CN222785698U - A water conservancy and hydropower line burying equipment - Google Patents

Abstract

The application relates to the technical field of hydropower line burying, and discloses hydropower line burying equipment. According to the application, the lifting center block is fixedly connected to the side surface of the operation panel, the lifting rod is slidably inserted into the side surface of the lifting center block, a plurality of height fixing holes are formed in the side surface of the lifting center block, a plurality of bearing vertical plates are fixedly connected to the side surface of the lifting center block, and sliding transverse grooves are formed in the side surface of the bearing vertical plates. And because of the wheel-shaped structure formed by the guide rod pulley clamping plate, the guide rod pulley rotating shaft and the guide rod pulley, the collision loss is reduced, the resistance is also reduced, and the operation of operators is convenient.

Description

Water conservancy water and electricity buries line equipment

Technical Field

The application belongs to the technical field of hydropower line embedding, and particularly relates to hydropower line embedding equipment.

Background

The water conservancy and hydropower is an important project for construction in China, along with the continuous development of science and continuous progress of economy, the water conservancy and hydropower project is expanding the implementation range continuously, and the operation of construction wires such as embedded cables is needed in the construction process of the water conservancy and hydropower project. The existing line burying equipment for hydraulic engineering construction is often pulled manually or dragged by a vehicle in the practical process.

The hydraulic engineering wire burying device comprises a vehicle body component, wherein moving components are arranged on two sides of the vehicle body component, the wire burying component is arranged at the top of the vehicle body component, a telescopic component is welded on the front face of the vehicle body component, a wire control component is arranged at the bottom of the telescopic component, the vehicle body component comprises a vehicle body platform and handrails, and the handrails are welded on one side of the top of the vehicle body platform. According to the utility model, through the matching arrangement of the wire control assembly, the wire coiled and unreeled in the wire coil can be flattened and outgoing after being taken out, so that the wire is kept in a straight line state, the flatness of the wire is improved, the wire burying distance of the wire is saved, and through the matching arrangement of the telescopic assembly and the vehicle body assembly, the wire outlet of the wire control assembly can be close to the ground of the wire burying pit, horizontal paying-off can be performed in a short distance, the wire is protected, and accidents such as winding of the wire around a roller in the process can be reduced.

However, when the wire is buried in the wire embedding device, an operator often deviates from the direction of the tunnel when moving the wire embedding device in the actual use process, so that the wire is wound or separated from the tunnel, and the wire embedding efficiency is reduced. It is therefore desirable to have a buried wire device that is relatively stable in position throughout the tunnel.

Disclosure of utility model

The application aims to provide a hydropower line burying device for solving the problem that the line burying device can always keep relatively stable and stable with an underground tunnel.

The technical scheme includes that a lifting center block is fixedly connected to the side surface of an operation panel, a lifting rod is connected to the side surface of the lifting center block in a sliding mode, a plurality of height fixing holes are formed in the side surface of the lifting rod, a plurality of bearing vertical plates are fixedly connected to the side surface of the lifting center block, a sliding transverse groove is formed in the side surface of the bearing vertical plate, a sliding cross rod is connected to the sliding transverse groove in a sliding mode through the formed hole groove in a sliding mode, a plug rod is fixedly connected to the side surface of the sliding cross rod in a plug mode, a guide rod is fixedly connected to the side surface of the lifting rod, a plurality of guide rod pulley clamping plates are connected to the side surface of the guide rod in a sliding mode, a guide rod pulley rotating shaft is connected to the side surface of the guide rod pulley clamping plates in a rotating mode in a plug mode, and a guide rod pulley is connected to the side surface of the guide rod pulley rotating shaft in a rotating mode.

Through adopting above-mentioned technical scheme, operating personnel utilizes the operation flat board to connect the lift center piece and makes lifter slide from top to bottom to make and drive the guide bar downwards and need bury the tunnel of line and contact, wherein utilize guide bar pulley splint, guide bar pulley pivot, guide bar pulley's wheel-like structure to contact with the tunnel wall that needs to bury the line, and utilize to bear riser, slip transverse groove, slip peg graft pole on the horizontal pole and the high fixed orifices on the lifter to peg graft, thereby make highly fixed.

The operation panel is used as a bearing panel, and the lifting center block and the lifting rod are in sliding connection so as to drive the guide rod to slide up and down, thereby driving the guide rod to be in contact with a tunnel needing to be buried.

Utilize guide bar pulley splint, guide bar pulley pivot, guide bar pulley on the guide bar to contact with the tunnel of burying the line to form a assistance-localization real-time's device equipment for help in burying the line in-process, can not off tracking direction when operating personnel drags. And because of the wheel-shaped structure formed by the guide rod pulley clamping plate, the guide rod pulley rotating shaft and the guide rod pulley, the collision loss is reduced, the resistance is also reduced, and the operation of operators is convenient.

The height is fixed by utilizing the plugging connection of the plugging connection rod and the height fixing hole, so that the guide rod can be adjusted according to different terrains, and can be contacted with the tunnel.

The bearing vertical plate and the sliding transverse groove are used for connecting the bearing sliding transverse rod. The sliding transverse groove also limits the movement track of the sliding cross rod, so that the sliding transverse groove can move more stably and smoothly.

Through the structure. The guiding rod can be contacted with the tunnel needing to be buried, so that a limited guiding effect is achieved, the relative position of the guiding rod and the tunnel can be kept unchanged in the wire burying process, the wire burying efficiency is guaranteed, and the wire burying device is simple in structure and easy to maintain.

In a preferred embodiment, the side surface of the operation panel is fixedly connected with a plurality of winding rollers, the side surface of the winding rollers is rotatably connected with a supporting plate, the side surface of the operation panel is fixedly connected with a guiding-out table, and the side surface of the operation panel is fixedly connected with a guiding-out slope.

Through adopting above-mentioned technical scheme, operating personnel utilize wire winding gyro wheel support backup pad for the backup pad can rotate, and with the coil of wire on the backup pad. The guide table and the guide slope together form a guide table, so that the wire on the support plate can be pulled out smoothly downwards.

In a preferred embodiment, a plurality of baffle plates of the guiding-out table are fixedly connected to the side surface of the guiding-out table, and a plurality of baffle plates of the guiding-out slope are fixedly connected to the side surface of the guiding-out slope.

By adopting the technical scheme, the guide-out table baffle and the guide-out slope baffle are utilized to prevent the line from escaping from the range, so that the line can be pulled out in one direction.

In a preferred embodiment, a plurality of clamping wheel clamping plates are fixedly connected to the side surface of the guide-out table baffle, a clamping wheel rotating shaft is rotatably inserted into the side surface of the clamping wheel clamping plates, and a guide-out clamping wheel is rotatably inserted into the side surface of the clamping wheel rotating shaft.

Through adopting above-mentioned technical scheme, utilize pinch roller pivot, the derivation pinch roller that pinch roller splint connect, derive the line from deriving between the pinch roller to avoid being used for burying the line and take place the winding when deriving.

In a preferred embodiment, a plurality of support rods are fixedly connected to the side surface of the operation panel, and a connection panel is fixedly connected to one end side surface of the support rods opposite to the operation panel.

By adopting the technical scheme, the support rod is utilized to be connected with the connecting flat plate for moving the rotating wheel component.

In a preferred embodiment, the side surface of the engagement plate is rotatably inserted with a plurality of movable wheel shafts, and a movable wheel connecting clamping plate is fixedly connected to one end side surface of the movable wheel shaft opposite to the engagement plate.

Through adopting above-mentioned technical scheme, utilize to remove round pivot, removal wheel connection splint to connect the wheel that rolls to utilize the rotation of removal round pivot to make it can move towards arbitrary direction, wherein remove the wheel connection splint and regard as the clamping part who connects the wheel.

In a preferred embodiment, the side surface of the movable wheel connecting clamping plate is rotatably inserted with a second movable wheel rotating shaft, the side surface of the second movable wheel rotating shaft is rotatably inserted with a movable wheel, and the second movable wheel rotating shaft is rotatably inserted with a plurality of anti-falling rings relative to one end side surface of the movable wheel.

By adopting the technical scheme, the second moving wheel is connected with the moving wheel through the rotating shaft of the second moving wheel, so that the movement of the device is realized. And uses the anti-falling ring as the anti-falling component.

In a preferred embodiment, a pulling handle is fixedly connected to the side surface of the operation panel.

By adopting the technical scheme, the dragging handle is used as a component dragged by an operator.

In summary, due to the adoption of the technical scheme, the beneficial effects of the application are as follows:

In the application, the operation panel is used as a bearing panel, and the lifting center block and the lifting rod are in sliding connection so as to drive the guide rod to slide up and down, thereby driving the guide rod to be in contact with a tunnel needing to be buried.

Utilize guide bar pulley splint, guide bar pulley pivot, guide bar pulley on the guide bar to contact with the tunnel of burying the line to form a assistance-localization real-time's device equipment for help in burying the line in-process, can not off tracking direction when operating personnel drags. And because of the wheel-shaped structure formed by the guide rod pulley clamping plate, the guide rod pulley rotating shaft and the guide rod pulley, the collision loss is reduced, the resistance is also reduced, and the operation of operators is convenient.

The height is fixed by utilizing the plugging connection of the plugging connection rod and the height fixing hole, so that the guide rod can be adjusted according to different terrains, and can be contacted with the tunnel.

The bearing vertical plate and the sliding transverse groove are used for connecting the bearing sliding transverse rod. The sliding transverse groove also limits the movement track of the sliding cross rod, so that the sliding transverse groove can move more stably and smoothly.

Through the structure. The guiding rod can be contacted with the tunnel needing to be buried, so that a limited guiding effect is achieved, the relative position of the guiding rod and the tunnel can be kept unchanged in the wire burying process, the wire burying efficiency is guaranteed, and the wire burying device is simple in structure and easy to maintain.

Drawings

FIG. 1 is a schematic view of the overall device structure of the present application;

FIG. 2 is a detailed schematic view of the lifting center block of the present application;

FIG. 3 is a detailed schematic of the derivation station of the present application;

FIG. 4 is a detailed schematic of the adapter plate of the present application.

In the figure, the mark is 1, an operation panel; 2, lifting center blocks, 3, lifting rods, 4, height fixing holes, 5, bearing vertical plates, 6, sliding transverse grooves, 7, sliding cross rods, 8, inserting rods, 9, guide rods, 10, guide rod pulley clamping plates, 11, guide rod pulley rotating shafts, 12, guide rod pulleys, 13, winding rollers, 14, supporting plates, 15, a guiding-out table, 16, guiding slopes, 17, guiding-out table baffles, 18, guiding-out slope baffles, 19, clamping wheel clamping plates, 20, clamping wheel rotating shafts, 21, guiding-out clamping wheels, 22, supporting rods, 23, connecting plates, 24, moving wheel rotating shafts, 25, moving wheel connecting clamping plates, 26, second moving wheel rotating shafts, 27, moving wheels, 28, anti-falling rings and 29, and pulling handles.

Detailed Description

For the purpose of making the objects, technical solutions and advantages of the embodiments of the present application more apparent, the technical solutions in the embodiments of the present application will be clearly and completely described in the following in conjunction with the embodiments of the present application, and it is apparent that the described embodiments are some embodiments of the present application, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the application without making any inventive effort, are intended to be within the scope of the application.

With reference to figures 1-4 of the drawings,

In the embodiment, a lifting center block 2 is fixedly connected to the side surface of an operation panel 1, a lifting rod 3 is connected to the side surface of the lifting center block 2 in a sliding and inserting mode, a plurality of height fixing holes 4 are formed in the side surface of the lifting rod 3, a plurality of bearing vertical plates 5 are fixedly connected to the side surface of the lifting center block 2, a sliding transverse groove 6 is formed in the side surface of the bearing vertical plates 5, a sliding transverse rod 7 is connected to the sliding transverse groove 6 in a sliding and inserting mode through the formed hole groove in a sliding and inserting mode, an inserting rod 8 is fixedly connected to the side surface of the sliding transverse rod 7 in a inserting mode, a guide rod 9 is fixedly connected to the side surface of the lifting rod 3, a plurality of guide rod pulley clamping plates 10 are fixedly connected to the side surface of the guide rod 9 in a rotating and inserting mode, and a guide rod pulley rotating shaft 11 is connected to the side surface of the guide rod pulley clamping plates 10 in a rotating and inserting mode.

The operator uses the operation flat plate 1to connect the lifting center block 2 to enable the lifting rod 3 to slide up and down, so as to drive the guide rod 9 to contact with the tunnel needing to be buried, wherein the wheel-shaped structures of the guide rod pulley clamping plate 10, the guide rod pulley rotating shaft 11 and the guide rod pulley 12 are used to contact with the wall of the tunnel needing to be buried, and the height fixing holes 4 on the lifting rod 3 are used for plugging by the bearing vertical plate 5, the sliding transverse groove 6 and the plugging rod 8 on the sliding transverse rod 7, so that the height is fixed.

The operation panel 1 is used as a bearing panel, and the lifting center block 2 and the lifting rod 3 are in sliding connection so as to drive the guide rod 9 to slide up and down, thereby driving the guide rod to be in contact with a tunnel needing to be buried.

The guide rod pulley clamping plate 10, the guide rod pulley rotating shaft 11 and the guide rod pulley 12 on the guide rod 9 are used for being in contact with a wire burying tunnel, so that auxiliary positioning device equipment is formed, and the auxiliary positioning device is used for helping an operator not to deviate in the wire burying process when dragging. And because of the wheel-shaped structure formed by the guide rod pulley clamping plate 10, the guide rod pulley rotating shaft 11 and the guide rod pulley 12, the collision loss is reduced, the resistance is also reduced, and the operation of operators is convenient.

The height is fixed by inserting the inserting connection rod 8 into the height fixing hole 4, so that the guide rod 9 can be adjusted according to different terrains and can be contacted with the tunnel.

The bearing vertical plate 5 and the sliding transverse groove 6 are used for connecting the bearing sliding transverse rod 7. So that the sliding cross bar can drive the inserting connection bar 8 to slide back and forth, thereby realizing the insertion, wherein the sliding cross bar 6 also limits the movement track of the sliding cross bar 7, and the movement is smoother.

Through the structure. The guiding rod 9 can be contacted with the tunnel needing to be buried by an operator, so that a limited guiding effect is achieved, the relative position of the operator and the tunnel can be kept unchanged in the wire burying process, the wire burying efficiency is guaranteed, and the wire burying device is simple in structure and easy to maintain.

The side surface of the operation panel 1 is fixedly connected with a plurality of winding rollers 13, the side surface of the winding rollers 13 is rotatably connected with a supporting plate 14, the side surface of the operation panel 1 is fixedly connected with a guiding-out table 15, and the side surface of the operation panel 1 is fixedly connected with a guiding-out slope 16. The operator supports the support plate 14 with the winding roller 13 so that the support plate 14 can rotate and wind the wire on the support plate 14. The guide-out table 15 forms a guide table together with the guide-out ramp 16, so that the thread on the support plate 14 can be pulled out smoothly downwards.

A plurality of leading-out table baffles 17 are fixedly connected to the side surface of the leading-out table 15, and a plurality of leading-out slope baffles 18 are fixedly connected to the side surface of the leading-out slope 16. The wire is prevented from coming out of the way by the guide-out table baffle 17 and the guide-out ramp baffle 18, so that it can be ensured that the wire is pulled out in one direction.

The side surface of the guiding-out table baffle 17 is fixedly connected with a plurality of clamping wheel clamping plates 19, the side surface of the clamping wheel clamping plates 19 is rotationally inserted with a clamping wheel rotating shaft 20, and the side surface of the clamping wheel rotating shaft 20 is rotationally inserted with a guiding-out clamping wheel 21. The wire is led out from between the leading-out pinch rollers 21 by the pinch roller rotating shaft 20 and the leading-out pinch roller 21 connected by the pinch roller pinch plate 19, thereby avoiding the wire for embedding from winding when being led out.

The side surface of the operation panel 1 is fixedly connected with a plurality of support rods 22, and one end side surface of the support rods 22 opposite to the operation panel 1 is fixedly connected with a connection panel 23. The support bar 22 is connected to a rotating wheel member for movement with a link plate 23.

The side surface of the engagement plate 23 is rotatably inserted with a plurality of movable wheel rotating shafts 24, and one end side surface of the movable wheel rotating shaft 24 opposite to the engagement plate 23 is fixedly connected with a movable wheel connecting clamping plate 25. The rolling wheel is connected by a moving wheel rotating shaft 24 and a moving wheel connecting clamping plate 25, and can move in any direction by the rotation of the moving wheel rotating shaft 24, wherein the moving wheel connecting clamping plate 25 is used as a clamping component for connecting wheels.

The side surface of the moving wheel connecting clamping plate 25 is rotatably inserted with a second moving wheel rotating shaft 26, the side surface of the second moving wheel rotating shaft 26 is rotatably inserted with a moving wheel 27, and the side surface of one end of the second moving wheel rotating shaft 26 opposite to the moving wheel 27 is rotatably inserted with a plurality of anti-falling rings 28. The second moving wheel shaft 26 is used to connect the moving wheel 27, thereby realizing the movement of the device. And the falling off prevention ring 28 is utilized as a falling off prevention member.

A pulling grip 29 is fixedly attached to the side surface of the operating panel 1. The pulling handle 29 is utilized as a means for the operator to pull.

The application relates to an embodiment of water conservancy and hydropower line burying equipment, which is based on the implementation principle that an operator utilizes an operation flat plate 1 to connect a lifting center block 2 to enable a lifting rod 3 to slide up and down, so that a guide rod 9 is driven to contact with a tunnel needing line burying, wherein a wheel-shaped structure of a guide rod pulley clamping plate 10, a guide rod pulley rotating shaft 11 and a guide rod pulley 12 is utilized to contact with a tunnel wall needing line burying, and a bearing vertical plate 5, a sliding transverse groove 6 and a plugging rod 8 on a sliding transverse rod 7 are utilized to plug in with a height fixing hole 4 on the lifting rod 3, so that the height is fixed.

The operation panel 1 is used as a bearing panel, and the lifting center block 2 and the lifting rod 3 are in sliding connection so as to drive the guide rod 9 to slide up and down, thereby driving the guide rod to be in contact with a tunnel needing to be buried.

The guide rod pulley clamping plate 10, the guide rod pulley rotating shaft 11 and the guide rod pulley 12 on the guide rod 9 are used for being in contact with a wire burying tunnel, so that auxiliary positioning device equipment is formed, and the auxiliary positioning device is used for helping an operator not to deviate in the wire burying process when dragging. And because of the wheel-shaped structure formed by the guide rod pulley clamping plate 10, the guide rod pulley rotating shaft 11 and the guide rod pulley 12, the collision loss is reduced, the resistance is also reduced, and the operation of operators is convenient.

The height is fixed by inserting the inserting connection rod 8 into the height fixing hole 4, so that the guide rod 9 can be adjusted according to different terrains and can be contacted with the tunnel.

The bearing vertical plate 5 and the sliding transverse groove 6 are used for connecting the bearing sliding transverse rod 7. So that the sliding cross bar can drive the inserting connection bar 8 to slide back and forth, thereby realizing the insertion, wherein the sliding cross bar 6 also limits the movement track of the sliding cross bar 7, and the movement is smoother.

Through the structure. The guiding rod 9 can be contacted with the tunnel needing to be buried by an operator, so that a limited guiding effect is achieved, the relative position of the operator and the tunnel can be kept unchanged in the wire burying process, the wire burying efficiency is guaranteed, and the wire burying device is simple in structure and easy to maintain.

The foregoing embodiments are merely for illustrating the technical solution of the present application, but not for limiting the same, and although the present application has been described in detail with reference to the foregoing embodiments, it will be understood by those skilled in the art that modifications may be made to the technical solution described in the foregoing embodiments or equivalents may be substituted for parts of the technical features thereof, and that such modifications or substitutions do not depart from the spirit and scope of the technical solution of the embodiments of the present application in essence.

Claims (8)

1. The water conservancy and hydropower line burying device comprises an operation panel (1) and is characterized in that a lifting center block (2) is fixedly connected to the side surface of the operation panel (1), a lifting rod (3) is connected to the side surface of the lifting center block (2) in a sliding mode, a plurality of height fixing holes (4) are formed in the side surface of the lifting rod (3), a plurality of bearing vertical plates (5) are fixedly connected to the side surface of the lifting center block (2), a sliding transverse groove (6) is formed in the side surface of the bearing vertical plates (5), a sliding transverse rod (7) is connected to the sliding transverse groove (6) in a sliding mode through a hole groove formed in the sliding mode, a splicing rod (8) is fixedly connected to the side surface of the sliding transverse rod (7), a guide rod (9) is fixedly connected to the side surface of the lifting rod (3), a plurality of guide rod pulley clamping plates (10) are connected to the side surface of the guide rod pulley clamping plates in a rotating mode, a guide rod pulley rotating shaft (11) is connected to the side surface of the guide rod pulley rotating shaft (12) in a sliding mode, and the guide rod rotating shaft (11) is connected to the side surface of the guide rod pulley rotating shaft (12).

2. The hydropower line burying device according to claim 1, wherein a plurality of winding rollers (13) are fixedly connected to the side surface of the operation panel (1), a supporting plate (14) is rotatably connected to the side surface of the winding rollers (13), a guiding-out table (15) is fixedly connected to the side surface of the operation panel (1), and a guiding-out slope (16) is fixedly connected to the side surface of the operation panel (1).

3. A hydropower line burying device according to claim 2, wherein a plurality of guide-out table baffles (17) are fixedly connected to the side surface of the guide-out table (15), and a plurality of guide-out slope baffles (18) are fixedly connected to the side surface of the guide-out slope (16).

4. A hydropower line burying device according to claim 3, wherein a plurality of pinch roller clamp plates (19) are fixedly connected to the side surface of the guide-out table baffle plate (17), a pinch roller rotating shaft (20) is rotatably inserted into the side surface of the pinch roller clamp plates (19), and a guide-out pinch roller (21) is rotatably inserted into the side surface of the pinch roller rotating shaft (20).

5. The hydropower line burying device according to claim 1, wherein a plurality of support rods (22) are fixedly connected to the side surface of the operation panel (1), and a connecting panel (23) is fixedly connected to the side surface of one end of the support rods (22) opposite to the operation panel (1).

6. A hydropower line burying device according to claim 5, wherein a plurality of movable wheel rotating shafts (24) are rotatably inserted into the side surface of the engagement plate (23), and a movable wheel connecting clamping plate (25) is fixedly connected to one end side surface of the movable wheel rotating shaft (24) opposite to the engagement plate (23).

7. A hydropower line burying device according to claim 6, wherein a second moving wheel rotating shaft (26) is rotatably inserted into a side surface of the moving wheel connecting clamp plate (25), a moving wheel (27) is rotatably inserted into a side surface of the second moving wheel rotating shaft (26), and a plurality of anti-falling rings (28) are rotatably inserted into a side surface of one end of the second moving wheel rotating shaft (26) opposite to the moving wheel (27).

8. The hydropower line burying device according to claim 1, wherein a pulling handle (29) is fixedly connected to the side surface of the operation panel (1).