1. The tunnel excavation method is characterized in that an end face arch part of a tunnel is used as a front supporting arch wall (100), two side parts (200) are excavated at the section of the tunnel, supporting beams (300) are installed along the excavation advancing directions of the two sides, a conveying device (400) is installed on the supporting beams (300), then the middle part (500) of the section of the tunnel is excavated, the conveying device (400) is installed on the supporting beams (300) along the excavation advancing direction of the middle part (500), and gravels excavated in the tunnel are conveyed out of the tunnel to the end face of the tunnel through the conveying device (400).

2. The method of tunneling according to claim 1, comprising the steps of:

s1, anchoring a plurality of advanced support rods on the end face of the tunnel excavation and supporting a template to pour concrete to form an advanced support arch wall (100);

s2, excavating two side parts (200) of the section of the tunnel, paving a reinforcing mesh on the outer side of the side part (200), anchoring through an anchoring rod, and then pouring concrete to form a side support;

s3, installing support beams (300) at intervals on the inner side of the side portion (200), installing a conveying device (400) on the support beams (300), and conveying the gravel soil dug out by the side portion (200) out of the tunnel by the conveying device (400);

s4, digging 10-20m in the side parts (200), excavating the middle part (500), paving a reinforcement cage on the top of the middle part (500) along with the excavation direction of the middle part (500), anchoring by the anchoring rods, pouring concrete to form top support, installing a conveying device (400) on the other side of the support beam (300), and conveying the gravel soil excavated in the middle part (500) out of the tunnel by the conveying device (400).

3. The method of excavating a tunnel according to claim 2, wherein: the supporting beam (300) is a vertical beam or an arc beam; when an arc beam is employed, the outer arc surface of the arc beam faces the middle portion (500), and the conveyor (400) is installed at the middle-lower portion of the support beam (300).

4. The tunnel excavation method according to any one of claims 1 to 3, wherein: the conveying device (400) comprises a support frame (410), a roller (420) arranged on the support frame (410) and a conveying belt (430) sleeved on the roller (420), wherein one end of the support frame (410) is arranged on the support beam (300), and the conveying device further comprises a motor arranged on the support frame (410) and used for driving the roller (420) to rotate.

5. The method of excavating a tunnel according to claim 4, wherein: support frame (410) include crossbeam frame (411), connect a plurality of gyro wheels installation pole (412) on crossbeam frame (411) and connect bracing piece (413) in the crossbeam frame (411) outside, gyro wheel (420) rotate to be installed on gyro wheel installation pole (412), the one end in the crossbeam frame (411) outside and bracing piece (413) is acute angle fixed connection, and the other end joint of crossbeam frame (411) and bracing piece (413) is on supporting beam (300).

6. The method of excavating a tunnel according to claim 5, wherein: the supporting beam (300) is provided with a clamping part, and the clamping part of the conveying device (400) used for installing the middle part (500) is higher than the clamping part of the conveying device (400) used for installing the side part (200).

7. The method of excavating a tunnel according to claim 6, wherein: the joint portion is including joint piece (310) that is used for joint crossbeam frame (411) and support groove (320) that are used for supporting bracing piece (413), joint piece (310) are located the upper portion of supporting groove (320).

8. The method of excavating a tunnel according to claim 7, wherein: be equipped with joint groove (311) on joint piece (310), the tip that crossbeam frame (411) and supporting beam (300) are connected is equipped with and connects groove (311) complex joint strip (414), joint strip (414) are arranged in joint groove (311).

9. The method of excavating a tunnel according to claim 4, wherein: the end parts of the conveying belt (430) are connected through a detachable belt clamping structure (600), and the belt clamping structure (600) comprises connecting cards (610) which are respectively clamped at the two end parts of the conveying belt (430) and a pin shaft (620) which connects the two connecting cards (610).

10. The method of excavating a tunnel according to claim 9, wherein: both sides are equipped with tooth (611) about one end of connecting card (610), tooth (611) card is established in conveyer belt (430), the other end of connecting card (610) is equipped with snare (612) that are used for wearing to establish round pin axle (620), two snare (612) the crisscross setting of connecting card (610).

Background

Tunnels are engineering structures buried in the ground and are a form of human use of underground space. The tunnel can be divided into a traffic tunnel, a hydraulic tunnel, a municipal tunnel, a mine tunnel and a military tunnel. When the tunnel is excavated, a progressive excavation method is adopted, excavated gravel soil and the like need to be continuously conveyed out of the tunnel in the excavation process, and the conventional conveying method generally adopts an engineering vehicle to enter and exit the tunnel for conveying.

However, the inventors have found that the tunnel excavation method in the related art has the following drawbacks: particularly, a tunnel excavation mode of excavating the side first is adopted, and due to the fact that space in the tunnel is limited, an engineering truck cannot conveniently enter or exit the tunnel, and construction efficiency is low.

Disclosure of Invention

In order to improve the excavation efficiency of the tunnel, the application provides a tunnel excavation method.

The application provides a tunnel excavation method, adopts following technical scheme:

a tunnel excavation method includes the steps that advanced support is conducted on an arch portion of a tunnel, two side portions of the tunnel are excavated firstly on a tunnel section, supporting beams are installed along with the excavation advancing directions of two sides, a conveying device is installed on the supporting beams, then the middle portion of the tunnel section is excavated, the conveying device is installed on the supporting beams along with the excavation advancing direction of the middle portion, and gravel soil excavated in the tunnel is conveyed out of the tunnel to the end face of the tunnel through the conveying device.

By adopting the technical scheme: when the avris part and the middle part of excavation tunnel, transport out the tunnel with the gravel soil through conveyer, then the rethread machineshop car transports the gravel soil to other places, can avoid the inconvenient problem of transportation of machineshop car in the avris part, has improved the efficiency of construction in tunnel.

Optionally, the method comprises the following steps: s1, anchoring a plurality of advanced support rods on the end face of tunnel excavation and supporting templates to pour an advanced support arch wall;

s2, excavating two side parts of the section of the tunnel, paving a reinforcing mesh on the outer side of the side part, anchoring through an anchoring rod, and then pouring concrete to form a side support;

s3, mounting support beams at intervals on the inner sides of the side portions, mounting a conveying device on the support beams, and conveying the gravel soil dug out of the side portions out of the tunnel by the conveying device;

s4, digging 10-20m from the side part, digging the middle part, paving a reinforcement cage on the top of the middle part along with the digging direction of the middle part, anchoring by an anchoring rod, pouring concrete to form a top support, installing a conveying device on the other side of the support beam, and conveying the gravel soil dug from the middle part out of the tunnel by the conveying device.

By adopting the technical scheme: when carrying out avris part excavation, every interval certain distance sets up one section avris protection, when the excavation mid portion, equally every interval one section distance sets up one section top and struts, can prevent that the tunnel from collapsing, has improved the security of construction. The excavated gravels are conveyed out of the tunnel through the conveying device, so that the construction efficiency is improved.

Optionally, the supporting beam is a vertical beam or an arc beam; when an arc beam is employed, the outer arc surface of the arc beam faces the middle portion, and the conveyor is installed at the middle-lower portion of the support beam.

By adopting the technical scheme: the supporting beam is used for jacking the top of the tunnel and is used for fixing the side reinforcing mesh and the middle part top reinforcing mesh, so that concrete can be poured conveniently to form side protection and top protection.

Optionally, the conveying device comprises a support frame, a roller arranged on the support frame, a conveying belt sleeved on the roller, and a motor arranged on the support frame and used for driving the roller to rotate, wherein one end of the support frame is arranged on the supporting beam.

By adopting the technical scheme: along with the continuous tunnelling in tunnel, a motor is installed at every a section distance, and a plurality of motors drive the gyro wheel jointly and rotate, and the gyro wheel drives the conveyer belt operation and realizes long distance's transport gravel soil.

Optionally, the support frame includes the crossbeam frame, connects a plurality of gyro wheels installation pole on the crossbeam frame and connects the bracing piece in the crossbeam frame outside, the gyro wheel rotates to be installed on the gyro wheel installation pole, the crossbeam frame outside is acute angle fixed connection with the one end of bracing piece, the other end joint of crossbeam frame and bracing piece is on a fender roof beam.

By adopting the technical scheme: the crossbeam frame is used for installing a plurality of gyro wheel installation poles, all rotates on every gyro wheel installation pole to connect a gyro wheel, overlaps on a plurality of gyro wheels and establishes the conveyer belt and be used for carrying the rubble soil, installs the crossbeam frame of segmentation on a back beam through the mode of joint after tunneling a section distance, then cup joints the conveyer belt again and realizes conveyer's extension, is convenient for along with the continuous tunnelling in tunnel, further long distance transport rubble soil.

Optionally, a clamping portion is arranged on the supporting beam, and the clamping portion for mounting the conveying device of the middle portion is higher than the clamping portion for mounting the conveying device of the side portion.

By adopting the technical scheme: through the mode of joint, be convenient for realize single section conveyer's installation, the operation is convenient.

Optionally, the clamping portion comprises a clamping block for clamping the beam frame and a supporting groove for supporting the supporting rod, and the clamping block is located on the upper portion of the supporting groove.

By adopting the technical scheme: when the installation, through the side with the crossbeam frame with joint piece joint, the tip card of bracing piece is established and is being supported alright realization installation, the operation is convenient in the inslot.

Optionally, a clamping groove is formed in the clamping block, a clamping strip matched with the clamping groove is arranged at the end portion, connected with the supporting beam, of the beam frame, and the clamping strip is arranged in the clamping groove.

By adopting the technical scheme: when carrying out the joint, the joint strip is pegged graft in the joint inslot alright fix the upper portion of crossbeam frame.

Optionally, the tip of conveyer belt is through detachable area card structural connection, area card structure is including blocking respectively and establishing the connection card at conveyer belt tip and the round pin axle of connecting two connection cards.

By adopting the technical scheme: the novel conveying belt can be conveniently detached and butted by arranging the belt clamping structure, so that the conveying belt can be conveniently butted in an extending way.

Optionally, the upper side and the lower side of one end of the connecting clamp are provided with teeth, the teeth are arranged in the conveying belt, the other end of the connecting clamp is provided with a ring sleeve for penetrating the pin shaft, and the ring sleeves of the two connecting clamps are arranged in a staggered manner.

By adopting the technical scheme: when the conveyer belt is extended, the two connecting clamps at the end part of the conveyer belt are butted, the pin shaft is penetrated, and the two ends of the pin shaft are fixed.

In summary, the present application includes at least one of the following beneficial technical effects:

1. when the avris part and the middle part of excavation tunnel, transport out the tunnel with the gravel soil through conveyer, then the rethread machineshop car transports the gravel soil to other places, can avoid the inconvenient problem of transportation of machineshop car in the avris part, has improved the efficiency of construction in tunnel.

2. Through the mode of joint, be convenient for realize single section conveyer's installation, the operation is convenient, and the conveyer of being convenient for transports the rubble to inside extension in tunnel.

3. When carrying out the extension conveyer belt, with two connecting card butt joints of conveyer belt tip back, penetrate the round pin axle and with the both ends of round pin axle fixed can, the operation is convenient.

Drawings

Fig. 1 is a schematic front structural view of an embodiment of the present application.

Fig. 2 is a schematic structural view of a support beam and a conveying device according to an embodiment of the present application.

Fig. 3 is an enlarged schematic structural diagram at a in fig. 2 according to an embodiment of the present application.

Fig. 4 is a schematic view of a clamping structure of a conveyor belt according to an embodiment of the present application.

Reference number specification, 100, advance timbering arch wall; 200. a side portion; 300. supporting the beam; 310. a clamping block; 311. a clamping groove; 320. a support groove; 400. a conveying device; 410. a support frame; 411. a beam frame; 412. a roller mounting rod; 413. a support bar; 414. a clamping strip; 420. a roller; 430. a conveyor belt; 500. a middle portion; 600. a strap clamp structure; 610. connecting a card; 611. teeth; 612. snaring; 620. and (7) a pin shaft.

Detailed Description

The present application is described in further detail below with reference to figures 1-4.

The embodiment of the application discloses a tunnel excavation method, which adopts the following technical scheme:

referring to fig. 1 and 2, a tunnel excavation method, comprising driving front support rods into arch-shaped end surfaces of a tunnel and anchoring them to form a front support, and laying reinforcing mesh to pour concrete to form a front support arch wall 100, preventing collapse of arch portions when excavating the tunnel, excavating both side portions 200 when excavating the tunnel, installing support beams 300 along with the advancing directions of both side excavations, the support beams 300 supporting the top of the tunnel and facilitating the pouring of side reinforcing mesh and top reinforcing mesh to fix the side reinforcing mesh, forming side protection and top protection, installing conveyor 400 on the support beams 300 for conveying crushed earth excavated from the side portions 200, excavating a middle portion 500 of a cross section of the tunnel after excavating one side portion 200, installing conveyor 400 along with the advancing direction of the middle portion 500 on the other side of the support beams 300, excavating the side portions 200 and the middle portion 500 of the tunnel, transport out the tunnel with the gravel soil through conveyer 400, then the rethread machineshop car transports the gravel soil to other places, can avoid the inconvenient problem of transportation of machineshop car in avris part 200, has improved the efficiency of construction in tunnel.

More specifically, the method of this embodiment specifically includes the following steps:

s1, anchoring a plurality of advance support rods on the tunnel excavation end face and supporting the templates to pour concrete to form an advance support arch wall 100, wherein the advance support arch wall is used for supporting the top of the tunnel excavation end face and preventing collapse during excavation;

s2, firstly, digging two side parts 200 of the section of the tunnel, paving reinforcing meshes on the outer sides of the side parts 200, anchoring the reinforcing meshes through anchoring rods, and then pouring concrete to the reinforcing meshes on the sides to form side supports, so that the side surfaces of the side parts 200 can be prevented from collapsing;

s3, installing support beams 300 at intervals on the inner sides of the side parts 200, installing a conveying device 400 on the outer side walls of the support beams 300, and conveying the gravel soil dug out by the side parts 200 out of the tunnel by the conveying device 400;

and S4, digging 10-20m in the side parts 200, excavating the middle part 500, paving a reinforcement cage on the top of the middle part 500 along the excavation direction of the middle part 500, anchoring the reinforcement cage by an anchoring rod, pouring concrete to form a top support, installing a conveying device 400 on the inner side of the support beam 300, and conveying the gravel soil excavated in the middle part 500 out of the tunnel by the conveying device 400.

When carrying out avris part 200 excavation, every interval certain distance sets up one section avris protection, can set up one section avris protection about seting up 5m in this embodiment, when excavation mid portion 500, equally every interval one section distance sets up one section top and struts, also can set up one section top protection for 5m, can prevent that the tunnel from collapsing, has improved the security of construction. The excavated gravels are conveyed out of the tunnel by the conveyor 400, improving the construction efficiency.

Referring to fig. 1 and 2, the support beam 300 is a vertical beam or an arc beam, which is used in this embodiment, and the outer arc surface of the arc beam faces the middle portion 500 of the excavated tunnel, and the conveyor 400 is installed at the middle and lower portion of the support beam 300. The support beam 300 is used for jacking the top of the tunnel, and is used for fixing the side reinforcing mesh and the middle part 500 top reinforcing mesh, so that concrete can be poured conveniently to form side protection and top protection.

Referring to fig. 2 and 3, in order to facilitate the delivery of excavated gravel soil, the delivery device 400 in this embodiment includes a support frame 410, a roller 420 disposed on the support frame 410, and a conveyor belt 430 disposed on the roller 420, wherein one end of the support frame 410 is mounted on the support beam 300, and further includes a motor mounted on the support frame 410 to drive the roller 420 to rotate. The output shaft of the motor is connected with the shaft head of one of the rollers 420 and is used for driving the conveying belt 430 to rotate, the motor is installed at intervals along with continuous tunneling of the tunnel, the rollers 420 are driven by the motors to rotate, and the rollers 420 drive the conveying belt 430 to operate to convey gravel soil in a long distance.

Referring to fig. 2 and 3, in order to facilitate installation of the conveyor 400 in segments, the supporting frame 410 in this embodiment includes a beam frame 411, a plurality of roller mounting rods 412 connected to the beam frame 411, and a supporting rod 413 connected to the outer side of the beam frame 411, wherein the rollers 420 are rotatably mounted on the roller mounting rods 412, the outer side of the beam frame 411 and one end of the supporting rod 413 are fixedly connected at an acute angle, and the other ends of the beam frame 411 and the supporting rod 413 are connected to the supporting beam 300 in a clamping manner. The beam frame 411 is used for mounting a plurality of roller mounting rods 412, each roller mounting rod 412 is rotatably connected with a roller 420, a conveyor belt 430 is sleeved on the rollers 420 for conveying gravel soil, the segmented beam frame 411 is mounted on the support beam 300 in a clamping manner after tunneling for a distance, and then the conveyor belt 430 is sleeved to realize the extension of the conveying device 400, so that the gravel soil can be conveyed for a further long distance.

Referring to fig. 2 and 3, in order to facilitate the installation of the cross-member frame 411, the support beam 300 is provided with a catching portion, which is higher for the installation of the transfer apparatus 400 of the middle portion 500 than for the installation of the transfer apparatus 400 of the side portion 200. The clamping portion includes a clamping block 310 for clamping the beam frame 411 and a supporting groove 320 for supporting the supporting rod 413, and the clamping block 310 is located at the upper portion of the supporting groove 320. When the installation, through with a avris and the joint piece 310 joint of crossbeam frame 411, the tip card of bracing piece 413 is established in supporting groove 320 alright realize the installation, and the operation is convenient.

The clamping block 310 of this embodiment is provided with a clamping groove 311, the end of the beam frame 411 connected to the supporting beam 300 is provided with a clamping strip 414 matched with the clamping groove 311, and the clamping strip 414 is disposed in the clamping groove 311. When the clamping is performed, the clamping bar 414 is inserted into the clamping groove 311, so that the upper portion of the beam frame 411 can be fixed.

Referring to fig. 3 and 4, in order to facilitate the docking of the conveyor belts 430, the ends of the conveyor belts 430 are connected by a detachable belt clamping structure 600, and the belt clamping structure 600 includes connection cards 610 respectively clamped at the ends of the conveyor belts 430 and a pin 620 connecting the two connection cards 610. The new conveying belt 430 can be conveniently butted by arranging the belt clamping structure 600, so that the conveying belt 430 can be conveniently butted in an extending way.

Specifically, the upper side and the lower side of one end of the connecting card 610 are provided with teeth 611, the teeth 611 are clamped in the conveying belt 430, the other end of the connecting card 610 is provided with a ring sleeve 612 for penetrating the pin shaft 620, and the ring sleeves 612 of the connecting card 610 clamped at the end of the conveying belt 430 are arranged in a staggered manner. When the conveyor belt 430 is extended, the two connecting clips 610 at the end of the conveyor belt 430 are butted in a staggered manner, and then the pin 620 is inserted and both ends of the pin 620 are fixed.

The above embodiments are preferred embodiments of the present application, and the protection scope of the present application is not limited by the above embodiments, so: all equivalent changes made according to the structure, shape and principle of the present application shall be covered by the protection scope of the present application.