RU2152470C1 - Method for erection of urban ring highway section megapolis - Google Patents

Abstract

FIELD: highway engineering, applicable in construction or reconstruction of road junctions at different grades of trunk highways in the conditions of narrow urban building. SUBSTANCE: the method consists in construction of the surface section, motor-road tunnel and at least one junction of ring highway with a radial highway. The novelty is in the fact that the tunnels are arranged in the axis of the ring highway and made in length with two sections curvilinear in plan, facing the opposite sides with the convex part, and formation of the middle rectilinear section located between them, and rectilinear terminal sections; the angle between the axis of one rectilinear terminal section and the axis of the middle rectilinear section is taken to be equal to 39 to 47 deg., and the angle between the axis of the other rectilinear terminal section and the axis of the middle rectilinear section - 23 to 31 deg. , and the junction of ring and radial highways is made at different grades; the radial highway at erection of the ring highway is arranged at the surface level, and the roadbed of the junction of the ring highway with the radial one is positioned on an overpass that is erected in the axis of the ring highway, and the roadways of the overpass and tunnel are conjugated with the surface section. EFFECT: reduced labour and material costs and scope of excavation at simultaneous provision of a high prevented jammings on motor roads, deformations of overground structures and improved ecology. 18 cl, 11 dwg

Description

 The invention relates to road construction and can be used in construction or reconstruction in the conditions of close urban development of intersection nodes at different levels of highways.

 The closest to the invention in its essence and the achieved result is a method of erecting a section of an inner-city ring transport highway of a metropolis, including the construction of a land section, a road tunnel and at least one intersection of a ring highway with a radial highway (see, for example, Makarov O.N., Vlasov SN "Underground transport systems in a big city". Transport construction, 1999, N 1, p. 2-6).

 A disadvantage of the known solution is the unacceptability for construction in conditions of close urban development, the presence of numerous underground utilities, to avoid the intersection of which significant land acquisition is required.

 The objective of the present invention is the creation of an inner-city high-speed ring highway in a metropolis under close urban development, the presence of nearby historical and architectural monuments and numerous nearby underground communications, while ensuring high traffic capacity and traffic safety, eliminating the formation of traffic jams due to the optimal redistribution of traffic flows, deformation of ground structures and improving the environmental situation.

The problem is solved due to the fact that in the method of constructing a section of an intracity ring transport highway of a metropolis, including the construction of a land section, a road tunnel and at least one intersection of a ring highway with a radial highway, according to the invention, the tunnel is arranged along the axis of the ring highway and is performed along two curvilinear in plan, facing the convex part in opposite directions and forming the middle straight section located between them straight end portions, the angle between the axis of the straight end portion and the axis of secondary rectilinear portion is determined to be 39-47 ^o, and the angle between the axis of the other end portion of rectilinear axis and secondary rectilinear portion - 23-31 ^o, and the intersection of the annular and radial lines operate at different levels, and the radial highway during the construction of the site is located at the ground level, and the roadway intersection of the ring highway with the radial is located on the overpass, which is built on ring main and roadways and overpasses ground portion of the tunnel match.

 Moreover, the middle straight section and at least part of at least one of the curved sections can be performed in a closed way by forming a closed method of work at one end of the section in the area of the smaller of the above angles of two mounting chambers, and at the other end There are two dismantling chambers that carry out the section of the closed method for performing the work, the installation is carried out in the left mounting chamber of the shield tunneling complex with closed chest and hydraulic loading of the face and sinking from this mine installation chamber of the left tunnel to the left dismantling chamber, dismantling the shield tunnel complex in it, transporting it to the right mounting chamber, re-installing the shield tunnel complex in it, and then tunneling the right tunnel in the direction from the right mounting chamber to the right dismantling chamber, where they dismantle paneling complex, while the erection of the load-bearing structures of the carriageway and the false ceiling in the left tunnel is carried out after the completion of the tunnel, and the erection The existing constructions of the carriageway and the false ceiling in the right tunnel are conducted as it is drilled.

 They can use a shield tunneling complex with hydraulic loading of the face of the firm "Herennknecht" with a diameter of 14.23 m, a total length of 61 m, including a head part 12.8 m long with a rotary working body equipped with cutters for breaking hard rocks, cutters for soft soils, a stone crusher for grinding individual boulders up to 1.2 m in size, a hydrotransport system with a slurry conduit for dispensing soil from the bottom to the surface, located on the surface by a separation station for separating soil from the solution used for sinking entonitovoy clay, which is fed into the bottom chamber under controlled pressure, which is carried out when driving the automatic movement of the shield tunneling system using ultrasonic and laser pointing location intelligence boulders and other large inclusions at a distance of 50 m from the face.

 Mounting and dismantling chambers can be performed in pits with a depth of 29.5 m and 25.9 m, respectively, with a width of 24.3 m, a length of 42.7 m and 49 m, respectively, using temporary enclosing structures of the walls of the pit in the form of walls of bored piles with a diameter of 750 mm with fixing the walls as excavation is carried out by anchors and shootings and the execution of an anti-filtration curtain along the contour of the pit.

 During the assembly and installation of the shield tunneling complex, metalwork can be mounted in the mounting chamber, transmitting force from the shield jacks when the complex moves to the chamber tray and the reinforced concrete beams, and after setting up the complex and enclosing the cutting part of the rotor in the sealing ring holder, the hydrotransport system of the complex with a load face at low pressure, mainly 0.5-1.0 atm, which is maintained until the shell of the head of the complex enters the soil at a calculated distance for and preventing the bentonite solution from breaking into the installation chamber through a sealing ring or soil mass, as well as preventing the formation of an air "bag" that can overcome hydrostatic pressure and rise to the surface, which is carried out by creating 12 meters in the direction of penetration before starting the installation chamber and a width of 20 m of a fixed soil mass in the form of a closed loop along the width of the chamber and a length of 15 m from bisected piles with its subsequent drainage or from a chemically fixed soil through the boreholes drilled from the surface of the well, and to advance the head of the complex in the mounting chamber, temporary lining rings are installed that transmit the force from the shield jacks to the supporting metal structure, and after the first 13 m of the complex has been driven and the rotor of the complex has been removed from the fixed soil mass to unstable soils, the hydraulic pressure increase to the required value and turn on the cement injection system for lining, after which the first 200 m of the tunnel pass and during this period work is carried out, associated with the deployment of the complex, which include the installation of technological platforms, hydrotransport systems and refinement of technologies to design parameters, and after driving the first 100 m and perceiving pressure from the shield jacks by friction between the lining and the rock, the temporary supporting structures in the assembly chamber are disassembled and further tunneling, and on approach to the dismantling chamber, the output of the complex is carried out in a pre-prepared array 10 m long and 17 m high, which is made from concrete within the dismantling chamber.

 When driving in a closed way, scheduled shutdowns of the complex can be carried out to replace roller cutters and cutters, which is carried out during the transition from some geological conditions to others and in the central sections of the tunnels, and during shutdowns of the complex, the bentonite solution is maximally downloaded, the pressure in the caisson chamber is reduced and they change the cutting tool on the rotary organ from the side of the tunnel, and after driving the first tunnel - the left one carries out preventive sanitation of the complex with the replacement whole cutting tool.

 Between the left and right tunnels with a step of 360 m in the level of the bottom of the tray and the carriageway, connection workings can be performed in the form of two-story discharges of the adit type with the outer dimensions: 3.2 m wide, about 8 m high and 14 m long, and in two failures the chambers of the drainage plants with a length of 20 m are made in cast iron elliptical lining with the largest dimensions of 7x8 m, and the workings for the drainage installations are located between the tunnels perpendicular to the failures with the formation of drainage chamber chambers between the tunnels to the rock pillar 3 m wide, and on four faults, electrical switchboard chambers are made in cast-iron lining with a diameter of 6 m, and the excavations for these chambers 11 m and 12 m long are placed between the tunnels perpendicular to the faults with the formation between the tunnels and the switchboard chambers of the rock pillar 4 m wide moreover, the implementation of failures and chambers begins after the first tunnel is left - the tunnel is left and is produced with the simultaneous transportation of soil, delivery of materials and structures along the retraction paths that are laid during the tunneling lei, and during the tunneling period, temporary welded metal elements filled with concrete are installed in the places of breakdowns in the lining, through which wells are drilled from the right and left tunnels and cemented the surrounding rock mass, then the filling concrete is removed and malfunctioned by small-scale mechanization, and before tunneling of the chambers is carried out from the completed fault, and after the second tunnel, the right one, the work is carried out to connect the fault to the constructed tunnel, similar to the adjacent ju failures to the first tunnel.

 They can use a shield tunnel complex, the hydrotransport system of which includes a separation complex and pumping facilities with intermediate pumps and pipelines, and the separation complex is equipped with cleaning and separating devices for separating and regenerating soil - vibrating screens, cyclones and centrifuges.

 The pulp-soil coming from the tunneling, mixed with an aqueous solution of bentonite clay, can be subjected to separation, during which large limestone fractions from 30 to 50 mm in size are separated, then bentonite clay is separated from the soil in a centrifuge, after which incoherent soils are sand, sandy loam , limestone is divided into fractions on grids - grids depending on size from 5 to 30 mm, and cohesive soils - Jurassic clay, marls and carbon clay are additionally dehydrated on sieves, the bentonite suspension purified from the soil is fed into tanks and after control, a suitable suspension is enriched with fresh bentonite and sent back to the hydrotransport system of the shield tunneling complex, and unsuitable - to a centrifuge, where it is separated into water and clay material, after which the purified water is used in the hydrotransport system or sent to the gutters of the metropolis, and clay the material is moved to the permanent dump site, and the cleaned soil from the separation chamber is sent to the intermediate dump site in the gallery, which is equipped with a conveyor, after four first, the soil is moved to the place of an intermediate or permanent dump in accordance with the transport scheme of soil removal.

 The pumps of the pumping facilities can be connected with each other by slurry pipelines, and bentonite mortar is supplied through pipelines from the separation complex to the shield tunneling complex, and a bentonite-soil mixture is supplied from the shield tunneling complex to the separation complex, while the pipelines are extended along the length during the sinking, centrifugal pumps for supply of bentonite solution and pumping pulp are placed on the shield tunneling complex, in the tunnel and on the surface, while four intermediate pumps are pumped pulp are placed in the tunnel at a distance of 1200 m from each other, and three intermediate pumps pumping the bentonite solution are placed in the tunnel and at the shield tunnel complex at a distance of 1800 m from each other.

The lining of tunnels covered by a closed method can be performed by a team of rings with a diameter of 13.75 m, a width of 2 m and a thickness of 0.7 m, and each ring can be made up of 6 normal, 2 adjacent and 1 castle reinforced concrete blocks which are made in the form of segments of different lengths and mounted in a tunnel at a temperature of at least 10 ^° C with dressing of the joints in adjacent rings and the establishment of connections between blocks in the ring and between adjacent rings.

 The supporting structures of the carriageway of the tunnels can be constructed at a distance of 300-400 m from the bottom using a gantry crane with a lifting capacity of 20 tons, a length of 6.2 m and a cantilever jib boom of 3.2 m, which is supported on the side structures of the carriageway, which are erected with approaches of 6 m using the cantilever boom of the crane, and after 24 hours after the concrete constructions are completed and the crane rail is completed, the crane is moved to the finished side parts of the supporting structures, and the suspended ceiling of monolithic reinforced concrete is mounted on metal cords, which are screwed into the embedded parts of the lining in the arched part of the tunnel, and work on the erection of a suspended ceiling is carried out 550-650 m from the bottom using mobile scaffolding 6 m long, which are used as formwork for concrete and reinforcing works.

 After the carriageway and the suspended ceiling are completed, internal tunnel structures can be constructed from fireproof plates made of basalt fiber, which are built simultaneously by several teams in areas free of temporary communications, and the completion of the internal tunnel structures is completed after dismantling all temporary communications in the tunnel.

 The implementation of the roadway of the carriageway can be performed after continuous ventilation of the tunnels.

 Extremely straight sections, including ramp sections, and at least part of one of the curved sections of tunnels and ramps of ramps with their ramp sections can be erected in open pits in pits with fastening in the form of a “wall in the ground” from bisected piles, and as the soil develops carry out the anchoring of the "wall in the ground" with soil anchors to remove the developed soil by excavators into dump trucks and through the portal to the surface, and after completion of the excavation, the foundation is waterproofed, they add reinforcement, concreted the bottom of the permanent structures, then gradually erect the permanent walls and the overlap of the tunnel, complete the waterproofing and backfill.

 Excavations for mounting and dismantling chambers can be performed in an open way in pits with fastening in the form of a “wall in the ground” from bisected piles and additional antifiltration walls, which are carried out in a closed circuit and closed into a water seal.

 When tunneling excavations in flooded limestones, they can be cemented to reduce water inflows, strengthen the fractured massif and eliminate the likelihood of development of karst phenomena, and when drilling, at least in some areas, the rocky soil is loosened by explosive method with small-hole charges of limited mass with a seismic design zone exposure no more than 5 m.

 In the process of erecting a tunnel-type overpass, they can protect buildings and structures of a metropolis located near the construction zone by installing clips and metal strands in the protected objects, making injection piles under the protected objects, performing local cementation of foundations and the foundation-ground contact zone using constantly operating injectors, compensatory injection of one or more shafts under the protected objects, installation of metal frames and screeds in the basement of the protected objects, laying brickwork of openings.

 The technical result provided by the specified set of features is to reduce labor and material costs and the volume of earthwork during the construction of the intracity ring highway of the metropolis in the conditions of close urban development, the presence of nearby historical and architectural monuments and numerous underground utilities, while ensuring high throughput and traffic safety, elimination of traffic congestion, deformation of ground structures and ulu shenii environmental conditions.

The invention is illustrated by drawings, where:
in FIG. 1 shows a route of a tunnel section of an intracity expressway in plan;
in FIG. 2 is a section of a closed method of work, a view along BB in FIG. 1;
in FIG. 3 is a view along BB in FIG. 1 (for water treatment plant);
in FIG. 4 is a view along DG in FIG. 1 (on step-down substation);
in FIG. 5 is a DD view of FIG. 1 (in the dismantling chamber);
in FIG. 6 is a view along EE in FIG. 1 (for emergency recovery);
in FIG. 7 - reinforced concrete lining ring section of the closed method of work, cross section;
in FIG. 8 is a cross-section along II in FIG. 7;
in FIG. 9 - one of the end sections of the tunnel section, plan view;
in FIG. 10 - another end section of the tunnel section, plan view;
in FIG. 11 - sectional view of a tunnel with a ventilation chamber.

 The method is as follows.

The tunnels 1 are arranged along the axis of the annular 2 highway and run along the length with two curved in plan, convex parts in opposite directions to sections 3, 4 and the formation of the middle straight section 5 located between them and the straight end sections 6, 7. The angle between the axis of one rectilinear end section 6 and the axis 8 of the middle straight section is taken equal to 39-47 ^o , and the angle between the axis of another straight end section 7 and the axis 8 of the middle straight section is 23-31 ^o . The intersection of the annular 2 and radial 9 highways is performed at different levels. The radial highway 9 during the construction of the section is located at the ground level, and the roadway 10 of the intersection of the ring 2 highway with the radial 9 is located on the overpass 11, which is erected along the axis of the ring 2 highway, and the carriageways of the overpass 11 and tunnel 1 are mated to the ground section 12.

 The middle straight section 5 and at least part of at least one of the curved sections 3 or 4 are performed in a closed way by forming at one end of the section a closed method of work in the area of the smaller of the above angles of two mounting chambers 13. On the other at the end of the closed method section, two dismantling chambers 14 are installed. Installation is carried out in the left mounting chamber 13 of the shield tunneling complex with closed chest and hydraulic load (not shown in the drawings) of the face and I carry out driving from this mounting chamber 13 of the left tunnel 1 to the left dismantling chamber 14, dismantling the shield tunnel complex in it, transporting it to the right mounting chamber 13, re-installing the shield tunnel complex in it, and then driving the right tunnel 1 in the direction from the right mounting chamber 13 to the right dismantling chamber 14, where the shield tunnel complex is dismantled. The erection of the load-bearing structures of the carriageway 15 and the suspended ceiling 16 in the left tunnel 1 is carried out after the completion of the tunneling, and the erection of the load-bearing structures of the carriageway 15 and the false ceiling 16 in the right tunnel 1 is carried out as it is drilled.

 Use a shield tunneling complex with hydraulic loading of the face of the firm "Herennknecht" with a diameter of 14.23 m, a total length of 61 m, including a head part 12.8 m long with a rotary working body equipped with cutters for breaking hard rocks, cutters for soft soils, stone crusher for grinding individual boulders up to 1.2 m in size, a hydrotransport system with a slurry pipeline for dispensing soil from the bottom to the surface located on the surface by a separation station to separate the soil from the bentonite used during the sinking new clay, which is fed into the bottomhole chamber under controlled pressure. When driving, automatic movement of the shield tunneling complex is carried out using laser guidance and ultrasonic reconnaissance of the location of boulders and other large inclusions at a distance of 50 m from the bottom (not shown in the drawings).

 Mounting 13 and dismounting 14 chambers are performed in pits with a depth of 29.5 m and 25.9 m, a width of 24.3 m, a length of 42.7 m and 49 m, respectively, using temporary enclosing structures of the walls of the excavation in the form of walls made of bored piles ( not shown in the drawings) with a diameter of 750 mm with fixing the walls as excavation was carried out by anchors and executions (not shown in the drawings) and performing an anti-filter curtain along the contour of the foundation pit (not shown in the drawings).

 During the assembly and installation of the shield tunneling complex, the metal structure 17 is mounted in the mounting chamber, transmitting force from the shield jacks (not shown in the drawings) when the complex moves to the camera tray 18 and supporting reinforced concrete beams (not shown in the drawings). After setting up the complex and enclosing the cutting part of the rotor in a sealing ring cage (not shown in the drawings), the hydrotransport system (not shown in the drawings) of the complex is loaded with a bottom face load under low pressure, mainly 0.5-1.0 atm, which is retained until the moment of insertion the shell of the head part of the complex (not shown in the drawings) into the soil at a calculated distance to prevent breakthrough of the bentonite solution into the mounting chamber 13 through a sealing ring (not shown in the drawings) or a soil mass, as well as preventing formation of an air "bag" that can overcome hydrostatic pressure and rise to the surface, which is carried out by creating a fixed soil mass in the form of a closed loop along the width of the chamber and the length before driving in front of the mounting chamber 13 in the direction of penetration at a length of 12 m and a width of 20 m 15 m from bisected piles (not shown in the drawings) with its subsequent drainage or from chemically fixed soil through wells drilled from the surface (not shown in the drawings). To advance the head of the complex in the mounting chamber 13, temporary lining rings are installed (not shown in the drawings), which transmit the force from the shield jacks to the supporting metal structure 17. After driving the first 13 m and removing the rotor of the complex from the fixed soil mass into unstable soils, the hydraulic load is increased to of necessary value and include a cement injection system for lining, after which the first 200 m of the tunnel pass and during this period they perform work related to the deployment of ca, among which include the installation of technological platforms (not shown), hydraulic transport system (not shown) and finishing technologies to design parameters. After driving the first 100 m and perceiving the pressure from the shield jacks by the forces of friction between the lining and the rock, the temporary supporting structures in the mounting chamber 13 are disassembled and further tunneling is carried out. On the approach to the dismantling chamber 14, the output of the complex is carried out in a pre-prepared array of 10 m long and 17 m high, which is made of lean concrete within the dismantling chamber 14.

 When driving in a closed way, planned shutdowns of the complex are carried out to replace cones and cutters (not shown in the drawings), which is carried out during the transition from one geological condition to another and in the central sections of the tunnels. During the shutdowns of the complex, the bentonite solution is maximally downloaded from the bottomhole zone, the pressure in the caisson chamber (not shown in the drawings) is reduced, and the cutting tool is changed on the rotor body from the tunnel side, and after the first tunnel - left 1 is excavated, the complex is rehabilitated with the whole replaced cutting tool.

 Between left and right tunnels 1 with a step of 360 m at the level of the bottom of the tray 18 and the carriageway 15, connecting workings 19, 20 are made in the form of two-story discharges of an adit type with the external shape: 3.2 m wide, about 8 m high and 14 m long The chambers of 21 drainage plants with a length of 20 m long in cast iron elliptical lining with the largest dimensions of 7x8 m are made at two faults. Excavations of 19, 20 are placed between tunnels 1 perpendicular to the faults with the formation between the tunnels of 22 tunnels 1 chambers of drainage plants of a natural rear pillar 3 m wide, and on four faults electrical switchboard chambers 23 are made in cast-iron lining 24 with a diameter of 6 m. The excavations for these chambers 11 m and 12 m long are placed between tunnels 1 perpendicular to the faults with the formation of a 25th wide polar pillar between tunnels and switchboard chambers 4 m. Failures and chambers are started after the first tunnel is drilled - left 1 and produced with the simultaneous transportation of soil, delivery of materials and structures along the retraction paths that are laid during tunneling. During the tunneling period, temporary welded metal elements filled with concrete (not shown in the drawings) are installed in the lining places in the lining, through which wells are drilled from the right 1 and left 1 tunnels (not shown in the drawings) and the surrounding rock mass is cemented, then removed concrete is filled and pass through by means of small-scale mechanization. Before tunneling the chambers, cementation is carried out from the completed fault, and after the second tunnel - right 1 is driven, work is carried out to adjoin the fault to the constructed tunnel, similar to work on adjoining the fault to the first tunnel.

 A shield tunneling complex is used, in the hydrotransport system of which they include a separation complex and pumping facilities with intermediate pumps and pipelines. The separation complex is equipped with cleaning and separating devices for the separation and regeneration of the soil - vibrating screens, cyclones and centrifuges (not shown in the drawings).

 The pulp-soil coming from the tunneling, mixed with an aqueous solution of bentonite clay, is subjected to separation, during which large limestone fractions from 30 to 50 mm in size are separated, then bentonite clay is separated from the soil in a centrifuge, after which incoherent soils are sand, sandy loam, limestone is divided into fractions on grids - grids depending on size from 5 to 30 mm, and cohesive soils - Jurassic clay, marls and carbon clay are additionally dehydrated on sieves, the bentonite suspension purified from the soil is fed to the cutter after control, the voyars are enriched with a suitable suspension with fresh bentonite and sent back to the hydrotransport system of the shield tunnel complex, and unsuitable - in a centrifuge, where it is separated into water and clay material. After that, the purified water is used in the hydrotransport system or sent to the gutters of the metropolis, and clay material is moved to the permanent dump (not shown in the drawings). The cleaned soil from the separation chamber is sent to the site of the intermediate dump in the gallery, which is equipped with a conveyor (not shown in the drawings), after which the soil is moved to the place of the intermediate or permanent dump in accordance with the transport scheme of soil removal.

 Pumps pumping facilities are interconnected by slurry pipelines. A bentonite solution is supplied through pipelines from the separation complex to the shield tunneling complex, and the bentonite-soil mixture is supplied from the shield tunneling complex to the separation tunnel complex. Pipelines are extended in length during the sinking process, centrifugal pumps for feeding bentonite solution and pumping pulp are placed on the shield tunnel complex, in the tunnel and on the surface, while four intermediate pumps pumping the pulp are placed in the tunnel at a distance of 1200 m from each other, and three intermediate pumps pumping the bentonite solution are placed in the tunnel and on the shield tunnel complex at a distance of 1800 m from each other (not shown in the drawings).

The lining of 22 tunnels covered in a closed way is performed by a team of rings 26 with a diameter of 13.75 m, a width of 2 m and a thickness of 0.7 m, and each ring is made up of six normal 26, two adjacent 28 and one castle 29 reinforced concrete blocks, which performed in the form of segments of different lengths and mounted in a tunnel at a temperature not lower than 10 ^o C with ligation of the joints in adjacent rings and the installation of ties 30 between blocks in the ring and between adjacent rings 26.

 The load-bearing structures of the carriageway of 15 tunnels 1 are constructed at a distance of 300-400 m from the bottom using a gantry crane with a lifting capacity of 20 tons (not shown in the drawings), a length of 6.2 m and a cantilever jib (not shown) of 3.2 m which is based on the side structures of the carriageway, which is erected with 6-meter stops using the crane's jib. After one day after the concrete constructions are finished and the crane rail is completed (not shown in the drawings), the crane is moved to the finished side parts of the supporting structures (not shown in the drawings). The suspended ceiling 16 made of cast reinforced concrete is mounted on metal bands 31, which are screwed into the embedded parts of the lining in the arched part of the tunnel. The construction of the suspended ceiling 16 is carried out 550-650 m from the bottom using mobile scaffolding (not shown) 6 meters long, which are used as formwork for concrete and reinforcing works.

 After the carriageway 15 and the suspended ceiling 16 are constructed, internal tunnel structures are constructed from fireproof plates of basalt fiber, which are built simultaneously by several teams in areas free of temporary communications, and the completion of the internal tunnel structures is completed after dismantling all temporary communications in the tunnel .

 The implementation of the roadway of the carriageway is carried out after continuous ventilation of the tunnels.

 Extreme rectilinear sections 6, 7, including ramp 32, 33, and at least part of one of the curved sections of 3 or 4 tunnels and exit tunnels 34, 35, 36 with their ramp sections are erected in an open way in pits with fastening in the form of " walls in the ground "from bisected piles (not shown in the drawings). As the soil is being developed, the "wall in the soil" is anchored with soil anchors (not shown in the drawings) with excavators removed by excavators to dump trucks and through the portal to the surface (not shown in the drawings), and after completion of excavation, the foundation is waterproofed, the reinforcement is laid Concrete the bottom of permanent structures. Then step by step the permanent walls and the ceiling of the tunnel are erected, the waterproofing works are completed and backfill is performed (not shown in the drawings).

 Workings out for mounting 13 and dismounting 14 chambers are performed in an open way in pits with fastening in the form of a “wall in the ground” from bisected piles (not shown in the drawings) and additional antifiltration walls (not shown in the drawings), which are closed-loop and sealed in waterproofing.

 When tunneling excavations in flooded limestones, they are cemented to reduce water inflows, to strengthen the fractured massif and to eliminate the likelihood of karst phenomena, and when drilling, at least in certain areas, rocky soil is loosened by explosive method with small-bladed charges of limited mass with a calculated seismic impact zone no more than 5 m.

 In the process of erecting a tunnel-type overpass, they protect buildings and structures of the metropolis located near the construction zone by installing clips and metal strands in the protected objects, making injection piles under the protected objects, performing local cementation of foundations and the foundation-soil contact zone using constantly operating injectors , carrying out work on compensatory injection from one or several mines under protected objects, installation of metal frames and screed nuts in the basement of the protected objects, laying brickwork with openings (not shown in the drawings).

 Tunnels are ventilated from ventilation chambers 37, which are equipped at both ends of the closed method section.

Claims (18)

1. A method of erecting a section of an intracity ring transport highway of a metropolis, including the construction of a land section, a road tunnel and at least one intersection of the ring highway with a radial highway, characterized in that the tunnels are arranged along the axis of the ring highway and are lengthwise with two curvilinear plan, facing the convex part in opposite directions by sections and the formation of the middle straight section located between them and the straight end sections Wherein the angle between the axis of the straight end portion and the axis of secondary rectilinear portion is determined to be 39 - 47 ^o, and the angle between the axis another straight end section and the axis of secondary rectilinear portion - 23 - 31 ^o, and the intersection of the annular and radial lines operate at different levels, moreover, the radial highway during the construction of the site is located at the ground level, and the roadway intersection of the ring highway with the radial is located on the overpass, which is erected along the axis of the ring highway, and drive s overpass portion and ground portion of the tunnel match.  2. The method according to claim 1, characterized in that the middle straight section and at least a portion of at least one of the curved sections are performed in a closed way by forming at one end of the section a closed method for performing work in the zone of the smaller of the above angles of two mounting chambers, and at the other end of the closed method section, two dismantling chambers are carried out, installation is carried out in the left mounting chamber of the shield tunneling complex with closed chest and bottom face hydraulic load, and driving from this mounting chamber of the left tunnel to the left dismantling chamber, removing the shield tunnel complex in it, transporting it to the right mounting chamber, re-installing the shield tunnel complex in it, and then driving the right tunnel in the direction from the right mounting chamber to the right dismantling to the chamber where the paneling complex is dismantled, while the erection of the load-bearing structures of the carriageway and the suspended ceiling in the left tunnel is made after the completion of this tunneling ator, and the construction of load-bearing structures of the roadway and the ceiling right in the tunnel leading to the extent of his penetration.  3. The method according to claim 2, characterized in that they use a shield tunneling complex with a hydraulic loading of the face of the firm "Herennknecht" with a diameter of 14.23 m with a total length of 61 m, including a warhead 12.8 m long with a rotary working body equipped with roller cutters for the destruction of hard rocks, cutters for soft soils, a stone crusher for grinding individual boulders up to 1.2 m in size, a hydrotransport system with a slurry pipeline for delivering soil from the face to the surface, located on the surface of a separation station for separating soil from during the sinking of a solution of bentonite clay, which is fed into the bottomhole chamber under controlled pressure, and during sinking, the shield boring complex is automatically moved using laser guidance and ultrasound to locate boulders and other large inclusions at a distance of 50 m from the bottom.  4. The method according to any one of claims 2 and 3, characterized in that the mounting and dismounting chambers are performed in pits with a depth of 29.5 and 25.9 m, respectively, a width of 24.3 m, a length of 42.7 and 49 m, respectively, using temporary enclosing structures of the walls of the pit in the form of walls of bisected piles with a diameter of 750 mm with fixing the walls as the excavation of the soil with anchors and shootings and the execution of the curtain pit along the contour of the pit.  5. The method according to any one of claims 2 to 4, characterized in that during the assembly and installation of the paneling tunneling complex, a metal structure is mounted in the mounting chamber, transmitting force from the panel jacks when the complex moves to the camera tray and the reinforced concrete beams, and after the complex is set up and the conclusion of the cutting part of the rotor in the sealing ring cage include the hydrotransport system of the complex with the bottom load at low pressure, preferably 0.5-1 atm, which is stored until the shell of the head of the unit is inserted ksa into the soil at a calculated distance to prevent breakthrough of bentonite mortar into the mounting chamber through the o-ring or soil mass, as well as to prevent the formation of an air "bag" that can overcome hydrostatic pressure and rise to the surface, which is carried out by creating a tunnel in front of the mounting chamber in the direction of penetration at a length of 12 m and a width of 20 m of a fixed soil massif in the form of a closed contour along the width of the chamber and a length of 15 m from bisected piles with subsequent by draining it or from chemically fixed soil through wells drilled from the surface of the well, and to advance the head of the complex in the installation chamber, temporary lining rings are installed that transmit forces from the shield jacks to the supporting metal structure, moreover, after the first 13 m has been drilled and the complex rotor is removed from the fixed soil mass in unstable soils, the hydraulic load is increased to the required value and the cement grouting system is turned on for lining, after which the first 200 m of the tunnel and during this period carry out work related to the deployment of the complex, including the installation of technological platforms, hydraulic transport systems and fine-tuning of technologies to design parameters, moreover, after driving the first 100 m and perceiving pressure from shield jacks by friction between the lining and the rock temporary supporting structures in the mounting chamber are disassembled and further tunneling is carried out, and on approach to the dismantling chamber, the complex is withdrawn to a pre-prepared array 10 m long and 17 m high, which is made of lean concrete within the dismantling chamber.  6. The method according to claim 5, characterized in that during the passage in a closed way carry out scheduled shutdowns of the complex to replace cones and cutters, which is carried out during the transition from some geological conditions to others and in the central sections of the tunnels, and during stops of the complex from the bottomhole zone download the bentonite solution as much as possible, reduce the pressure in the caisson chamber and change the cutting tool on the rotor body from the side of the tunnel, and after driving the first tunnel, the left one is prophylactically rehabilitation of the complex with the replacement of the entire cutting tool.  7. The method according to any one of claims 2 to 6, characterized in that between the left and right tunnels with a step of 360 m in the level of the bottom of the tray and the carriageway, connecting workings are performed in the form of two-story discharges of an adit type with an outer shape with a width of 3.2 m, a height of about 8 m and a length of 14 m, moreover, at two faults, chambers of drainage plants with a length of 20 m are made in cast iron elliptical lining with the largest dimensions of 7 x 8 m, and the workings under the drainage installations are located between the tunnels perpendicular to the faults with the formation between Christmas trees of tunnels of chambers of drainage installations of a pedigree pillar of 3 m width, and for four faults, electrical switchboards are made in cast-iron lining with a diameter of 6 m, and excavations for these chambers 11 m and 12 m long are placed between tunnels perpendicular to faults with the formation of tunnels and switchboard chambers between lining a pillar with a width of 4 m, and the implementation of failures and chambers begin after driving the first tunnel - the left and produce with the simultaneous transportation of soil, delivery of materials and structures by haulage holes, which are laid during tunneling, and during tunneling, temporary welded metal elements filled with concrete are installed in the places of breakdowns in the lining, through which wells are drilled from the right and left tunnels and the surrounding natural mass is cemented, then the filling concrete is removed and they fail by means of small-scale mechanization, and before driving the chambers, cementation is performed from the completed fault, and after driving the second tunnel, the right tunnel, work is carried out to adjoin the fault to the constructed th tunnel, similar to work on adjoining faults to the first tunnel.  8. The method according to claim 3, characterized in that they use a shield tunnel complex, the hydrotransport system of which includes a separation complex and pumping facilities with intermediate pumps and pipelines, and the separation complex is equipped with cleaning and separating devices for separating and regenerating soil - vibrating screens, cyclones and centrifuges.  9. The method according to claim 8, characterized in that the pulp-soil coming from the tunnel penetration, mixed with an aqueous solution of bentonite clay, is subjected to separation, during which large limestone fractions from 30 to 50 mm in size are separated, then bentonite clay is separated from the soil in a centrifuge, after which incoherent soils — sand, sandy loam, limestone — are separated into fractions on mesh grids depending on size from 5 to 30 mm, and cohesive soils — Jurassic clay, marls, and carbon clay are additionally dehydrated on sieves, free of soil the tonitic suspension is fed into reservoirs, and after control, a suitable suspension is enriched with fresh bentonite and sent back to the hydrotransport system of the shield tunneling complex, and unsuitable - to a centrifuge, where it is separated into water and clay material, after which the purified water is used in the hydrotransport system or sent to gutters of the metropolis, and clay material is moved to the permanent dump, and the cleaned soil from the separation chamber is directed to the intermediate dump in the gallery, which uduyut conveyor, after which the soil is transferred to the intermediate space or persistent heap in accordance with a transport system soil removal.  10. The method according to p. 8, characterized in that the pumps of the pumping facilities are connected by slurry pipelines, and from the separation complex to the shield tunneling complex, bentonite solution is supplied through pipelines, and from the shield tunneling complex to the separation complex - bentonite-soil mixture, while the pipelines increase along the length during the sinking process, centrifugal pumps for feeding the bentonite solution and pumping the pulp are placed on the shield tunneling complex, in the tunnel and on the surface, while four omezhutochnyh pump pumping pulp, arranged in the tunnel at a distance of 1200 m from each other, and the three intermediate pump pumping bentonite solution in a tunnel and tunneling system switchboard at a distance of 1800 m from each other. 11. The method according to any one of claims 2 to 10, characterized in that the lining of tunnels covered by a closed method is performed by a team of rings with a diameter of 13.75 m, a width of 2 m and a thickness of 0.7 m, and each ring is composed of 6 normal, 2 adjacent and 1 castle reinforced concrete blocks, which are made in the form of segments of different lengths and are mounted in a tunnel at a temperature of at least 10 ^o C with ligation of joints in adjacent rings and the establishment of connections between blocks in the ring and between adjacent rings.  12. The method according to claim 2, characterized in that the supporting structures of the carriageway of the tunnels are constructed at a distance of 300 to 400 m from the bottom using a gantry crane with a lifting capacity of 20 tons, a length of 6.2 m and a cantilever reach of 3.2 m, which is supported on the side structures of the carriageway, which is erected with 6 m run-ins using the crane jib, and after 24 hours after the structures are concrete and the crane rail is completed, the crane is moved to the finished side parts of the supporting structures, and the suspended ceiling is made of monolithic reinforced concrete is mounted on metal strands that are screwed into the embedded parts of the lining in the arched part of the tunnel, and work on the erection of a suspended ceiling is carried out in 550 - 650 m from the bottom using mobile scaffolding 6 m long, which are used as formwork for concrete and reinforcing works .  13. The method according to any one of paragraphs.2, 12, characterized in that after the carriageway and the suspended ceiling are constructed from the fireproof plates of basalt fiber, the tunnel’s internal structures are constructed simultaneously by several teams in areas free of temporary communications, with full completion work on the implementation of the internal structures of the tunnel is carried out after the dismantling of all temporary communications in the tunnel.  14. The method according to any one of claims 2, 13, characterized in that the roadway is carried out after continuous ventilation of the tunnels.  15. The method according to claim 2, characterized in that the extreme rectilinear sections, including ramp, and at least part of one of the curved sections of the tunnels and exit ramps with their ramp sections are constructed in an open way in pits with a wall the soil "from bisected piles, and as the soil is developed, anchor the" wall in the soil "by ground anchors to remove the excavated soil by excavators into dump trucks and through the portal to the surface, and after excavation is completed Waterproofing of the foundations, laid fittings, concreted the bottom of permanent structures, then gradually erect permanent walls and ceiling of the tunnel, complete the work on the implementation of waterproofing and produce backfill.  16. The method according to p. 15, characterized in that the workings for the mounting and dismantling chambers are performed in an open way in pits with a wall in the ground fastening from bisected piles and additional antifiltration walls, which are made in a closed circuit and are sealed in a water seal.  17. The method according to any one of paragraphs.15, 16, characterized in that during the tunneling of mine tunnels in flooded limestones, the latter is cemented to reduce water inflows, strengthen the fractured massif and eliminate the likelihood of development of karst phenomena, and when driving, at least on some sections of the soil are loosened by explosive blasting with small-hole charges of limited mass with a calculated seismic impact zone of not more than 5 m.  18. The method according to any one of paragraphs.2 to 17, characterized in that during the construction of the tunnel type overpass, they protect buildings and structures of the metropolis located near the construction zone by installing clips and metal bands in the protected objects, making injection piles under the protected objects, performing local cementation of foundations and the foundation-soil contact zone using continuously operating injectors, carrying out compensatory injection of one or more shafts under protection aemye objects, installation of metal frames and ties in the basement of the protected objects, bookmarks masonry openings.

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