WO2018177304A1 - Fabricated underground building and construction method thereof - Google Patents

Abstract

A fabricated underground building, comprising underground walls (1). A concave-convex embedded structure is provided at each joint of adjacent underground walls (1), and a convex portion is provided at one side and a concave portion at the other side; an open recess with a cavity is formed at the middle of the concave portion; the convex portion at the joint of one of the walls (1) is embedded into the concave portion at the joint of the other of the walls (1); the bottom and side surfaces of the walls (1) are provided with tracks (2); a chain cutter (3) is mounted on the track (2) during construction; the width of the chain cutter (3) is smaller than that of the recess opening at the joint; the chain cutter (3) is composed of a chain (3-1) and a cutter (3-2) mounted on the chain (3-1); during construction, the chain cutter (3) merely excavates rock at the bottom of the wall (1); the chain cutter (3) running from bottom to top brings the excavated rock upward from the bottom of the wall (1); and the wall (1) and the bottom chain cutter (3) move downwards simultaneously. Also disclosed is a construction method of the fabricated underground building. The wall (1) is prefabricated by a factory and is provided with the chain cutter (3) for excavating rock at the bottom of the wall (1); the wall (1) and the chain cutter (3) move downwards simultaneously; after a wall (1) is constructed to a set depth, an adjacent wall (1) is then constructed. The construction is simple, the construction period is short, and the costs are low.

Description

Assembled underground building and construction method thereof Technical field

The invention relates to a prefabricated underground building and a construction method thereof, and belongs to the technical field of civil engineering foundation construction.

Background technique

The existing large-scale basic technology adopts the overall excavation construction method, with long construction period, high labor intensity and poor working environment safety.

The existing underground continuous wall technology uses a trenching machine on the ground to excavate a long and narrow deep trough under the condition of mud retaining wall, hoist the steel cage in the trough, and pour the underwater concrete into a unit trough section. This is done piece by piece. The main defects are as follows: 1) The underwater construction quality in the tank is difficult to control and detect, and the construction period is long; 2) The interface between the groove sections is difficult to construct and easy to seep; 3) The slotting machine is high and moves along the circumference. Applications are limited.

The existing revetment foundation is generally excavated by an excavator, and a drainage ditch or a collecting well is provided for drainage, and a cofferdam is required to be formed on the outer side of the revetment. In order to prevent a large amount of settlement, the daily masonry height is limited, the construction period is long, and the cost is high.

Summary of the invention

The invention provides a prefabricated underground building and a construction method thereof, the purpose of which is to overcome the defects of the prior art, and the main advantages thereof: the assembled underground building is composed of a wall, and the adjacent wall interface adopts concave and convex embedding. The structure of the wall has a chain knife for excavating the bottom of the rock, the factory prefabricated wall, the site is divided into blocks or the whole is lowered, the construction is simple, the construction period is short, and the cost is low.

Technical solution of the invention: the assembled underground building comprises an underground wall 1 comprising a wall 1-1, a wall 1-2 and a cross wall 1-3; the structure of the adjacent wall 1 interface is adopted Concave-convex embedded structure, one being a convex part and the other being a concave part, the concave part is a groove having an opening in the middle of the wall, that is, the convex part of the interface of the wall 1 is embedded in the concave part of the interface of the other wall 1, and the wall 1 is convex The thickness t of the junction between the tail end and the wall 1 is greater than or equal to the thickness of the same wall 1. The width of the groove mouth is greater than or equal to the thickness t of the junction of the convex end of the other wall 1 and the wall 1 and is smaller than the other wall. 1 The maximum thickness of the convex part at the interface; the interface of the adjacent wall 1 has three structures: a word interface, a 丅 word interface and a cross interface; the bottom and the side of the wall 1 are provided with a track 2, and the track 2 is provided with a chain knife 3 during construction. The width of the chain cutter 3 is smaller than the width of the groove portion at the interface, and the chain cutter 3 is composed of a chain 3-1 and a cutter 3-2 mounted on the chain 3-1. When the chain cutter 3 is working, only the rock at the bottom of the wall 1 is excavated. The soil, the chain cutter 3 running from the bottom up, brings the excavated rock at the bottom of the wall 1 to the upper side, and the wall 1 and the bottom chain cutter 3 run downward at the same time.

The invention has the advantages that the wall has a chain cutter for excavating the bottom of the rock, and adopts a factory prefabrication, on-site block or overall descending construction method, the construction is simple, the construction period is short, and the cost is low.

DRAWINGS

1 is a schematic view showing a construction structure in which a convex portion of a wall 1-1A is embedded in a concave portion of an interface of another wall 1, and is a structural schematic view of a thickness t of a joint between a rear end of the wall 1-1A and a wall 1-1A;

Figure 2 is a view in the direction of arrow A of Figure 1, and is also a structural schematic view of the core knife 1-3A and the chain cutter 3 descending together, and is also driven by the driving power device 5-1, the spoil handling device 5-2 and the machine. Schematic diagram of the chain cutter driving device 5 composed of the frame 5-3;

Figure 3 is a BB view of Figure 2 (with the chain cutter 3 removed), also a schematic view of the structure of the rail 2 running on the bottom chain cutter 3 of the wall 1-1A, and also the mud nozzle 6 of the mud pipeline device 6 on the wall 1-1A. 1 and a schematic view of the structure of the mud pipeline 6-2;

4 is a schematic structural view of the chain cutter 3, and is also a schematic structural view of the chain 3-1 and the cutter 3-2;

FIG. 5 is a schematic structural view of another space-curable chain cutter 3, and is also a schematic structural view of the chain 3-1 and the cutter 3-2;

6 is a schematic structural view of a wall 1-1 of three structural forms of 1-1A, 1-1B, and 1-1C; and is a schematic structural view of a side cover 7 having a bottom edge at the outer side of the rail 2 on the wall 1;

7 is a schematic structural view showing the construction state of the three types of wall structures 1-1A, 1-1B and 1-1C after the chain cutter 3 and the tooling 4 are installed;

Figure 8 is a schematic structural view of two types of embossed walls 1-2A and 1-2B;

Figure 9 is a schematic structural view of a cross wall 1-3;

10 is a schematic structural view of a word interface 8-1 formed by the convex portion of the wall 1 embedded in the groove of the other wall 1, and is also a structural schematic view of the thickness t of the connection between the end of the convex portion of the wall 1 and the wall 1;

11 is a schematic structural view of a word interface 8-1 of another structural form;

Figure 12 is a schematic view showing the structure of the 接口-shaped interface 8-2A formed by the convex portion of the corner wall 1-2A embedded in the groove shape of the other wall 1;

Figure 13 is a schematic view showing the structure of the 接口-shaped interface 8-2B formed by the convex portion of the middle stencil wall 1-2B embedded in the groove of the other two walls 1;

Figure 14 is a schematic view showing the structure of the cross interface 8-3A formed by the convex portions of the two walls 1 embedded in the grooves of the cross walls 1-3;

Figure 15 is a schematic view showing the structure of the cross interface 8-3B formed by the convex portions of the three walls 1 embedded in the recesses of the cross walls 1-3;

Figure 16 is a schematic view showing the construction structure after the prefabricated wall 1-1C is transported to the installation site, and the chain cutter 3 and the chain cutter driving device 5 are installed;

Figure 17 is the bottom chain knife 3 of the wall 1-1C excavated the rock, the side of the chain knife 3 running from the bottom up to bring the excavated rock to the top, the wall 1-1C and the bottom chain knife 3 together down to the design depth Schematic diagram of the structure;

Figure 18 is a view taken along line A of Figure 17, and is also a schematic view of the structure of the tooling 4;

Figure 19 is a schematic view showing the structure after the wall 1-1C is lowered to the set depth and the chain cutter 3, the tooling 4 and the chain cutter driving device 5 are removed;

20 is a structural schematic view showing the convex portion on the unconstructed wall 1-1A being embedded in the groove of the concave portion at the interface of the constructed wall 1-1C;

Figure 21 is a view in the direction of arrow A of Figure 20, and is also a schematic structural view of the chain cutter 3 and the chain cutter driving device 5 mounted on the wall 1-1A;

Figure 22 is the bottom of the wall 1-1A chain knife 3 excavated rock, the side of the chain knife 3 running from the bottom up to bring the excavated geotechnical to the top, the wall 1-1A and the bottom chain knife 3 together down to the design depth Schematic;

Figure 23 is a schematic structural view of the chain cutter driving device 5 and the chain cutter 3 on the wall 1-1A;

24 is a schematic structural view of a prefabricated underground building formed after completion of construction of all the walls 1, and is also a structural schematic view of the assembled underground building as an underground continuous wall;

Figure 25 is a view of the A-A of Figure 24, and is a structural schematic view of the construction of the basement after digging the rock in the surrounding wall after the completion of the construction of the wall 1;

Figure 26 is a schematic view showing the structure of an underground building composed of a plurality of word intermediate wall 1-2B;

Figure 27 is a view taken along line A-A of Figure 26.

1 in the figure is the underground wall of the assembled underground building, including a wall 1-1, a wall 1-2 and a cross wall 1-3; 1-1 is a wall, according to the category of the interfaces at both ends 1-1A, 1-1B, and 1-1C; 1-1A is a wall with a groove at one end and a convex portion at the other end; 1-1B is a wall with convex portions at both ends; -1C is a wall with grooves at both ends; 1-2 is a wall with 1-2A and 1-2B; 1-2A is a corner wall; 1-2B is middle Word wall; 1-3 is the cross wall; 2 is the track with the chain knife 3 running at the bottom and side of the wall 1; 3 is the chain knife for excavating the rock, which is connected by the chain 3-1 and the chain 3-1 The cutter 3-2 is composed; 3-1 is the chain constituting the chain cutter 3; 3-2 is the cutter constituting the chain cutter 3; 4 is the tooling; 5 is the chain cutter driving device, which is driven by the driving power device 5-1 and spoil The device 5-2 and the frame 5-3 are composed; 5-1 is the driving power device; 5-2 is the spoil handling device; 5-3 is the frame; 6 is the mud pipeline device; 6-1 is the bottom of the wall 1 The mud nozzle on the wall; 6-2 is the mud pipeline inside the wall 1; 7 is the side cover with the edge angle on the outer side of the rail 2 on the wall 1; 8 is the interface of the adjacent wall 1 One-word interface 8-1, 丅 word interface 8-2 and cross interface 8-3 three structures; 8-1 is a word interface; 8-2 is a 丅 word interface, divided into 8-2A and 8-2B two structures 8-2A is the 丅 word interface applied to the two wall 1 connections at the interface; 8-2B is the 丅 word interface applied to the interface with three wall 1 connections; 8-3 is the cross interface, divided into 8-3A and 8 -3B two structures; 8-3A is the cross interface applied to the three wall 1 connections at the interface; 8-3B is the cross interface applied to the four wall 1 connections at the interface; t is the wall 1 convex end and wall 1 The thickness of the joint.

detailed description

The prefabricated underground building includes a subterranean wall 1 including a wall 1-1, a plaque wall 1-2 and a cross wall 1-3; the structure of the adjacent wall 1 interface adopts a concave-convex embedded structure, one The other part is a concave portion, and the concave portion is a groove having an opening in the middle of the wall, that is, the convex portion of the interface of the wall 1 is embedded in the concave portion of the interface of the other wall 1, and the rear end of the convex portion of the wall 1 is connected with the wall 1. The thickness of the portion is greater than or equal to the thickness of the same wall 1, the width of the groove portion is greater than or equal to the thickness of the junction of the end of the convex portion of the other wall 1 and the wall 1, and is smaller than the maximum thickness of the convex portion at the interface of the other wall 1; The interface of the adjacent wall 1 has three structures: a word interface, a 接口 word interface and a cross interface; the bottom and the side of the wall 1 are provided with a track 2, and the track 2 is provided with a chain knife 3 during construction, and the width of the chain knife 3 is smaller than that at the interface. The width of the notch portion, the chain cutter 3 is composed of a chain 3-1 and a cutter 3-2 mounted on the chain 3-1. When the chain cutter 3 is working, only the rock at the bottom of the wall 1 is excavated, and the chain cutter running from the bottom to the top is operated. 3 Bring the excavated geotechnical soil at the bottom of the wall 1 to the top, and the wall 1 and the bottom chain cutter 3 run downward at the same time.

The bottom and side of the groove end of the wall 1 interface are provided with a track 2, and the track 2 is provided with a chain knife 3 during construction. When the chain knife 3 is working, only the rock at the bottom of the groove end of the interface of the wall 1 is excavated, and runs from bottom to top. The chain cutter 3 brings the excavated rock at the bottom of the groove end of the wall 1 interface to the upper side, and the wall 1 and the bottom chain cutter 3 simultaneously run downward.

The interfaces at both ends of the wall 1-1 are divided into three structures: A, B, and C: A, one end is a groove, the other end is a convex part; B, both ends are convex parts; C, both ends are Groove.

Both the wall 1-2 and the cross wall 1-3 are composed of a wall 1-1.

The one-word interface is applied to the connection with two walls 1 at the interface.

The 丅 word interface is divided into two structures A and B: A, the connection of the wall 1 applied to the interface at the interface; B, the connection of the three walls 1 applied to the interface.

The cross interface is divided into two structures A and B: A, the connection of the wall 1 applied to the three interfaces at the interface; B, the connection of the wall 1 applied to the four interfaces.

The wall 1 is an underground continuous wall or a bank.

The specific construction method described has the following steps:

1) Prefabricated wall 1;

2) Transport the wall 1 to the installation site, first construct the wall with the end interface as the recessed part 1

3) Install the chain cutter 3 and the chain cutter driving device on the rail 2 at the bottom and side of the wall 1;

4) Install the chain cutter 3 and the chain cutter driving device on the bottom and side rails 2 at the groove end interface of the wall 1;

5) The bottom chain knife 3 of the wall 1 excavates the rock and soil, and the side of the chain knife 3 running from the bottom up brings the excavated rock soil to the top;

6) Wall 1 and the chain knife 3 at the bottom are lowered together;

7) The wall 1 is lowered to the set depth, and the chain cutter driving device and the chain cutter 3 are removed;

8) attaching a chain cutter 3 and a chain cutter driving device to the wall 1 whose other interface is a convex portion;

9) embedding the convex portion on the unconstructed wall 1 into the groove of the concave portion at the interface of the constructed wall 1;

10) The bottom chain knife 3 of the wall 1 excavates the rock and soil, and the side of the chain knife 3 running from the bottom up brings the excavated rock soil to the top;

11) Wall 1 and the chain knife 3 at the bottom are lowered together;

12) The wall 1 is lowered to the set depth, and the chain cutter driving device and the chain cutter 3 are removed;

13) removing the geotechnical soil in the groove cavity at the interface of the two walls and pouring concrete;

The construction of the above 2) to 13) is repeated until the construction of all the walls 1 is completed.

After the construction of the wall 1 is completed, the underground soil is excavated and the construction of the basement is carried out.

The invention is further described below in conjunction with the drawings:

As shown in FIG. 1 to FIG. 5, the assembled underground building includes a basement wall 1, and the structure of the interface of the adjacent wall 1 adopts a concave-convex embedded structure, one is a convex part and the other is a concave part, and the concave part is a cavity in the middle. The groove of the opening, that is, the convex portion of the interface of the wall 1 is embedded in the concave portion of the interface of the other wall 1, and the thickness t of the connection between the end of the convex portion of the wall 1 and the wall 1 is greater than or equal to the thickness of the same wall 1, the groove The width of the mouth is equal to the thickness t of the junction of the end of the convex portion of the other wall 1 and the wall 1, which is smaller than the maximum thickness of the convex portion at the interface of the other wall 1; the bottom and the side of the wall 1 are provided with the track 2, and the wall 1 interface is concave The bottom and side of the groove end are also provided with a track 2, and the track 2 is provided with a chain cutter 3 at the time of construction. The width of the chain cutter 3 is smaller than the width of the groove portion at the interface, and the chain cutter 3 is connected by the chain 3-1 and the chain 3- The cutter 3-2 is composed of 1 and the driving power unit 5-1 drives the chain cutter 3. When the chain cutter 3 works, only the rock at the bottom of the wall 1 is excavated, and the rock that has been excavated at the bottom of the wall 1 is driven by the chain cutter 3 running downwards and upwards. The soil belt is up to the upper portion, and the device 5-2 separates the rock soil brought from the bottom of the wall cutter 3 from the bottom of the wall 1 with the chain cutter 3, and the wall 1 and the bottom chain cutter 3 simultaneously run downward.

As shown in FIG. 6 to FIG. 9 , the underground wall 1 includes a wall 1-1, a wall 1-2 and a cross wall 1-3; the wall 1-1 is divided into 1-1A according to the category of the interfaces at both ends. 1-1B and 1-1C three structures, 1-1A is a wall with a groove at one end and a convex portion at the other end, 1-1B is a wall with convex portions at both ends, 1-1C is two The wall is a grooved wall, and the wall 1-2 has two structures: a corner wall 1-2A and a middle wall 1-2B; both the wall 1-2 and the cross wall 1-3 It is composed of a wall 1-1.

As shown in FIG. 10 to FIG. 15 , the interface of the adjacent wall 1 has three structures: a word interface 8-1, a 丅 word interface 8-2, and a cross interface 8-3, and the 接口 word interface 8-2 has two interfaces applied to the interface. The wall interface 1 is connected to the 接口 interface 8-2A and the 应用于 interface 8-2B is applied to the interface with three wall 1 connections. The cross interface 8-3 is applied to the cross interface of the three walls 1 connected at the interface. 8-3A and the cross interface 8-3B applied to the four wall 1 connections at the interface.

As shown in Fig. 16 to Fig. 25, the concrete construction method of the assembled underground building composed of the wall 1-1A, the wall 1-1C and the wall 1-2A has the following steps:

1) Prefabricated wall 1;

2) transport the wall 1 to the installation site, first construct the wall 1-1C with the end interface as the recess;

3) mounting the chain cutter 3 and the chain cutter driving device 5 on the rail 2 at the bottom and the side of the wall 1-1C;

4) mounting the chain cutter 3 and the chain cutter driving device 5 on the bottom and side rails 2 at the groove end interface of the wall 1-1C;

5) The bottom chain knife 3 of the wall 1-1C excavates the rock and soil, and the side of the chain knife 3 running from the bottom up brings the excavated rock soil to the top;

6) Wall 1-1C and the chain cutter 3 at the bottom are lowered together;

7) The wall 1-1C is lowered to the set depth, and the chain cutter driving device 5 and the chain knife 3 are removed;

8) attaching the chain cutter 3, the chain cutter driving device 5, and the like to the wall 1-1A whose other interface is a convex portion;

9) embedding the convex portion on the unconstructed wall 1-1A into the groove of the concave portion at the interface of the constructed wall 1-1C;

10) The bottom chain knife 3 of the wall 1-1A excavates the rock and soil, and the side of the chain knife 3 running from the bottom up brings the excavated rock soil to the top;

11) Wall 1-1A and the chain cutter 3 at the bottom are lowered together;

12) The wall 1-1A is lowered to the set depth, and the chain cutter driving device 5 and the chain knife 3 are removed;

13) removing the geotechnical soil in the groove cavity at the interface of the two walls and pouring concrete;

Repeat the above construction of 2) to 13) until the construction of all the walls 1 is completed;

After the completion of the construction of the wall 1 of the underground building, the rock and soil in the surrounding wall are excavated to carry out the construction of the basement; the assembled underground building formed after the completion of all the walls 1 is the underground continuous wall.

As shown in Fig. 26 and Fig. 27, the underground building composed of a plurality of word intermediate wall 1-2B is a bank.

Claims (10)

A fabricated underground building characterized in that the assembled underground building comprises a underground wall (1), and the underground wall (1) comprises a wall (1-1), a wall (1-2) and a cross wall (1- 3); the structure at the interface of the adjacent wall (1) adopts a concave-convex embedded structure, one is a convex portion and the other is a concave portion, and the concave portion is a groove having an opening in the middle of the cavity, that is, an interface of the wall (1) The convex portion is embedded in the concave portion of the interface of the other wall (1), and the thickness of the joint between the end of the convex portion of the wall (1) and the wall (1) is greater than or equal to the thickness of the same wall (1), and the width of the groove portion The thickness greater than or equal to the junction of the end of the convex wall and the wall (1) of the other wall (1) is smaller than the maximum thickness of the convex portion at the interface of the other wall (1); the interface of the adjacent wall (1) has a word interface, Three types of structure: 丅 word interface and cross interface; the bottom (1) of the wall (1) is provided with a track (2), and the track (2) is provided with a chain knife (3) during construction. The width of the chain knives (3) is smaller than that at the interface. The width of the notch, the chain cutter (3) consists of a chain (3-1) and a cutter (3-2) mounted on the chain (3-1), and the chain cutter (3) only excavates the wall when working (1) At the bottom of the rock, the rock that has been excavated from the bottom of the wall (1) by a chain knife (3) running up and down Band to the top wall (1) and a bottom chain cutter (3) run downwards. A prefabricated underground building according to claim 1, characterized in that the bottom (1) of the groove end of the wall (1) is provided with a rail (2), and the rail (2) is provided with a chain knife (3) during construction. ), when the chain cutter (3) is working, only the rock and soil at the bottom of the groove end of the wall (1) interface is excavated, and the geotechnical strip at the bottom of the groove end of the wall (1) is connected by the chain knife (3) running from the bottom up. To the top, the wall (1) and the bottom chain knife (3) run down at the same time. A prefabricated underground building according to claim 1, wherein the interfaces at both ends of the wall (1-1) are divided into three structures: A, B and C: A, one end is a groove, and the other end is It is a convex part; B, both ends are convex parts; C, both ends are grooves. A prefabricated underground building according to claim 2, wherein said wall (1-2) and cross wall (1-3) are each composed of a wall (1-1). A fabricated underground building according to claim 1, wherein said one-word interface is applied to a connection having two walls (1) at the interface. A prefabricated underground building according to claim 1, wherein said 接口 word interface is divided into two structures A and B: A, a connection applied to two walls (1) at the interface; B, application There are three wall (1) connections at the interface. A prefabricated underground building according to claim 1, wherein said cross interface is divided into two structures A and B: A, a connection applied to three walls (1) at the interface; B, applied The connection of the four walls (1) at the interface. A fabricated underground building according to claim 1, characterized in that said wall (1) is a subterranean continuous wall or a bank. A fabricated underground building according to claim 1, wherein said specific construction method has the following steps: 1) Prefabricated wall (1); 2) Transport the wall (1) to the installation site, first construct the wall with the end interface as the recess (1) 3) Install a chain knife (3) and a chain cutter drive device on the rail (2) at the bottom and side of the wall (1); 4) Install a chain knife (3) and a chain cutter drive device on the bottom and side rails (2) at the groove end interface of the wall (1); 5) The wall (1) bottom chain knife (3) excavates the rock and soil, and the side of the chain knife (3) running from the bottom up to bring the excavated rock soil to the top; 6) The wall (1) and the chain knife (3) at the bottom are lowered together; 7) The wall (1) is lowered to the set depth, and the chain cutter drive and the chain cutter (3) are removed; 8) attaching a chain knife (3) and a chain cutter driving device to the wall (1) whose other interface is a convex portion; 9) Embedding the convex portion on the unconstructed wall (1) into the groove of the concave portion at the interface of the constructed wall (1); 10) The bottom chain knife (3) of the wall (1) excavates the rock and soil, and the chain cutter (3) running from the bottom to the top brings the excavated rock and soil to the top; 11) The wall (1) and the chain knife (3) at the bottom are lowered together; 12) The wall (1) is lowered to the set depth, and the chain cutter drive and the chain cutter (3) are removed; 13) remove the geotechnical soil in the groove cavity at the interface of the two walls (1) and inject the concrete; Repeat the construction of 2) to 13) above until the construction of all walls (1) is completed. A prefabricated underground building according to claim 9, characterized in that after the underground building completes the construction of the wall (1), the rock in the surrounding wall is excavated and the basement is constructed.

Images