CN215672228U - Shield constructs end reinforced structure that starts - Google Patents

Abstract

The utility model provides a reinforcing structure for a shield starting end, which comprises a reinforcing area, a freezing area, a ground connection wall, a portal steel ring and a short sleeve box which are sequentially arranged from inside to outside, wherein the freezing area is positioned at the junction of the reinforcing area and the ground connection wall, the freezing area is constructed by adopting a vertical freezing method, the portal steel ring is arranged on the ground connection wall, the short sleeve box is positioned on the outer side of the portal steel ring and is connected with the portal steel ring, and at least one shield tail steel wire brush is arranged on the inner walls of the short sleeve box and the portal steel ring. The shield starting end reinforcing structure formed by combining the vertical freezing short sleeve and at least two shield tail steel wire brushes effectively reduces the risks of water burst, sand burst, road surface collapse and the like easily occurring before starting and in the starting and tunneling process of the shield machine, can be suitable for different construction environments, and overcomes the defects of the existing shield tunnel portal waterproof device in universality and compatibility.

Description

Shield constructs end reinforced structure that starts

Technical Field

The utility model relates to the technical field of shield engineering construction, in particular to a reinforcing structure for a shield starting end.

Background

In shield launching and receiving preparation work, a waterproof device and a waterproof method adopting a curtain cloth rubber plate and a sector plate are a mature construction process, the tunnel portal launching and receiving waterproof device is used in a combined mode to stop water for a tunnel portal in a shield launching and receiving stage, the curtain cloth rubber plate is used as a first water stop device for the shield launching and receiving to enter and exit the tunnel portal, the curtain cloth rubber plate is usually pressed in a mold in a blocking mode and then connected into a whole frame, the curtain cloth rubber plate is of an inward-turning structure and can be attached to a shield machine shell in a surrounding mode, and the waterproof device is reliable.

The sector plate is used as a second water stop device for starting the shield and receiving the access portal and is made of a steel plate, the sector plate is manufactured in sections according to installation conditions, is welded into a whole by a fixing plate, a turning plate and a pin bush, is inserted into a pin shaft and is fixed on a steel ring of the portal through expansion bolts.

The waterproof process of the combined use of the cord fabric rubber plate and the sector plate can meet the requirement of the shield machine in the starting stage, and the shield machine is not easy to cause water gushing and sand gushing when entering a tunnel portal and other major engineering risks. However, before the shield machine starts to enter the tunnel, risks such as collapse, water burst, sand burst, and road surface collapse are likely to occur between the ground wall and the reinforced area, and at the stage of the shield machine starting to enter the tunnel, risks such as water burst, sand burst, and road surface collapse are likely to occur at the tunnel portal through a gap between the shield machine shell and the tunnel portal steel ring waterproof device, and effective measures need to be taken to ensure the safety of the shield starting.

SUMMERY OF THE UTILITY MODEL

The utility model aims to provide a reinforcing structure for a shield starting end, which effectively reduces the risks of water burst, sand burst, road surface collapse and the like easily occurring before the shield machine starts and in the process of starting and entering a tunnel, meets the requirement on the safety of the shield machine starting end, can adapt to different shield machines and segment size types, can be flexibly installed and used under different soil layer geological conditions, and overcomes the defects of the existing shield tunnel portal waterproof device in universality and compatibility.

In order to achieve the purpose, the utility model provides a shield starting end reinforcing structure which comprises a reinforcing area, a freezing area, a ground connection wall, a portal steel ring and a short sleeve box, wherein the reinforcing area, the freezing area, the ground connection wall, the portal steel ring and the short sleeve box are sequentially arranged from inside to outside, the freezing area is positioned at the junction of the reinforcing area and the ground connection wall, the freezing area is constructed by adopting a vertical freezing method, the portal steel ring is arranged on the ground connection wall, the short sleeve box is positioned on the outer side of the portal steel ring and is connected with the portal steel ring, and at least one shield tail steel wire brush is arranged on the inner walls of the short sleeve box and the portal steel ring.

Optionally, at least two rows of freezing holes distributed vertically are arranged in the freezing area.

Optionally, the thickness of the freezing zone is not less than 2 m.

Optionally, the temperature of the junction of the freezing zone and the underground diaphragm wall is not higher than-5 ℃.

Optionally, each shield tail steel wire brush comprises a plurality of shield tail steel wire brushes, and the plurality of shield tail steel wire brushes are circumferentially arranged along the inner walls of the short sleeve box and the portal steel ring and are welded into a ring.

Optionally, shield tail grease is filled in the shield tail steel wire brush.

Optionally, the shield tail grease is hand-coating type shield tail grease.

Optionally, the inner walls of the short sleeve box and the portal steel ring are both provided with a shield tail steel wire brush, the short sleeve box is reserved with a plurality of grouting holes along the circumferential direction, and the grouting holes are located between the two shield tail steel wire brushes.

Optionally, the diameter of the short sleeve box is the same as that of the portal steel ring.

Optionally, the outer side of the underground diaphragm wall is further provided with a lining wall, and the portal steel ring is located on the lining wall.

In the reinforcing structure for the starting end of the shield provided by the utility model, the reinforcing structure for the starting end of the shield is formed by combining the vertical freezing short sleeve and the water stopping two shield tail steel wire brushes, so that the risks of water burst, sand burst, road surface collapse and the like easily occurring before the starting of the shield machine and in the starting and hole entering process are effectively reduced, and the requirement on the safety of the starting end of the shield machine is met. In addition, the reinforcing structure of the shield starting end can be flexibly installed and used under different shield machines, duct piece size types and different soil layer geological conditions, and overcomes the defects of the existing shield tunnel portal waterproof device in universality and compatibility.

Drawings

Fig. 1 is a schematic diagram of a shield originating end reinforcing structure provided in an embodiment of the present invention;

fig. 2 is a step diagram of a shield tunneling machine initiation method provided in this embodiment.

In the drawings:

10-a reinforcement zone; 20-freezing area; 21-freezing the hole; 30-diaphragm wall; 31-interior lining; 40-portal steel ring; 50-short jacket box; 60-shield tail steel wire brush; 70-grouting holes;

Detailed Description

As described in the background art, the waterproof process of the curtain cloth rubber plate and the sector plate is combined for use, so that the starting stage of the shield machine can be met, and the shield machine is not easy to cause water burst and sand burst and other major engineering risks when entering a tunnel portal. However, before the shield machine starts to enter the tunnel, risks such as collapse, water burst, sand burst, and road surface collapse are likely to occur between the ground wall and the reinforced area, and at the stage of the shield machine starting to enter the tunnel, risks such as water burst, sand burst, and road surface collapse are likely to occur at the tunnel portal through a gap between the shield machine shell and the tunnel portal steel ring waterproof device, and effective measures need to be taken to ensure the safety of the shield starting.

Common reinforcing methods for the shield starting end include a deep stirring method, a high-pressure jet grouting method, an SMW (soil mixing wall) construction method, a freezing method, a grouting method, a plain concrete cast-in-place pile method, a dewatering method and the like. The soil body reinforcement can adopt a reinforcement means combining one or more construction methods. The reinforcement methods can be divided into the following two broad categories: chemical reinforcement (high-pressure rotary spraying method, deep stirring method, grouting plain concrete pile-in-place method and the like) and physical reinforcement (freezing method, dewatering method and the like), in the case of a soft soil area, when the construction of a stirring pile and a rotary spraying pile cannot be carried out due to the restriction of the ground environment, or when serious water and sand leakage is found during the exploration of a hole after chemical reinforcement, the vertical freezing method can be adopted for reinforcement. The vertical freezing method adopts a plate freezing reinforcement theoretical design, a certain number of vertical freezing holes are arranged at the end of the shield tunnel, and a plate frozen soil curtain is formed at a tunnel portal after freezing to resist the water and soil pressure during shield wall breaking, so that soil layer collapse and mud water are prevented from flowing into a shield working well.

Based on the structure, the core idea of the utility model is to provide a reinforcing structure for a shield starting end, wherein the reinforcing structure for the shield starting end comprises a reinforcing area, a freezing area, an underground diaphragm wall, a portal steel ring and a short sleeve box which are sequentially arranged from inside to outside, the freezing area is positioned at the junction of the reinforcing area and the underground diaphragm wall, the freezing area is constructed by adopting a vertical freezing method, the portal steel ring is arranged on the underground diaphragm wall, the short sleeve box is positioned at the outer side of the portal steel ring and is connected with the portal steel ring, and at least one shield tail steel wire brush is arranged on the inner walls of the short sleeve box and the portal steel ring. The shield starting end reinforcing structure formed by combining the vertical freezing short sleeve and the water stopping two shield tail steel wire brushes effectively reduces the risks of water burst, sand burst, road surface collapse and the like easily occurring before the shield machine is started and in the starting and tunnel entering process, and meets the requirement on the safety of the shield machine starting end. In addition, the reinforcing structure of the shield starting end can be flexibly installed and used under different shield machines, duct piece size types and different soil layer geological conditions, and overcomes the defects of the existing shield tunnel portal waterproof device in universality and compatibility.

To further clarify the objects, advantages and features of the present invention, a more particular description of the utility model will be rendered by reference to specific embodiments thereof which are illustrated in the appended drawings. It is to be noted that the drawings are in greatly simplified form and are not to scale, but are merely intended to facilitate and clarify the explanation of the embodiments of the present invention. Further, the structures illustrated in the drawings are often part of actual structures. In particular, the drawings may have different emphasis points and may sometimes be scaled differently.

As used in this application, the singular forms "a," "an," and "the" include plural referents unless the content clearly dictates otherwise. As used in this disclosure, the term "or" is generally employed in its sense including "and/or" unless the content clearly dictates otherwise. As used in this disclosure, the term "plurality" is generally employed in its sense including "at least one" unless the content clearly dictates otherwise. As used in this disclosure, the term "at least two" is generally employed in a sense including "two or more" unless the content clearly dictates otherwise. Furthermore, the terms "first", "second", "third" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated. Thus, features defined as "first", "second", "third" may explicitly or implicitly include one or at least two of the features.

Referring to fig. 1, fig. 1 is a schematic view of a shield originating end reinforcing structure according to an embodiment of the present invention. The embodiment provides a shield starting end reinforcing structure, which is used for reinforcing a shield starting end and comprises a reinforcing area 10, a freezing area 20, a ground connecting wall 30, a portal steel ring 40 and a short sleeve 50 which are sequentially arranged from inside to outside, wherein the freezing area 20 is positioned at the junction of the reinforcing area 10 and the ground connecting wall 30, the freezing area 20 is formed by adopting a vertical freezing method, the portal steel ring 40 is arranged on the ground connecting wall 30, the short sleeve 50 is positioned on the outer side of the portal steel ring 40 and is connected with the portal steel ring 40, and at least one shield tail steel wire brush 60 is arranged on the inner walls of the short sleeve 50 and the portal steel ring 40.

It is noted that in this application and in the following, the terms "inner", "outer" and "outer" are all defined with respect to a tunnel opening from which the shield originates, the terms "inner" and "inner" being in the inward direction along the tunnel opening, and the terms "outer" and "outer" being in the outward direction along the tunnel opening.

Specifically, the underground diaphragm wall 30 is an enclosure structure of the shield starting end. Preferably, an inner lining wall 31 can be further disposed on one side of the diaphragm wall 30 close to the opening, and the portal steel ring 40 is disposed on the inner lining wall 31. In this embodiment, the reinforcing area 10 may be formed by enclosing a triaxial jet mixing pile, and other reinforcing methods may be adopted, for example, a deep mixing method and a high pressure jet mixing method, which are not limited in this application.

Because before the shield constructs the machine and begins to advance the hole, easily take place between ground even wall 30 and the reinforced area 10 and collapse, gush water and gush sand, road surface collapse risk such as, so this application through reinforced area 10 with the juncture of ground even wall 30 sets up freezing junction area 20, can be effectively right ground even wall 30 with consolidate the soil body between the district 10 and consolidate to avoid collapsing, gush water and gush sand, road surface collapse risk such as.

Further, at least two rows of freezing holes 21 which are vertically distributed are arranged in the freezing area 20. In this embodiment, there are 29 freezing holes 21 in two rows, the row spacing is 1.0m, the distance between two adjacent freezing holes 21 is 800mm, and the freezing area 20 is further provided with 4 temperature measuring holes. Preferably, the thickness of the freezing zone 20 is not less than 2 m. It should be understood that the thickness refers to the effective thickness of the freezing zone 20.

The steps of the construction by the vertical freezing method are approximately as follows:

1) drilling holes by using a geological drilling machine, performing hole site lateral inclination and deviation correction on each formed hole, and performing pressure test after putting the freezing pipe into the stratum;

2) and (3) installing a freezing and refrigerating system: arranging a freezing station on a ground freezing platform, carrying out model selection on freezing equipment, carrying out pipeline connection and heat preservation, dissolving calcium chloride, filling fluorine into a unit and oiling;

3) active freeze and maintenance freeze: debugging is carried out after the equipment is installed, the refrigerator is started after checking and confirming that the operating parameters of the circuit system, the cooling water circulation system and the brine circulation system are normal, the refrigerator idles for 1-3 hours, and then the energy, pressure, temperature and motor load state parameters are gradually adjusted, so that the unit operates under the condition of the technical parameters related to the equipment regulations and the operating requirements;

4) and (3) freezing monitoring: temperature measuring holes are respectively arranged inside and outside the vertical shaft, a well position observation hole is arranged in the vertical shaft, and a monitoring system is adopted to monitor the temperature of the soil body in the construction process; monitoring the working state of the freezing period through the temperature difference and the flow of the branch brine to the loop; fixing a steel string type sensor on a temperature measuring pipe in a frozen wall to monitor frost heaving pressure;

5) judging excavation conditions: the active freezing time is not less than 30 days, and the average frozen soil temperature is-10 ℃; according to temperature measurement data of the temperature measurement holes, the average temperature and thickness of the frozen soil wall reach design required values, and an analysis report is written; detecting a detection hole, wherein the detection hole is selected at a position with larger distance between the freezing holes 21 or a position with abnormal freezing;

6) freezing tube treatment: adopting an air pick for tunneling, and adjusting an excavation mode in time according to the reinforcement effect of the exposed soil body and construction monitoring information in tunneling construction; during excavation, the earthwork is placed in a prefabricated soil hopper and is lifted along with excavation, the freezing pipes are protected during the excavation process, and the next freezing pipe can be cut off and recovered when one freezing pipe is recovered;

7) and (3) thawing and performing melt-precipitation grouting treatment: natural thawing is adopted, and after freezing is stopped, the orifice pipe and the freezing pipe which are not used on the wall are cut off immediately; stopping freezing, unfreezing, sealing the freezing holes 21, lining, and filling and grouting.

Preferably, the temperature of the junction between the freezing zone 20 and the diaphragm wall 30 is not higher than-5 ℃.

Preferably, the short casing 50 and the steel portal ring 40 have the same diameter. The short sleeve box 50 and the portal steel ring 40 can be connected by welding, screwing and the like, and the application does not limit the connection.

With reference to fig. 1, each of the shield tail steel wire brushes 60 includes a plurality of shield tail steel wire brushes 60, and the plurality of shield tail steel wire brushes 60 are circumferentially disposed along the inner walls of the short casing 50 and the portal steel ring 40 and are welded to form a ring. The shield tail wire brush 60 is used to prevent water, sand, soil and injection materials from entering the originating well from the shield tail.

In this embodiment, before the shield starts, related technical departments refine the shield construction conditions according to the shield starting conditions, and design the length, size, steel plate thickness and welding position of the shield tail steel brush 60 of the short casing 50 installed outside the portal steel ring 40, so as to provide a construction basis for the welding construction of the portal external short casing 50. The width of the short sleeve box 50 is 50cm, after the short sleeve box 50 is installed, the shield tail steel wire brush 60 in the short sleeve box 50 and the shield tail steel wire brush 60 in the portal steel ring 40 are welded, the length of each shield tail steel wire brush 60 is 42cm, and the shield tail steel wire brushes are welded into a ring.

Preferably, the shield tail steel wire brush 60 is filled with shield tail grease. The shield tail grease has the functions of sealing and lubricating, can effectively protect the shield tail and isolate slurry, ensures the shield to be smoothly propelled, and has the effects of preventing corrosion and reducing abrasion on the shield. In this embodiment, the shield tail grease is hand-coating type shield tail grease.

Preferably, a shield tail steel wire brush 60 is arranged on each of the inner walls of the short sleeve box 50 and the portal steel ring 40, a plurality of grouting holes 70 are reserved in the short sleeve box 50 along the circumferential direction, and the grouting holes 70 are located in a cavity between two shield tail steel wire brushes 60. The cavity between the shield tail steel wire brush 60 can be filled and grouted in the later period through the grouting holes 70, so that underground water, silt and the like can be effectively prevented from flowing into the originating well from the gap between the portal steel ring 40 and the pipe piece. In addition, the grout holes 70 may also be used for emergency grouting.

In this embodiment, the number of the grouting holes 70 is 12, and the 12 grouting holes 70 are uniformly distributed along the axial direction of the short casing 50. Of course, the number and distribution of the grouting holes 70 are not limited in this application.

Accordingly, please refer to fig. 2 in combination with fig. 1. The application also provides a shield tunneling machine starting method, which comprises the following steps:

s1, performing freezing construction at the junction of the reinforcing area 10 and the diaphragm wall 30 to form a freezing area 20;

s2, installing a short sleeve box 50 on the outer side of the portal steel ring 40;

s3, welding a shield tail wire brush 60 on the inner walls of the portal steel ring 40 and the short sleeve box 50 respectively;

and S4, driving the shield tunneling machine to start entering the hole.

Firstly, step S1 is executed, freezing method construction is performed at the boundary of the reinforced area 10 and the diaphragm wall 30, and a freezing area 20 is formed, wherein the freezing area 20 is formed by vertical freezing method construction, and is used for forming a waterproof curtain between the reinforced area 10 and the diaphragm wall 30.

Then, step S2 is executed, a short box 50 is installed on the outer side of the steel portal ring 40, the short box 50 has the same diameter as the steel portal ring 40, and the width thereof can be slightly smaller than the steel portal ring 40, and the short box 50 and the steel portal ring 40 can be connected by welding.

Then, step S3 is executed, a shield tail wire brush 60 is welded on the inner walls of the portal steel ring 40 and the short pouring jacket 50, each shield tail wire brush 60 includes a plurality of shield tail wire brushes 60, and the plurality of shield tail wire brushes 60 are circumferentially arranged along the inner walls of the short pouring jacket 50 and the portal steel ring 40 and are welded into a ring.

Preferably, shield tail grease is applied to 2 shield tail wire brushes 60 in advance, and the gap between the shield shell and the shield tail wire brush 60 is filled.

Preferably, a plurality of grouting holes 70 are reserved in the short casing 50 along the circumferential direction, the grouting holes 70 are located between the two shield tail steel wire brushes 60, and post-filling grouting can be performed between the shield tail steel wire brushes 60 through the grouting holes 70, so that groundwater, silt and the like can be effectively prevented from flowing into the originating well from the gap between the portal steel ring 40 and the pipe piece.

Finally, step S4 is executed to drive the shield tunneling machine to start tunneling.

The S4 specifically includes the following steps:

chiseling a tunnel portal, driving the shield tunneling machine to tunnel, and removing a freezing pipe in front of the shield tunneling machine in advance in the tunneling process of the shield tunneling machine;

closing the hole door;

and stopping freezing and reinforcing.

In the embodiment, the tunnel portal is chiseled off, the vertical freezing pipe at the tunnel portal is pulled out, the shield tunneling machine recovers tunneling, the cutter head rotates at low speed to enter the freezing reinforcement body, the length of the cutter head is 2.5m, the cutter head is in 3 rings (5 rings, 4 rings and 3 rings), and the cutter head does not stop rotating when passing through the freezing reinforcement area 10.

In this embodiment, the width of the arc-shaped steel plate for closing the tunnel door is 25cm, the arc-shaped steel plate is divided into 30 pieces, the outer side wall of the short sleeve box 50 and the +1 ring bearing steel plate are subjected to full-weld welding, the sector plate and the rubber curtain cloth plate are disassembled in a blocking manner, the tunnel door steel plate is welded, and the whole tunnel door is closed.

In this embodiment, after the shield tunneling machine starts to normally propel the cutter head to pass through the freezing and reinforcing area 10, and after the tunnel portal steel plate is welded, the freezing is stopped according to the requirement of the instruction list, and the freezing pipeline is removed.

In summary, the embodiment of the utility model provides a shield starting end reinforcing structure, which is formed by combining a vertical freezing short sleeve and at least two shield tail steel wire brushes, effectively reduces the risks of water burst, sand burst, road surface collapse and the like easily occurring before the shield machine starts and in the starting and tunneling process, and meets the requirement on the safety of the shield machine starting end. In addition, the shield starting end reinforcing structure is suitable for different shield machines and segment size types and can be flexibly installed and used under different soil layer geological conditions, and the defects of the existing shield tunnel portal waterproof device in universality and compatibility are overcome.

The above description is only a preferred embodiment of the present invention, and does not limit the present invention in any way. It will be understood by those skilled in the art that various changes, substitutions and alterations can be made herein without departing from the spirit and scope of the utility model as defined by the appended claims.

Claims (10)

1. A shield constructs end reinforced structure that starts, its characterized in that includes reinforcement district, freezing zone, ground even wall, portal steel ring and short pouring jacket that set gradually from inside to outside, freezing zone is located the juncture of reinforcement district with the ground even wall, and freezing zone adopts perpendicular freezing method construction to form, portal steel ring set up in on the ground even wall, short pouring jacket is located the outside of portal steel ring and is connected with portal steel ring, all be provided with at least one shield tail steel wire brush on the inner wall of short pouring jacket and portal steel ring.

2. The shield starting end reinforcing structure of claim 1, wherein at least two rows of vertically distributed freezing holes are arranged in the freezing zone.

3. The shield originating end reinforcing structure of claim 1, wherein the freezing zone has a thickness of not less than 2 m.

4. The shield originating end reinforcing structure of claim 1, wherein a temperature at a junction of the freezing zone and the diaphragm wall is not higher than-5 ℃.

5. The shield starting end reinforcing structure according to claim 1, wherein each of the shield tail wire brushes comprises a plurality of shield tail wire brushes, and the plurality of shield tail wire brushes are circumferentially arranged along the inner walls of the short casing and the portal steel ring and are welded into a ring.

6. The shield originating end reinforcing structure of claim 5, wherein the shield tail wire brush is internally filled with shield tail grease.

7. The shield originating end reinforcing structure of claim 6, wherein the shield tail grease is a hand-applied shield tail grease.

8. The shield starting end reinforcing structure according to claim 1, wherein a shield tail wire brush is arranged on each of the inner walls of the short sleeve box and the portal steel ring, a plurality of grouting holes are reserved in the short sleeve box along the circumferential direction, and the grouting holes are located between two shield tail wire brushes.

9. The shield originating end strengthening structure of claim 1, wherein the short casing is the same diameter as the portal steel ring.

10. The shield starting end reinforcing structure according to claim 1, wherein an inner lining wall is further arranged on the outer side of the underground diaphragm wall, and the portal steel ring is located on the inner lining wall.

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