Inverse construction method for deep, large and long pit assembling structure of suspension-type envelope enclosure

Abstract

The present invention relates to the field of construction of underground buildings, specifically to an inverse construction method for a deep, large and long pit assembling structure of a suspension-type envelope enclosure. A method includes design and calculation; engineering construction of foundation piles; control over underground water; construction of a pit enclosure; building of a basement reinforcing and anti-seeping layer; inverse construction; and floor structure construction. By the inverse construction method for a deep, large and long pit assembling structure of a suspension-type envelope enclosure of the present invention, the pit construction quality is easily controlled, the basement is well waterproofed and easily monitored, and the quality control, service and maintenance are easy.

Claims

1. An inverse construction method for a deep, large and long pit assembling structure of a suspension-type envelope enclosure, comprising the following steps: (I) determining a pit size and depth of a pit enclosure according to a size of a basement to be constructed, and determining a thickness of a basement reinforced anti-seeping layer according to the depth of the pit enclosure and geological conditions; (II) performing one-column-one-pile construction in the pit, wherein the one-column-one-pile refers to an integrated structure of a column pile and an engineering pile, the engineering pile is disposed below the column pile, the bottom of the engineering pile is embedded into a waterproof layer or a rock formation, the top of the column pile is constructed to the designed height at one time; during the construction, the verticality of the column pile is ensured, post grouting is carried out at the bottom and the lateral middle portion of the pile to ensure the bearing capability of the column pile and relieve sedimentation; (III) before completing the construction of the pit enclosure and the basement reinforced anti-seeping layer, controlling the pressure of underground water to prevent bottom heaving and inrush; (IV) digging a groove, forming a continuous wall by mutually assembling splicing-type prefabricated wall boards in the groove, grouting and reinforcing the wall after the assembling is completed such that the pit resists stressed deformation and maintains stability, wherein the depth of the splicing-type prefabricated wall boards is greater than a depth of the basement floor; (V) modifying soil at the bottom of the basement by injecting a grouting material at a high pressure to form a waterproof layer, which is connected with the pit enclosure, as the basement reinforced anti-seeping layer, wherein the basement reinforced anti-seeping layer and the pit enclosure form a structure with an H longitudinal section, meaning that the depth of the basement reinforced anti-seeping layer is greater than the depth of the basement floor and smaller than the depth of the pit enclosure; (VI) dividing the basement into floors B.sub.0-B.sub.n+1 from the ground surface, digging the floor B.sub.0 first, setting up prefabricated framework beams in the space of the floor B.sub.0 after the digging is completed, then completing the digging of the floors B.sub.1-B.sub.n and setting up of the prefabricated framework beams therein in sequence, and finally digging the floor B.sub.n+1, and pouring the bottom face of the basement after digging to form the basement floor; (VII) performing construction upward floor by floor from the floor B.sub.n of the basement, wherein prefabricated concrete superposed floor-slabs or profiled sheet combined floor-slabs are assembled with the corresponding prefabricated framework beams during the construction on each floor, and then concrete is poured onto the prefabricated framework beams to form integrated floor system and floor slabs, and when the floor strength reaches 80% of the designed strength, the construction is continued upward higher floors; and wherein in step III, the pressure of the underground water is controlled by a method comprising steps of detecting the cover depth and water head height of the confined groundwater in a construction area, controlling the underground water using a dewatering well and recharge well combined technology in conjunction with the depth of the dug pit to prevent bottom heave and inrush, and during the soil excavation process and before the construction and strength formation of the basement reinforced anti-seeping layer, maintaining the pressure of the dewatering well on the confined water layer and keeping working state.

2. The inverse construction method for a deep, large and long pit assembling structure of a suspension-type envelope enclosure according to claim 1, characterized in that each one of the splicing-type prefabricated wall boards is provided with splicing portions on two sides; the splicing-type prefabricated wall boards are connected through the splicing portions; each one of the splicing portions is internally provided with a grouting semi-opening; a grouting cavity is formed after splicing the grouting semi-openings of two adjacent splicing-type prefabricated wall boards; and each one of the grouting cavities is internally provided with reinforced steel bars and concrete.

3. The inverse construction method for a deep, large and long pit assembling structure of a suspension-type envelope enclosure according to claim 2, characterized in that each one of the splicing portions is provided with a splicing strip and a splicing slot which are matched with each other; each one of the splicing-type prefabricated wall boards is formed with an opening in the length direction, and the opening is internally provided with the reinforced steel bars and the concrete.

4. The inverse construction method for a deep, large and long pit assembling structure of a suspension-type envelope enclosure according to claim 1, characterized in that during high-pressure grouting in step V, the anti-seeping extension layer is grouted outside the pit enclosure at the same time.

5. The inverse construction method for a deep, large and long pit assembling structure of a suspension-type envelope enclosure according to claim 1, characterized in that the thickness of the basement reinforced anti-seeping layer is determined upon the depth of a pit base plate and the distribution characteristics of a underground layer structure; the position relationship between the waterproof layer and the pit base plate needs to be clear; the thickness of the waterproof layer below the pit base plate is coordinated with the embedding depth of the wall boards of the suspension-type envelope enclosure according to the water-soil coupling analysis of a seepage flow and the stability requirement of a specification-based approach to ensure the stability design of the pit; the following conditions need to be judged, namely whether the pit base plate passes through the waterproof layer, wherein the worst condition is that the pit base plate does pass through the waterproof layer, and whether the waterproof layer exists in a certain range and whether the position of the waterproof layer meets the design requirements; except the case that the waterproof layer with a thickness which meets the design requirements exists below the pit base plate, a soil body in the range of the designed depth of the pit bottom needs to be completely grouted for reinforcement and seepage resistance in other conditions.

6. The inverse construction method for a deep, large and long pit assembling structure of a suspension-type envelope enclosure according to claim 1, characterized in that in step IV, a supporting wall groove is dug along the outer line of the pit first using a groove milling machine, then the prefabricated wall boards are assembled in the groove to form an underground continuous wall of which the top is provided with a closed reinforcing and concrete crown beam; the height and width of the crown beam are determined through calculation while the width is better not smaller than the thickness of the underground continuous wall; the underground continuous wall is constructed by section; the top of the wall is provided with a full-length ring-shaped top beam to strength the integrity of the underground continuous wall; the ring-shaped top beam is better leveled with the soil-ward face of the underground continuous wall to maintain a guide wall which plays a role of blocking the soil body and protecting the slope and avoiding adverse effect on surroundings; the top of the underground continuous wall is embedded into the ring-shaped beam by a length of better not smaller than 50 mm, and the length of the longitudinal reinforcing and bars that are anchored in the ring-shaped beam is better determined according to tensioning and anchoring requirements.

7. The inverse construction method for a deep, large and long pit assembling structure of a suspension-type envelope enclosure according to claim 1, characterized in that in step V, the grouting material is injected from the pit top to the position of the reinforced anti-seeping layer at a high pressure via grouting holes; the grouting holes extend to a position which is 2 to 4 m below the base plate of the basement; after mud jacking in the grouting holes, the basement reinforced anti-seeping layer is formed at the bottom of the basement, and the thickness of the basement reinforced anti-seeping layer is 2 to 3 m.

8. The inverse construction method for a deep, large and long pit assembling structure of a suspension-type envelope enclosure according to claim 1, characterized in that in step VI, each one of the prefabricated framework beams consists of a main beam and a secondary beam; the main beam is built into a cross structure; the crossing point of the main beam is disposed at the position of the corresponding one of the column piles; the main beam and the secondary beam are overlapped to form a floor-slab superposing area; each one of the prefabricated framework beams comprises a slip formwork moving area; and in step VII, a slip formwork is adopted to install pre-stress concrete superposed floor-slabs or profiled steel combined floor-slabs in the floor-slab superposing area.

9. The inverse construction method for a deep, large and long pit assembling structure of a suspension-type envelope enclosure according to claim 1, characterized in that in step VII, each one of the prefabricated framework beams is provided with an assembling pre-embedded parts which are used to be connected with the pre-stress concrete superposed floor-slabs or profiled steel combined floor-slabs.

10. The inverse construction method for a deep, large and long pit assembling structure of a suspension-type envelope enclosure according to claim 1, wherein the splicing-type prefabricated wall boards include flat-plate-type wall boards and bent-type wall boards.

11. The inverse construction method for a deep, large and long pit assembling structure of a suspension-type envelope enclosure according to claim 1, wherein in step VI, a stripping alternative bay method is adopted to excavate the soil, and specially, the soil is excavated by layer and by zone while the soil next to the wall is retained.

Description

BRIEF DESCRIPTION OF THE SEVERAL VIEWS OF THE DRAWINGS

(1) FIG. 1 is a schematic view of a one-column-one-pile structure in the present invention;

(2) FIG. 2 is a schematic view of a basement reinforcing and anti-seeping layer in the present invention;

(3) FIG. 3 is a schematic view of soil excavation on floor B.sub.0 in an inverse sequence in the present invention;

(4) FIG. 4 is schematic view of soil excavation on floor B.sub.1 in an inverse sequence in the present invention;

(5) FIG. 5 is a schematic view of a floor-slab structure construction in the present invention;

(6) FIG. 6 is a schematic view of a completed basement in the present invention;

(7) FIG. 7 is a schematic view of assembling of the splicing-type prefabricated wall boards;

(8) FIG. 8 is a structural view of a prefabricated framework beam in the present invention;

(9) FIG. 9 is a schematic view of embodiment 2 in the present invention.

(10) FIG. 10 is a schematic illustrating a structure comprising a ring-shaped top beam and a closed reinforced concrete crown beam.

DETAILED DESCRIPTION OF THE INVENTION

(11) The following specific embodiments are merely used to explain the present invention and cannot be regarded as limit to the present invention. Those skilled in the art can make modifications on the embodiments without creative labor after reading the Description, and all the modifications should fall within the protective scope of the Claims of the present invention.

(12) The present invention is described in detail in conjunction with the attached drawings and embodiments.

(13) Embodiment 1:

(14) As shown in FIG. 1-6, an inverse construction method for a deep, large and long pit assembling structure of a suspension-type envelope enclosure is adopted to construct an underground three-floor basement by the following steps:

(15) I. Design and calculation: Geological conditions of hydrological and geological engineering are researched according to the size of the basement to be constructed and the geological conditions of water-enriched projects near rivers and seas to determine the relationship between the level of the underground water at the position of the basement and the tide of the river and sea water body and the permeability relationships between all soil layers, and then the design number of the floors of the underground structure and the sensitivity of the surroundings are combined to comprehensively determine the pit size and the depth of a pit enclosure 1; the thickness of a basement reinforcing and anti-seeping layer 2 is determined according to the depth of the pit enclosure 1 and the geological conditions. The thickness of the basement reinforcing and anti-seeping layer 2 is determined upon the depth of a pit base plate and the distribution characteristics of an underground layer structure; the position relationship between a waterproof layer and the pit base plate needs to be figured out; the thickness of the waterproof layer below the pit base plate is required to be coordinated with the embedding depth of the wall board of the suspension-type envelope enclosure according to the results of a water-soil coupling analysis of a seepage flow and the stability requirement of a specification-based approach to ensure the stability design of the pit; the following conditions need to be judged, namely whether the pit base plate passes through the waterproof layer, wherein the worst condition is that the pit base plate does pass through the waterproof layer, and whether the waterproof layer exists in a certain range and whether the position of the waterproof layer meets the design requirements; except the case that the waterproof layer with a thickness which meets the design requirements exists below the pit base plate, the soil body in the range of the designed depth of the pit bottom needs to be completely grouted for reinforcement and seepage resistance in other conditions.

(16) II Engineering construction of foundation piles: As shown in FIG. 1, one-column-one-pile construction is adopted in the pit, wherein the one-column-one-pile refers to an integrated structure of a column pile 3 and an engineering pile 4, the engineering pile 4 is a grouting pile while the column pile 3 is a steel pipe concrete column pile, the engineering pile 4 is disposed below the column pile 3, the bottom of the engineering pile 4 is embedded into a waterproof layer or a rock formation, the top of the column pile 4 is constructed to the designed height at one time; during the construction, the verticality of the column pile 3 is ensured, post grouting is carried out at the bottom and the lateral middle portion of the pile to ensure the bearing capability of the column pile 3 and relieve sedimentation.

(17) III. Control over underground water: before the construction of the pit enclosure 1 and the basement reinforcing and anti-seeping layer 2 is completed, the pressure of the underground water is controlled by a method including steps of detecting the cover depth and water head height of the confined groundwater in a construction area, controlling the underground water using a precipitation well and inverted well combined technology in conjunction with the depth of the dug pit to prevent bottom heaving and inrush, and during the soil excavation process and before the construction and strength formation of the basement reinforcing and anti-seeping layer 2, maintaining the pressure of the precipitation well on the confined water layer and keeping working state.

(18) IV Construction of the pit enclosure 1: A supporting wall groove is dug along the outer line of the pit first using a groove milling machine, then the prefabricated wall boards 100 are assembled in the groove to form an underground continuous wall, and the wall is reinforced by grouting after the assembling is completed such that the pit can resist stressed deformation and meet the requirement for stability; the depth of the splicing-type prefabricated wall boards 100 is greater than the depth of a basement floor 6; the top of the underground continuous wall should be provided with a closed reinforced concrete crown beam; the height and width of the crown beam are determined through calculation while the width is better not smaller than the thickness of the underground continuous wall; the underground continuous wall is constructed by section; the top of the wall is provided with a full-length ring-shaped top beam to strength the integrity of the underground continuous wall; the ring-shaped top beam is better leveled with the soil-ward face of the underground continuous wall to maintain a guide wall which plays a role of blocking the soil body and protecting the slope and avoiding adverse effect on surroundings; the underground continuous wall is embedded into the ring-shaped beam by a length of better not smaller than 50 mm, and the length of the longitudinal reinforcing bars that are anchored in the ring-shaped beam is better determined according to tensioning and anchoring requirements.

(19) According to FIG. 7, each one of splicing-type prefabricated wall boards 100 is provided with splicing portions 110 on two sides; the splicing-type prefabricated wall boards 100 are connected through the splicing portions 110; each one of the splicing portions 110 is internally provided with a grouting semi-opening 113; the grouting semi-openings 113 of two adjacent pieces of the splicing-type prefabricated wall boards 100 are spliced to form a grouting cavity 114; each one of the grouting cavities 114 is internally provided with reinforcing steel bars 115 and concrete; each one of the splicing portions 110 is provided with a splicing strip 111 and a splicing slot 112 which are matched with each other; each one of the splicing-type prefabricated wall boards 100 is formed with an opening 120 in the length direction, and the opening 120 is internally provided with the reinforcing steel bars 115 and the concrete; the splicing-type prefabricated wall boards 100 include flat-plate-type wall boards and bent-type wall boards, and the bent-type wall boards are disposed at the corners of the pit.

(20) V. Construction of the basement reinforcing and anti-seeping layer 2: As shown in FIG. 2, the soil at the bottom of the basement is modified by injecting a grouting material at a high pressure to form a waterproof layer, which is connected with the pit enclosure 1, as the basement reinforcing and anti-seeping layer 2, wherein the basement reinforcing and anti-seeping layer 2 and the pit enclosure 1 form a structure with an H longitudinal section, meaning that the depth of the basement reinforcing and anti-seeping layer 2 is greater than the depth of the base plate 6 of the basement and smaller than the depth of the pit enclosure 1; the grouting material is injected from the pit top to the position of the basement reinforcing and anti-seeping layer 2 at a high pressure via grouting holes 201; the grouting holes 201 extend to a position which is 2-4 m below the base plate of the basement; after mud jacking in the grouting holes 201, the basement reinforcing and anti-seeping layer 2 is formed at the bottom of the basement, the thickness of the basement reinforcing and anti-seeping layer 2 is 2-3 m; during high-pressure grouting, an anti-seeping extension layer 21 is grouted outside the pit enclosure 1, and the anti-seeping extension layer 21 extends out of the pit by 1-2 m.

(21) VI. Inverse construction: A stripping alternative bay method is adopted to excavate the soil, and specifically, the soil is excavated by layer and by zone while the soil next to the wall is retained. The three-floor basement is divided into B.sub.0-B.sub.2 floors from the ground surface. As shown in FIG. 3, the floor B.sub.0 is excavated first, and prefabricated framework beams 5 are set up in the space of the floor B.sub.0 after the digging is completed.

(22) As shown in FIG. 8, each one of the prefabricated framework beams 5 consists of a main beam 501 and a secondary beam 502; the main beam 501 is built into a cross structure; the crossing point of the main beam 501 is disposed at the position of the corresponding one of the column piles 3; the main beam 501 and the secondary beam 502 are overlapped to form a floor-slab superposing area 510; and each one of the prefabricated framework beams 5 includes a slip formwork moving area 520. As shown in FIG. 4, the excavation of the floor B.sub.1 and the building of the prefabricated framework beams 5 therein are completed in the same way; the floor B2 is excavated at last, and the bottom face of the basement is poured after digging to form the basement floor 6.

(23) VII. Construction of a floor structure: As shown in FIG. 5, construction is carried out upward floor by floor from the floor B2 of the basement, wherein a slip form device 9 is adopted to install prefabricated concrete superposed floor-slabs 7 or profiled sheet combined floor-slabs 8 in the floor-slab superposing area 510; the slip-form device 9 is installed on the column pile 3 and is controlled to go up and down by a hydraulic system; during the construction on each floor, the prefabricated concrete superposed floor-slabs 7 or profiled sheet combined floor-slabs 8 are assembled with the corresponding prefabricated framework beams 5 on each floor; each one of the prefabricated framework beams 5 is provided with an assembling pre-embedded part such that the prefabricated framework beams 5 are connected with the prefabricated concrete superposed floor-slabs 7 or profiled sheet combined floor-slabs 8; then concrete is poured onto the prefabricated framework beams 5 to form integrated floor system and floor slabs after the installation, and when the floor strength reaches 80% of the designed strength, the above steps are repeated to construct the higher floors in sequence, wherein the floor B.sub.1 goes first and followed by the floor B.sub.0.

(24) Embodiment 2:

(25) Embodiment 2 is different from embodiment 1 in that, as shown in FIG. 9, after the building of the pre-fabricated framework beams 5 of the floor B.sub.0 is completed, pouring is carried out directly; during pouring, the a slip-form frame moving area 520 of the prefabricated framework beams 5 of such floor is retained as the discharging opening of the excavated soil; then, the excavation of the floor B.sub.1 and floor B.sub.2 and the building of the prefabricated framework beams 5 therein are carried out downward in sequence, and after the excavation and the building of the prefabricated framework beams 5 are completed, the slip-form 9 device is adopted to install the floor-slabs upward from the floor B.sub.2.