreover, metal beams (not shown) are used as guides for the shield (not shown in the drawings), and a punching device (not shown) is installed on the site (not shown), which is erected on the elements 11 of the screen 2 previously sold in the wall area 16 with their building up.

 The protective screen 2 is made of metal pipes, mainly circular, including rolled, and / or welded, and / or cold drawn, and / or brazed along the seam, and / or seamless, and / or spiral-seam. And the lock connections 12 are made in the form of forming a lock, welded on facing each other surfaces of adjacent elements 11 of the screen 2, two extended elements 17, 18, one of which 17 is made C-shaped in cross section, and the other 18 - in the form wound in walls with a broadening 19 located on the free edge that is wider than the width of the C-shaped alignment in the cross section of the element 17.

 After punching in the soil of each element 11 of the screen 2, the cavity 20 of the element 11 is filled with hardening material, which can be used concrete or polymer concrete.

 The filling of the cavity 20 of each element 11 of the protective screen 2 is performed with reinforcement (not shown).

 Reinforcement is performed by frames, and / or individual rods, and / or nets, and / or with the inclusion of rolling profiles, and / or using rod structures such as flat or spatial trusses (not shown).

 At least a portion of the surfaces of the elements 11 of the screen 2 are coated with a protective coating (not shown) before being pressed.

 The filling of the cavities 20 of the elements 11 of the screen 2 is carried out by layer-by-layer laying of the material in a low-pressure mode using self-laying material.

 When concreting the cavities 20 of the elements 11 of the screen 2, a concrete or polymer concrete mixture is pumped (not shown) to ensure its movement under the influence of gravitational forces and a slope of up to 2%, and a highly thixotropic self-stacking mixture with a standard cone draft of at least 18 cm is used.

 When using a concrete mixture, superplasticizing and / or hydrophobizing additives are introduced into it.

 When filling the cavities 20 of the elements 11 of the screen 2 with hardening material with an element length of 20 m or more, the hardening material is laid in layers with a corresponding increase in the number of layers and the number of nozzles for supplying hardening material (not shown).

 When filling the cavities 20 of the elements 11 of the screen 2 with hardening material before starting the supply of hardening material, the cavities 20 of the elements 11 of the screen 2 are closed from the ends with plugs (not shown), and at least from the supply side of the hardening material, the cavity 20 of the element 11 is connected with the atmosphere, moreover in the plug (not shown in the drawings) on the supply side of the hardening material, holes (not shown) are made for the nozzles for supplying the hardening material (not shown in the drawings).

 In the plug (not shown) at the end of the element 11 of the screen 2 remote from the supply side of the hardening material, holes (not shown) are made to control the filling level of the cavity 20 with hardening material, and the number of holes (not shown) corresponds to the number of nozzles (not shown), when this, these holes are closed with removable plugs (not shown in the drawings).

 The development of the soil in each tier 7, 8 is carried out by approaches with the installation in each approach to the height of the tier 7, 8 of the reinforcing screen 2 of the frame 21 and the subsequent development of the lower tier 8 after the penetration and unfastening of the upper tier 7 for the entire length of tunnel 1.

 The soil is fixed by injecting fixing materials, mainly synthetic resins, and / or their solutions, and / or cement mortars, and / or polymer-cement mortars.

 The fixing materials are injected into the soil by impregnation, and / or in hydraulic fracturing mode, and / or using inkjet technology.

 The ground of the foundation, at least of the starting pit (not shown) before the installation of the micro-panel complex (not shown), is fixed by making a pile foundation (not shown), mainly from bored, including cement-cement piles (not shown in the drawings).

 When erecting the lining 6, it includes a screen 2, reinforcing elements 11 of the screen 2 of the frame 14 and the filling between them.

 Frames 14 are single-span or multi-span, with uprights 22 and beams 23 made in the form of closed, or open, and / or combined profiles of rolled, and / or bent, and / or welded, and / or tubular elements.

 Overlap 10, walls 16 and tray 24 of tunnel 1 are performed with a ratio of thicknesses 1: (0.7-1.2) :( 0.5-0.9), piles 4 with a diameter of 600-1000 mm with a length of 10 -16 m, and the elements 11 of the screen 2 - with a diameter of 800-1400 mm.

 At least, during the development of the ground of the first approaches, the loads perceived by the elements 22, 23 of the frame 14 are monitored, providing temporary fastening during the development of the soil in the internal volume of 3 tunnels 1, surveying observations of soil deformations and high-precision leveling of the position of the elements 11 of screen 2 in the extreme and the midpoints of each frame 14 at all stages of soil development, according to monitoring data, the design parameters of the soil and elements 22, 23 of the frames 14 are refined, and then the design simulation of the development process is repeated ki soil and upon receipt of satisfactory results specified design parameters to take further production operations.

Claims (24)

 1. A method of erecting a tunnel, including the formation of a protective screen in the soil, injection fixing the soil in the internal volume of the future tunnel and outside it with the formation of injection piles under the base of the tunnel, the subsequent development of fixed soil in the internal volume of the future tunnel and the construction of the lining, characterized in that the fixing and the development of soil is carried out in tiers with the formation of a leading overlying ledge and at least one, located in height below the overlying, underlying tier, In this case, preliminary injection fixation of the soil in the zone of the overlying layer is performed with the formation of a reinforced soil structure with a compressive strength exceeding the compressive strength of the reinforced soil structure of the underlying layer.  2. The method according to p. 1, characterized in that the reinforced soil structure of the overlying layer is performed with compressive strength exceeding the compressive strength of the reinforced soil structure of the underlying layer by at least 5%.  3. The method according to any one of paragraphs. 1 and 2, characterized in that before the construction of the tunnel, start and receiving pits are made, a micro-shield complex is installed in the starting pit, with the help of which a protective screen is formed in the ground by forcing in the ground, at least over the overlap of the tunnel being built from the starting pit in receiving closed or open in cross section extended metal elements with locking joints between adjacent elements, and at the same stage they push through the ton inside the contour I further hollow metal elements, closed in cross-section for supporting the screen reinforcing frames that set as a tiered development previously grouting.  4. The method according to any one of paragraphs. 1-3, characterized in that the protective screen is formed around the entire perimeter of the tunnel being constructed in a sequence from the bottom up, with the elements of the tray part of the protective screen being pushed first using a stationary stop, the punching device being installed directly on the bottom of the launching pit with a shield inset in the ground punching the first screen elements through the concrete retaining wall, and the subsequent ones through the soil wall fixed by piles and metal sheet, punching the screen elements in One of the walls of the constructed tunnel is made with an inset of the shield into the ground through concrete retaining walls, fixed with piles of pipes and a wooden block, followed by installation of the punching device on the inventory interchangeable frame, which is installed on previously shipped and extended elements of the protective screen, and the forcing of the elements of the protective screen in the area the overlap of the tunnel is carried out with an inset of the shield into the ground through the soil retaining wall, fixed with longitudinal metal beams and a wooden block, and llicheskie beams are used as guides for the panel and for punching device is mounted on a platform which is erected on the previously sagging in the region of the screen wall elements with their capacity.  5. The method according to any one of paragraphs. 1-4, characterized in that the protective shield is made of metal pipes, mainly circular cylindrical, including rolled, and / or welded, and / or cold drawn, and / or brazed along the seam, and / or seamless, and / or spiral-seam, and lock joints in the form of a lock welded on facing surfaces of adjacent screen elements of two extended elements, one of which is made C-shaped in cross section, and the other in the form of a wall wound into it with a broadening located on the free edge, exces the width of the cross section of the C-shaped element in the cross section.  6. The method according to any one of paragraphs. 3-5, characterized in that after punching in the soil of each element of the screen, the cavity of the element is filled with hardening material.  7. The method according to p. 6, characterized in that the cavity of each element of the screen is filled with concrete or polymer concrete.  8. The method according to any one of paragraphs. 6 and 7, characterized in that the filling of the cavity of each element of the protective screen is performed with reinforcement.  9. The method according to p. 8, characterized in that the reinforcement is performed by frames, and / or individual rods, and / or nets, and / or with the inclusion of rolling profiles, and / or using rod structures such as flat or spatial trusses.  10. The method according to any one of paragraphs. 3-9, characterized in that at least part of the surface of the screen elements before punching is coated with a protective coating.  11. The method according to any one of paragraphs. 6-9, characterized in that the filling of the cavities of the screen elements is produced by layer-by-layer laying of the material in a low-pressure mode using a self-stacking material.  12. The method according to any one of paragraphs. 7-11, characterized in that when concreting the cavities of the screen elements, a concrete or polymer concrete mixture is pumped to ensure its movement under the influence of gravitational forces and a slope of up to 2%, and a highly thixotropic self-stacking mixture with a standard cone draft of at least 18 cm is used.  13. The method according to p. 12, characterized in that when using a concrete mixture, superplasticizing and / or hydrophobizing additives are introduced into it.  14. The method according to any one of paragraphs. 6-13, characterized in that when filling the cavities of the screen elements with hardening material with an element length of 20 m or more, the hardening material is laid in layers with a corresponding increase in the number of layers and the number of nozzles for supplying hardening material.  15. The method according to any one of paragraphs. 6-14, characterized in that when filling the cavities of the screen elements with hardening material before the supply of hardening material, the cavities of the screen elements from the ends are covered with plugs, and at least from the supply side of the hardening material, the cavity of the element is communicated with the atmosphere, and in the plug from the side hardening material supply openings for nozzles for supplying hardening material.  16. The method according to p. 15, characterized in that in the plug on the end of the hardening material end face of the screen element, holes are made to control the level of filling the cavity with hardening material, the number of holes corresponding to the number of nozzles, and these holes are closed with removable plugs.  17. The method according to any one of paragraphs. 1-16, characterized in that the development of the soil in each tier is performed by approaches with the installation of frames supporting the screen in each approach to the height of the tier and the subsequent development of the lower tier after driving and unfastening the upper tier for the entire length of the tunnel.  18. The method according to any one of paragraphs. 1-17, characterized in that the fixing of the soil is carried out by injection of fixing materials, mainly synthetic resins, and / or their solutions, and / or cement mortars, and / or polymer-cement mortars.  19. The method according to p. 18, characterized in that the injection of fixing materials into the soil is carried out by impregnation, and / or in the mode of hydraulic fracturing, and / or using inkjet technology.  20. The method according to any one of paragraphs. 2-19, characterized in that the soil of the base, at least of the starting pit, before the installation of the micro-panel complex is fixed by making a pile foundation, mainly from bored, including cement-cement piles.  21. The method according to any one of paragraphs. 3-20, characterized in that during the construction of the lining, a screen is included in it, reinforcing elements of the frame screen and filling between them.  22. The method according to any one of paragraphs. 3-21, characterized in that the frames are single-span or multi-span, with uprights and beams made in the form of a closed or open and / or combined profiles of rolled and / or bent and / or welded and / or tubular elements.  23. The method according to any one of paragraphs. 5-22, characterized in that the overlap, walls and the tunnel tray are performed with a ratio of thicknesses 1: (0.7-1.2): (0.5-0.9), piles with a diameter of 600-1000 mm with a length of 10-16 m, and screen elements with a diameter of 800-1400 mm.  24. The method according to any one of paragraphs. 3-23, characterized in that, at least when developing the ground of the first passages, they monitor the loads perceived by the frame elements providing temporary fastening, while developing the ground in the internal volume of the tunnel, surveying observations of ground deformations and highly accurate leveling of the position of the screen elements in the extreme and middle points of each frame at all stages of soil development, according to monitoring data, specify the design parameters of the soil and frame elements, and then repeat the calculation modeling of the process soil development and upon receipt of satisfactory results, the adjusted design parameters are accepted for further work.

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