The present invention belongs to the technical field of underground engineering, and particularly relates to a mechanical tunneling apparatus and process for a tunnel in a quicksand stratum.
With the development of transportation power construction of China, the scale of urban subway tunnel construction continues to expand, and tunnel construction inevitably passes through a quicksand stratum area. As is known to all, a steel structure may be inserted into a natural quicksand stratum under the action of external force. Meanwhile, excavation disturbance of a tunnel is very prone to causing a large volume of collapse, and it is difficult to form a stable surrounding rock mass. Once an initial stress state of the quicksand stratum changes, it is very prone to causing collapse of a sand layer, endangering the life safety of a constructor.
However, in the prior art, a traditional construction process for a tunnel in a quicksand stratum usually adopts a reinforcement method of “advanced small pipe+large pipe shed+radial grouting”. Such construction process has the disadvantages of high construction cost and long time consumption. Moreover, it is prone to causing disturbance and then a large volume of collapse of the quicksand stratum during tunnel construction, thereby affecting a tunneling speed and safety of the tunnel.
In order to solve the above problems in the prior art, the present invention provides a mechanical tunneling apparatus for a tunnel in a quicksand stratum. The mechanical apparatus of the present invention may effectively increase a tunneling speed and safety for the tunnel in the quicksand stratum, ensure the stability of surrounding rocks of the tunnel, and reduce a large volume of collapse of the quicksand stratum due to tunnel construction disturbance.
To achieve the above objective, the present invention adopts the following technical solutions:
A mechanical tunneling apparatus for a tunnel in a quicksand stratum includes a supporting apparatus, isolating apparatuses, an excavation apparatus, a spraying apparatus, a muck discharging apparatus and a propulsion apparatus, wherein
Preferably, the isolating apparatus includes the circular shield; the circular shield has an outer diameter of 6.77 m, an inner diameter of 6.70 m and a length of 2.00 m; and a plurality of spraying ports are formed between the outer diameter and the inner diameter, to be used for spraying the expansive soil slurry. The isolating apparatuses may be inserted into the quicksand stratum in advance to isolate stress and strain transfer between the quicksand strata in the excavation area and the non-excavation area;
Preferably, the propulsion apparatus is arranged at the rear end of the circular shield; the propulsion apparatus includes a rear duct piece and a jack; and the rear duct piece is pushed forward by the jack to apply the propulsive force, so as to push the tunneling apparatus forward. The propulsion apparatus is identical to a shield machine.
Preferably, the excavation apparatus includes a cutterhead and a drive apparatus; the cutterhead is provided with a plurality of excavator bucket type cutters; the excavator bucket type cutters communicate with an interior of the cutterhead; the drive apparatus includes a rotating bearing; one end of the rotating bearing is connected with the cutterhead; the other end of the rotating bearing is connected with a power apparatus; the rotating bearing may drive the cutterhead to rotate under the driven of the power apparatus. The excavation surface of the quicksand stratum is effectively segmented using the conical cutterhead, and the quicksands are excavated and collected using the excavator bucket type cutters. The excavator bucket type cutters communicate with the cutterhead, and the excavator bucket type cutters may make the excavated quicksands enter the cutterhead for collection during excavation.
Preferably, the cutterhead is conical, having a bottom diameter of 6.65 m and a height of 1.0 m; and the excavator bucket type cutters are distributed on the conical cutterhead in a cruciform arrangement, and distributed in 4 rings in total with an interval between two rings being 1.0 m.
Preferably, an upper end and a lower end of the cutterhead are embedded into a groove on an inner surface of the shield; a certain gap is formed between the cutterhead and the shield; and the fine brushes are arranged between the cutterhead and the shield. Through sealing with the fine brushes, the quicksands are prevented from blocking the gap.
Preferably, the spraying apparatus includes a conveying pipeline and spraying ports, and an inner surface and an outer surface of the shield and the interior of the cutterhead are all provided with the spraying ports. The expansive soil slurry may be poured into the quicksand stratum using the spraying ports formed in the inner surface and the outer surface of the shield, so as to make the quicksands outside the tunneling apparatus and inside the shield be reinforced and stabilized without being disturbed and destroyed. The expansive soil slurry may be poured into the conical cutterhead using the spraying ports inside the cutterhead, so as to make the tunneled quicksand muck in the conical cutterhead be formed, which is convenient to collect and transport the quicksand muck outside the tunnel through a muck discharging system.
Preferably, the fine brushes are arranged at the spraying ports for preventing the quicksands from blocking the spraying ports.
Preferably, the muck discharging apparatus includes a screw conveyor arranged in the cutterhead; and a belt conveyor is arranged at an end of the screw conveyor. The muck in the cutterhead may be conveyed onto the belt conveyor by the screw conveyor, and then transported outside the tunnel.
The present invention further discloses a mechanical tunneling process for a tunnel in a quicksand stratum, using any one of the above mechanical tunneling apparatuses for the tunnel in the quicksand stratum for construction, and specifically including the following process steps:
Based on a shield tunneling method and a theory of steel structure mechanics, the present invention proposes a mechanical apparatus suitable for tunneling construction in the quicksand stratum. The mechanical apparatus includes the circular shield, the conical cutterhead, the spraying apparatus, the muck discharging apparatus, and the propulsion apparatus. The circular shield may be inserted into the quicksand stratum in advance to isolate stress and strain transfer between the quicksand strata in the excavation area and the non-excavation area. The conical cutterhead uses a cone to effectively segment the excavation surface of the quicksand stratum, and uses the excavator bucket type cutters at an upper part of the cone to excavate and collect the quicksands. The spraying apparatus pours the expansive soil slurry into the quicksand stratum by virtue of the spraying ports formed in the circular shield and the conical cutterhead, so as to make the quicksands outside the tunneling apparatus and inside the circular shield be reinforced and stabilized without being disturbed and destroyed; and therefore, the tunneled quicksand muck in the conical cutterhead be formed, which is convenient to collect and transport the quicksand muck outside the tunnel through the muck discharging system. The muck discharging apparatus conveys the muck onto the belt conveyor by the screw conveyor, and then transports the muck outside the tunnel. The propulsion apparatus, being identical to a shield machine, acts on the rear duct piece, and pushes the rear duct piece forward by the jack to apply the propulsive force, so as to push the tunneling apparatus forward.
The mechanical apparatus of the present invention may effectively increase a tunneling speed and safety for the tunnel in the quicksand stratum, ensure the stability of surrounding rocks of the tunnel, reduce collapse of the quicksand stratum due to tunnel construction, reduce the engineering construction cost and increase the engineering construction speed.
Reference numerals in the drawings: 1. circular shield, 2. conical cutterhead, 3. spraying apparatus, 4. excavator bucket type cutter, 5. screw conveyor, 6. jack, 7. belt conveyor, 8. rotating bearing, 9. rear duct piece, 10. fine brush, and 11. supporting apparatus.
The present invention will be described in detail below. Before the description, it should be understood that the terms used in the specification and the accompanying claims should not be construed as limited to general meaning and dictionary meaning, but should be interpreted according to the corresponding meanings and concepts of the technical aspects of the present invention on the basis of the principle of allowing the inventor to properly define the terms for optimal interpretation. Therefore, the description presented here is merely a preferred example for an illustrative purpose, and is not intended to limit the scope of the present invention, and it should be understood that, without departing from the spirit and the scope of the present invention, other equivalents or modifications can be obtained therefrom.
The following embodiments are merely listed as examples of the implementations of the present invention, and do not suggest any limitation as to the present invention. Those skill in the art can understand that all the alterations without departing from the scope of the essence and conception of the present invention fall within the scope of the protection of the present invention. Unless otherwise specified, the reagents and the instruments used in the following embodiments are all commercially available products.
As shown in
The circular shield has an outer diameter of 6.77 m, an inner diameter of 6.70 m and a length of 2.00 m; and a plurality of spraying ports are distributed between the outer diameter and the inner diameter, to be used for spraying the expansive soil slurry.
The conical cutterhead includes a cone and excavator bucket type cutters; the cone has a bottom diameter of 6.65 m and a height of 1.0 m; the conical cutterhead is embedded into a groove on an inner wall of the circular shield, sealed by the fine brushes; and the excavator bucket type cutters are distributed on the cone in a cruciform arrangement, and distributed in 4 rings in total with an interval between two rings being 1.0 m.
The mechanical apparatus may effectively increase a tunneling speed and safety for the tunnel in the quicksand stratum, ensure the stability of surrounding rocks of the tunnel, reduce collapse of the quicksand stratum due to tunnel construction, reduce the engineering construction cost and increase the engineering construction speed.
A mechanical tunneling process for a tunnel in a quicksand stratum, using the mechanical tunneling apparatuses for the tunnel in the quicksand stratum according to claim 1 for construction, specifically includes the following process steps:
The construction process may effectively increase a tunneling speed and safety for the tunnel in the quicksand stratum, ensure the stability of surrounding rocks of the tunnel, reduce collapse of the quicksand stratum due to tunnel construction, reduce the engineering construction cost and increase the engineering construction speed.
The above embodiments are merely used for illustration of the technical solutions of the present invention, but not limit them. Although the present invention has been described in detail with reference to the foregoing embodiments, those of ordinary skills in the art should understand that: the technical solutions described in the foregoing embodiments may still be modified, or equivalent substitutions to some of the technical features may be performed. However, these modifications or substitutions do not make the essence of the corresponding technical solutions deviate from the spirit and scope of the technical solutions of the embodiments of the present invention.
Number | Date | Country | Kind |
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202110403763.0 | Apr 2021 | CN | national |
The present application is a continuation of PCT application PCT/CN2021/093235 entitled “mechanical tunneling apparatus for tunnel in quicksand stratum, and process” filed on May 12, 2021, which claims priority of Chinese patent application CN202110403763.0, filed on Apr. 15, 2021, the entire contents of which are incorporated herein by reference.
Number | Date | Country | |
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Parent | PCT/CN2021/093235 | May 2021 | US |
Child | 18460340 | US |