CN213510623U

CN213510623U - Tunnel excavating device for hydroelectric engineering

Info

Publication number: CN213510623U
Application number: CN202022695853.5U
Authority: CN
Inventors: 陈涛; 闫生存; 杜鹏侠; 张良; 王兆明; 李萌; 席亚滨; 吴玉杰; 袁超义; 袁鹏; 梁存绍; 邱鸿志; 温哲昊
Original assignee: Sichuan Huaneng Luding Hydropower Co Ltd
Current assignee: Sichuan Huaneng Luding Hydropower Co Ltd
Priority date: 2020-11-20
Filing date: 2020-11-20
Publication date: 2021-06-22
Anticipated expiration: 2030-11-20

Abstract

The utility model discloses a tunnel excavating device for water and electricity engineering relates to tunnel excavation technical field, the utility model discloses a mobile device, controlling means, collection device, active device, auxiliary device and slave unit, the mobile device is including removing the bearing, controlling means is including removing post and support column, remove the post and remove the bearing welding, collection device is including supporting the case, the support column welds with the supporting case, the active device includes the motor support, motor support welds with the supporting case, auxiliary device includes auxiliary bearing, auxiliary bearing welds with the supporting case, the slave unit includes driven bearing, driven bearing welds with the supporting case. The utility model relates to a tunnel excavating device for water and electricity engineering, the rotation of wheel drives whole device and removes, and the rotation of moving bearing can change the moving direction of device, and initiative drill bit and a plurality of driven drill bit can be smashed massive rock, and the collection swash plate can be collected smashing rock.

Description

Tunnel excavating device for hydroelectric engineering

Technical Field

The utility model relates to a tunnel excavation technical field, in particular to tunnel excavating device for hydroelectric engineering.

Background

Hydraulic engineering is an engineering built for controlling and allocating surface water and underground water in nature to achieve the purposes of removing harmful substances and benefiting. Also known as water engineering. Water is a valuable resource essential for human production and life, but its naturally occurring state does not completely meet the needs of human beings. Only when hydraulic engineering is built, water flow can be controlled, flood disasters are prevented, and water quantity is adjusted and distributed to meet the requirements of people on water resources in life and production. Hydraulic engineering needs to build various types of hydraulic buildings such as dams, dikes, spillways, water gates, water inlets, channels, transition troughs, rafts, fishways and the like so as to achieve the aims.

The tunnel excavation device is used for the hydraulic engineering, but large stones are often encountered in the tunnel excavation process, and the existing tunnel excavation device has the defects of inconvenient stone breaking and inconvenient movement.

SUMMERY OF THE UTILITY MODEL

A primary object of the utility model is to provide a tunnel excavating device for water and electricity engineering can effectively solve the problem that has inconvenient rubble and inconvenient removal among the background art.

In order to achieve the above purpose, the utility model adopts the following technical scheme: a tunnel excavating device for hydroelectric engineering comprises a moving device, a control device, a collecting device, a driving device, an auxiliary device and a driven device, wherein the moving device comprises a moving bearing, the control device comprises a moving column and a supporting column, the lower end of the moving column is welded with the upper surfaces of a plurality of moving bearings respectively, the collecting device comprises a supporting box, one end of the supporting column is welded with the surface of the supporting box, the driving device comprises a motor support, the supporting box is of a hollow structure, the lower end of the motor support is welded with the inner surface of the supporting box, the auxiliary device comprises an auxiliary bearing, a plurality of surfaces of the auxiliary bearings are welded with the inner side surface of the supporting box, the driven device comprises a driven bearing, a plurality of surfaces of the driven bearing are welded with the inner side surface of the supporting box, wherein the number of the moving bearings is four, the main effect of removal bearing is the direction of movement that changes the device, and the number of auxiliary bearing and driven bearing is two, and auxiliary bearing's main effect is for providing the holding power for the auxiliary belt, and driven gear rotation is assisted to driven bearing's main effect.

Preferably, the moving device further comprises moving blocks, axles and wheels, wherein the upper surfaces of the moving blocks are welded to the lower surfaces of the moving bearings respectively, rotating holes are formed in one surface of each moving block, the axles are in rotating fit with the rotating holes respectively, two ends of each axle are welded to the inner surfaces of the wheels respectively, the number of the moving blocks and the number of the axles are four, and the moving blocks and the axles are mainly used for providing supporting force for the wheels.

Preferably, the control device further comprises a control box, the upper ends of the plurality of movable columns are welded to the lower surface of the control box, the other ends of the support columns are welded to the surface of the control box, and the control box can control each electrical appliance element.

Preferably, collection device still includes baffle and collection swash plate, a baffle surface and supporting box side surface welding, collect swash plate side surface and supporting box side surface welding, the rock of smashing can be collected to the collection swash plate.

Preferably, the driving device further comprises a motor, a driving shaft, a driving gear, a driving rotating rod and a driving drill bit, the upper end of the motor support is welded to the lower surface of the motor, a motor shaft is arranged on one surface of the motor, one end of the driving shaft is in rotating fit with the motor shaft, the other end of the driving shaft is welded to the surface of the driving gear, one end of the driving rotating rod is welded to the other surface of the driving gear, the other end of the driving rotating rod is welded to the surface of the driving drill bit, and the motor can drive the driving drill bit to crush the rock.

Preferably, the auxiliary device still includes connecting rod, auxiliary gear and auxiliary belt, the driving gear meshes with the auxiliary belt mutually, and is a plurality of connecting rod one end welds with another surface of a plurality of auxiliary bearings respectively, and is a plurality of the connecting rod other end welds with a plurality of auxiliary gear surface respectively, and is a plurality of the auxiliary gear all meshes with the auxiliary belt mutually, and wherein, the number of connecting rod and auxiliary gear is two, and the main effect of connecting rod is for providing holding power for auxiliary gear, and auxiliary gear's main effect is for driving the auxiliary belt and rotate.

Preferably, the driven device further comprises a plurality of supporting rods, driven gears, driven rotating rods and driven drill bits, one end of each supporting rod is welded with the side surface of each driven bearing, the other end of each supporting rod is welded with one surface of each driven gear, one end of each driven rotating rod is welded with the other surface of each driven gear, the other end of each driven rotating rod is welded with the side surface of each driven drill bit, the driven gears are all meshed with the auxiliary belts, wherein, the number of bracing piece, driven gear, driven bull stick and driven drill is two, and the main effect of bracing piece is for providing holding power for driven gear, and driven gear's main effect drives driven drill and rotates, and driven bull stick's main effect provides holding power for driven drill, and driven drill's main effect is smashed the rock.

Compared with the prior art, the utility model discloses following beneficial effect has:

1. the utility model discloses in, through setting up removal bearing and wheel, the rotation of wheel drives whole device and removes, and the rotation of removal bearing can change the moving direction of device, reaches the purpose that facilitates the use.

2. The utility model discloses in, through setting up initiative drill bit and a plurality of driven drill bit, can smash massive rock, reach the purpose of rubble.

3. The utility model discloses in, through setting up collection device, collect the swash plate and can collect the rock of smashing, reach the purpose of retrieving the rock.

Drawings

Fig. 1 is a schematic view of the overall structure of a tunnel excavating device for hydroelectric engineering of the present invention;

fig. 2 is a schematic front view of the tunnel excavating device for hydroelectric engineering of the present invention;

fig. 3 is a left side view structural schematic diagram of the tunnel excavation device for hydroelectric engineering of the present invention;

FIG. 4 is a schematic view of the cross-sectional view taken along line A-A of FIG. 3 according to the present invention;

fig. 5 is a schematic view of a partial enlarged structure at D in fig. 1 according to the present invention.

In the figure: 100. a mobile device; 101. moving the bearing; 102. a moving block; 103. an axle; 104. a wheel; 200. a control device; 201. moving the column; 202. a control box; 203. a support pillar; 300. a collection device; 301. a support box; 302. a baffle plate; 303. collecting the inclined plate; 400. an active device; 401. a motor; 402. a motor bracket; 403. a drive shaft; 404. a driving gear; 405. an active rotating rod; 406. an active drill bit; 500. an auxiliary device; 501. an auxiliary bearing; 502. a connecting rod; 503. an auxiliary gear; 504. an auxiliary belt; 600. a driven device; 601. a driven bearing; 602. a support bar; 603. a driven gear; 604. a driven rotating rod; 605. a driven drill bit.

Detailed Description

In order to make the technical means, creation features, achievement purposes and functions of the present invention easy to understand, the present invention is further described below with reference to the following embodiments.

In the description of the present invention, it should be noted that the terms "upper", "lower", "inner", "outer", "front end", "rear end", "both ends", "one end", "the other end" and the like indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, and are only for convenience of description and simplification of description, but do not indicate or imply that the device or element to which the reference is made must have a specific orientation, be constructed in a specific orientation, and be operated, and thus, should not be construed as limiting the present invention. Furthermore, the terms "first" and "second" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance.

In the description of the present invention, it is to be noted that, unless otherwise explicitly specified or limited, the terms "mounted," "disposed," "connected," and the like are to be construed broadly, and for example, "connected" may be either fixedly connected or detachably connected, or integrally connected; can be mechanically or electrically connected; they may be connected directly or indirectly through intervening media, or they may be interconnected between two elements. The specific meaning of the above terms in the present invention can be understood in specific cases to those skilled in the art.

The first embodiment is as follows:

referring to fig. 1-5, the present invention relates to a tunnel excavating device for hydroelectric engineering, which comprises a moving device 100, a control device 200, a collecting device 300, a driving device 400, an auxiliary device 500 and a driven device 600, wherein the moving device 100 comprises a moving bearing 101, the control device 200 comprises a moving column 201 and a supporting column 203, the lower end of the moving column 201 is welded with the upper surface of the moving bearing 101, respectively, the collecting device 300 comprises a supporting box 301, one end of the supporting column 203 is welded with one surface of the supporting box 301, the driving device 400 comprises a motor bracket 402, the supporting box 301 is a hollow structure, the lower end of the motor bracket 402 is welded with the inner surface of the supporting box 301, the auxiliary device 500 comprises an auxiliary bearing 501, one surface of the auxiliary bearing 501 is welded with the inner side surface of the supporting box 301, the driven device 600 comprises a driven bearing 601, one surface of the driven bearing 601 is welded with the inner side surface of the supporting box 301, the number of the movable bearings 101 is four, the movable bearings 101 mainly serve to change the moving direction of the device, the number of the auxiliary bearings 501 and the number of the driven bearings 601 are two, the auxiliary bearings 501 mainly serve to provide supporting force for the auxiliary belt 504, and the driven bearings 601 mainly serve to assist the rotation of the driven gear 603.

Further, the mobile device 100 further comprises a moving block 102, axles 103 and wheels 104, the upper surfaces of the moving blocks 102 are welded to the lower surfaces of the moving bearings 101, rotating holes are formed in the surfaces of the moving blocks 102, the axles 103 are in rotating fit with the rotating holes, the two ends of each axle 103 are welded to the inner surfaces of the wheels 104, the number of the moving blocks 102 and the number of the axles 103 are four, and the moving blocks 102 and the axles 103 are mainly used for providing supporting force for the wheels 104.

Further, the control device 200 further comprises a control box 202, the upper ends of the plurality of movable columns 201 are welded to the lower surface of the control box 202, the other ends of the support columns 203 are welded to one surface of the control box 202, and the control box 202 can control various electrical components.

Further, the collecting device 300 further comprises a baffle 302 and a collecting inclined plate 303, one surface of the baffle 302 is welded with the side surface of the supporting box 301, the side surface of the collecting inclined plate 303 is welded with the side surface of the supporting box 301, and the collecting inclined plate 303 can collect broken rocks.

Further, the driving device 400 further includes a motor 401, a driving shaft 403, a driving gear 404, a driving rotating rod 405 and a driving drill bit 406, the upper end of the motor support 402 is welded to the lower surface of the motor 401, a motor shaft is arranged on one surface of the motor 401, one end of the driving shaft 403 is rotationally matched with the motor shaft, the other end of the driving shaft 403 is welded to one surface of the driving gear 404, one end of the driving rotating rod 405 is welded to the other surface of the driving gear 404, the other end of the driving rotating rod 405 is welded to one surface of the driving drill bit 406, and the motor 401 can drive the driving drill.

Further, the auxiliary device 500 further includes a connecting rod 502, an auxiliary gear 503 and an auxiliary belt 504, the driving gear 404 is meshed with the auxiliary belt 504, one end of each of the connecting rods 502 is welded to another surface of each of the auxiliary bearings 501, the other end of each of the connecting rods 502 is welded to one surface of each of the auxiliary gears 503, each of the auxiliary gears 503 is meshed with the auxiliary belt 504, the number of the connecting rods 502 and the number of the auxiliary gears 503 are two, the connecting rod 502 mainly functions to provide a supporting force for the auxiliary gear 503, and the auxiliary gear 503 mainly functions to drive the auxiliary belt 504 to rotate.

Further, the driven device 600 further includes support rods 602, driven gears 603, driven rotation rods 604 and driven drills 605, wherein one ends of the plurality of support rods 602 are respectively welded to the side surfaces of the plurality of driven bearings 601, the other ends of the plurality of support rods 602 are respectively welded to one surfaces of the plurality of driven gears 603, one ends of the plurality of driven rotation rods 604 are respectively welded to the other surfaces of the plurality of driven gears 603, the other ends of the plurality of driven rotation rods 604 are respectively welded to the side surfaces of the plurality of driven drills 605, the plurality of driven gears 603 are all engaged with the auxiliary belt 504, the number of the support rods 602, the driven gears 603, the driven rotating rods 604 and the driven drill bits 605 is two, the support rods 602 mainly serve to provide supporting force for the driven gears 603, the driven gears 603 mainly serve to drive the driven drill bits 605 to rotate, the driven rotating rods 604 mainly serve to provide supporting force for the driven drill bits 605, and the driven drill bits 605 mainly serve to crush rocks.

Example two:

please refer to fig. 1-5, the utility model relates to a tunnel excavating device for hydroelectric engineering, wherein the model of motor 401 is YE2-132S1-2, the rotation of wheel 104 can drive the whole device and remove, the rotation of removal bearing 101 can change the moving direction of device, start motor 401 through control box 202, motor 401 drives driving gear 404 and rotates, further drive supplementary area 504 and rotate, through the meshing mutually of supplementary area 504 and driven gear 603, drive driven gear 603 and rotate, make driving bit 406 and driven bit 605 work simultaneously, carry out the rubble, the broken rock is retrieved through collecting swash plate 303.

The basic principles and the main features of the invention and the advantages of the invention have been shown and described above. It will be understood by those skilled in the art that the present invention is not limited to the above embodiments, and that the foregoing embodiments and descriptions are provided only to illustrate the principles of the present invention without departing from the spirit and scope of the present invention. The scope of the invention is defined by the appended claims and equivalents thereof.

Claims

1. A tunneling device for hydroelectric power engineering, comprising a moving device (100), a control device (200), a collection device (300), a driving device (400), an auxiliary device (500) and a driven device (600), characterized in that: the moving device (100) comprises moving bearings (101), the control device (200) comprises moving columns (201) and supporting columns (203), the lower ends of the moving columns (201) are respectively welded with the upper surfaces of the moving bearings (101), the collecting device (300) comprises a supporting box (301), one end of the supporting column (203) is welded with one surface of the supporting box (301), the active device (400) comprises a motor bracket (402), the support box (301) is of a hollow structure, the lower end of the motor bracket (402) is welded with the inner surface of the support box (301), the auxiliary device (500) comprises auxiliary bearings (501), one surface of each of the auxiliary bearings (501) is welded with the inner side surface of the support box (301), the driven device (600) comprises driven bearings (601), and one surface of each of the driven bearings (601) is welded with the inner side surface of the support box (301).

2. A tunneling device for hydroelectric engineering according to claim 1, characterized in that: the moving device (100) further comprises moving blocks (102), axles (103) and wheels (104), wherein the upper surfaces of the moving blocks (102) are welded to the lower surfaces of the moving bearings (101) respectively, rotating holes are formed in one surface of each moving block (102), the axles (103) are in rotating fit with the rotating holes respectively, and two ends of each axle (103) are welded to the inner surfaces of the wheels (104) respectively.

3. A tunneling device for hydroelectric engineering according to claim 1, characterized in that: the control device (200) further comprises a control box (202), the upper ends of the plurality of movable columns (201) are welded to the lower surface of the control box (202), and the other ends of the support columns (203) are welded to one surface of the control box (202).

4. A tunneling device for hydroelectric engineering according to claim 1, characterized in that: the collecting device (300) further comprises a baffle (302) and a collecting inclined plate (303), one surface of the baffle (302) is welded with the side surface of the supporting box (301), and the side surface of the collecting inclined plate (303) is welded with the side surface of the supporting box (301).

5. A tunneling device for hydroelectric engineering according to claim 1, characterized in that: the driving device (400) further comprises a motor (401), a driving shaft (403), a driving gear (404), a driving rotating rod (405) and a driving drill bit (406), the upper end of the motor support (402) is welded to the lower surface of the motor (401), a motor shaft is arranged on one surface of the motor (401), one end of the driving shaft (403) is in rotating fit with the motor shaft, the other end of the driving shaft (403) is welded to one surface of the driving gear (404), one end of the driving rotating rod (405) is welded to the other surface of the driving gear (404), and the other end of the driving rotating rod (405) is welded to one surface of the driving drill bit (406).

6. A tunneling device for hydroelectric engineering according to claim 5, wherein: the auxiliary device (500) further comprises a connecting rod (502), auxiliary gears (503) and an auxiliary belt (504), the driving gear (404) is meshed with the auxiliary belt (504), one ends of the connecting rods (502) are respectively welded with the other surfaces of the auxiliary bearings (501), the other ends of the connecting rods (502) are respectively welded with one surfaces of the auxiliary gears (503), and the auxiliary gears (503) are all meshed with the auxiliary belt (504).

7. A tunneling device for hydroelectric engineering according to claim 1, characterized in that: the driven device (600) further comprises a support rod (602), a driven gear (603), a driven rotating rod (604) and a driven drill bit (605), wherein one end of the support rod (602) is welded with the side surface of the driven bearings (601) respectively, the other end of the support rod (602) is welded with the surface of the driven gears (603) respectively, one end of the driven rotating rod (604) is welded with the other surface of the driven gears (603) respectively, the other end of the driven rotating rod (604) is welded with the side surface of the driven drill bit (605) respectively, and the driven gears (603) are meshed with the auxiliary belt (504).