CN115288509B - Auxiliary installation equipment for power grid planning - Google Patents

Abstract

The invention provides auxiliary installation equipment for power grid planning, which belongs to the technical field of power grid planning and comprises a support frame body, a blocking frame, a lifter, a clamp holder, a driver and a jacking mechanism; an outlet is formed in one side of the support frame body, a bearing plate and a rotating plate which are arranged at intervals up and down are arranged in the support frame body, a first strip opening and a second strip opening are formed in the bearing plate, travelling wheels are arranged on the support frame body, the separation frame is arranged on the bearing plate, a lifter is arranged below the bearing plate, a supporting block is arranged on the lifter, a clamp holder is arranged on two sides of the rotating plate, and a driver is used for driving the rotating plate to rotate; the jacking mechanism is connected to the support frame body and is positioned below the outlet. The auxiliary installation equipment for power grid planning provided by the invention has the advantages that the telegraph pole is rapidly installed in the hole pile by means of the rotation of the rotating plate, the jacking action of the jacking mechanism and the reciprocating motion of the supporting frame body, so that the installation efficiency is higher; and in the whole installation process, the telegraph pole does not work aloft, and the safety is high.

Description

Auxiliary installation equipment for power grid planning

Technical Field

The invention belongs to the technical field of power grid planning, and more specifically, relates to an auxiliary installation device for power grid planning.

Background Art

Electric poles are a kind of equipment that transmits the voltage of the power grid to households, factories and other places where electricity is used. Due to the particularity of transmitting electric wires, electric poles that are too high are often required for transmission. At present, due to the length and weight of electric poles, it is inconvenient to plant the electric poles in the pile holes. The electric poles are directly erected using a lifting device. After the electric poles are tied with ropes through the lifting device, the electric poles are erected and installed. During construction, the transportation of electric poles, the soil removal of pole ponds, and the lifting of electric poles are essential links in the installation process, resulting in the need for multiple people to work together to complete the installation of electric poles. This installation method is inefficient, and due to the large mass of electric poles, there are safety hazards in the process of transporting and lifting electric poles.

Summary of the invention

The purpose of the present invention is to provide an auxiliary installation device for power grid planning to solve the technical problems existing in the prior art that the efficiency of utility pole installation is low and there are potential safety hazards.

To achieve the above-mentioned purpose, the technical solution adopted by the present invention is: to provide an auxiliary installation equipment for power grid planning, including a support frame, a blocking frame, a lifter, a clamp, a driver and a lifting mechanism; a accommodating space is provided inside the support frame, and an outlet is provided on one side; a bearing plate and a rotating plate arranged at intervals up and down are provided in the accommodating space; the outlet corresponds to the rotating plate; a first long strip opening and a second long strip opening arranged in parallel and adjacent to each other are provided on the bearing plate; a walking wheel is provided on the support frame; the blocking frame is installed on the bearing plate and is located above the first long strip opening; the lifter is installed below the bearing plate; a support block that slides with the second long strip opening is provided on the free end of the lifter, and the upper end face of the support block is an inclined surface extending toward the first long strip opening; the clamper is installed on both sides of the rotating plate for pushing the electric pole to the center; the driver is installed on the support frame and connected to the rotating plate for driving the rotating plate to rotate; the lifting mechanism is connected to the support frame and is located below the outlet.

In a possible implementation, there are two first long strip openings and two second long strip openings, there are two blocking frames and two lifters, and the first long strip openings and the second long strip openings are opened on both sides of the upper end surface of the supporting plate; the two first long strip openings are close to the inner wall of the accommodating space.

In a possible implementation, the inclined surface is an arc-shaped concave surface, and a guiding inclined surface is provided on a side of the blocking frame close to the support block, and the inclination direction of the guiding inclined surface is consistent with the inclination direction of the inclined surface.

In a possible implementation, a partition slope is further provided on the support block and is located on a side of the support block away from the slope; the ratio of the width of the slope to the width of the partition slope is 10:1-15:1.

In a possible implementation, a mounting plate is further provided in the accommodating space, wherein the mounting plate is provided between the supporting plate and the rotating plate, and the mounting plate is provided with the third long strip opening below the first long strip opening; the lower end of the lifter is installed on the mounting plate; a plurality of reinforcing columns are also provided on the mounting plate, and the upper ends of the reinforcing columns are supported on the lower end of the supporting plate.

In a possible implementation, the holder includes:

A first linear drive mechanism is fixedly mounted on the outer side of the support frame, and a connecting hole is opened at the free end;

A connecting rod, one end of which is rotatably connected to the connecting hole, and the other end of which is located in the support frame body; the connecting rod is rotatably connected to the support frame body;

A limit block is fixedly mounted on the other end of the connecting rod and is used for contacting the electric pole.

In a possible implementation, the limit block is provided with a concave surface adapted to fit with the outer wall of the electric pole, and one end of the connecting rod is provided with a torsion spring, which is installed in the connecting hole.

In a possible implementation, the auxiliary installation device for power grid planning further includes:

A booster pusher is installed on the rotating plate and is located at one end of the rotating plate away from the opening; the booster pusher is used to push the electric pole toward the outlet; the booster pusher includes a second linear drive mechanism and a pushing block, and the pushing block is provided with a limiting groove for matching with the end of the electric pole.

In a possible implementation, a storage box is provided on the support frame, and a through hole is opened in the storage box; the fixed end of the jacking mechanism is installed in the storage box, and the free end of the jacking mechanism passes through the through hole.

In a possible implementation, a plurality of vertically arranged elastic support bodies are provided at the lower end of the accommodating space, and the plurality of elastic support bodies are arranged in a rectangular array; and the rotating plate is supported on the plurality of elastic support bodies.

The beneficial effects of the auxiliary installation equipment for power grid planning provided by the present invention are as follows: compared with the prior art, the auxiliary installation equipment for power grid planning provided by the present invention, before installing the electric poles, multiple electric poles are placed on the bearing plate in the support frame and located on one side of the blocking frame, and then moved to the side of the hole pile by the walking wheels; the lifting device is started to make the support block pass through the second long strip opening, and lift up an electric pole, and when the electric pole is higher than the blocking frame, the electric pole enters the blocking frame under the action of the inclined surface, and the electric pole passes through the first long strip opening and falls on the rotating plate, and the clamp is started to push the electric pole to the position where the rotating plate corresponds to the hole pile, and then the driver is started to control the rotating plate to rotate, and the electric pole is inclined. After the pole is in the state, it slides toward the exit, and one end falls into the hole pile after passing through the exit, and then the jacking mechanism is started to contact the pole and start to move toward the side away from the hole pile, so that the pole is completely separated from the support frame; then the support frame is moved in the opposite direction, and the jacking mechanism is made to continuously jack up the pole to a vertical state, so that it can be accurately installed in the hole pile; in this way, the pole is first installed on the bearing plate, and the poles are made to enter the rotating plate one by one, and then the rotation of the rotating plate, the jacking action of the jacking mechanism and the reciprocating motion of the support frame are used to quickly install the pole in the hole pile, and the installation efficiency is high; and in the whole installation process, there is no high-altitude operation on the pole, and the safety is high.

BRIEF DESCRIPTION OF THE DRAWINGS

In order to more clearly illustrate the technical solutions in the embodiments of the present invention, the drawings required for use in the embodiments or the description of the prior art will be briefly introduced below. Obviously, the drawings described below are only some embodiments of the present invention. For ordinary technicians in this field, other drawings can be obtained based on these drawings without paying creative labor.

FIG1 is a schematic diagram of the internal structure of an auxiliary installation device for power grid planning provided by an embodiment of the present invention;

FIG2 is a top view of an auxiliary installation device for power grid planning provided by an embodiment of the present invention;

FIG3 is a partial cross-sectional view of an auxiliary installation device for power grid planning provided by an embodiment of the present invention;

FIG4 is an enlarged view of point A in FIG3 ;

5 is a schematic diagram of a use status of an auxiliary installation device for power grid planning provided by an embodiment of the present invention;

FIG6 is a schematic diagram of the connection between the lifter and the support block provided in an embodiment of the present invention;

FIG. 7 is a schematic diagram of the connection between the first linear drive mechanism and the connecting rod provided in an embodiment of the present invention.

Among them, the reference numerals in the figure are:

100, support frame; 110, accommodating space; 120, exit; 130, carrying plate; 131, first long strip opening; 132, second long strip opening; 140, rotating plate; 150, mounting plate; 160, elastic support body; 170, walking wheel;

200, barrier frame; 210, guide slope;

300, lifter; 310, support block; 320, inclined surface; 330, dividing inclined surface; 340, third long strip opening; 350, reinforcing column; 360, pad;

400, clamp; 410, first linear drive mechanism; 420, connecting rod; 430, limit block; 440, connecting hole; 450, torsion spring;

500, driver;

600, lifting mechanism; 610, storage box;

700, booster pusher; 710, second linear drive mechanism; 720, push block; 730, limit slot;

800. Electric pole.

DETAILED DESCRIPTION

In order to make the technical problems, technical solutions and beneficial effects to be solved by the present invention more clearly understood, the present invention is further described in detail below in conjunction with the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are only used to explain the present invention and are not intended to limit the present invention.

It should be noted that when an element is referred to as being "fixed to" or "disposed on" another element, it can be directly on the other element or indirectly on the other element. When an element is referred to as being "connected to" another element, it can be directly connected to the other element or indirectly connected to the other element.

It should be understood that the terms "length", "width", "up", "down", "front", "back", "left", "right", "vertical", "horizontal", "top", "bottom", "inside", "outside", etc., indicating the orientation or position relationship, are based on the orientation or position relationship shown in the drawings, and are only for the convenience of describing the present invention and simplifying the description, and do not indicate or imply that the device or element referred to must have a specific orientation, be constructed and operated in a specific orientation, and therefore cannot be understood as a limitation on the present invention.

In addition, the terms "first" and "second" are used for descriptive purposes only and should not be understood as indicating or implying relative importance or implicitly indicating the number of the indicated technical features. Therefore, the features defined as "first" and "second" may explicitly or implicitly include one or more of the features. In the description of the present invention, the meaning of "plurality" is two or more, unless otherwise clearly and specifically defined.

Please refer to Figures 1 to 6 for an explanation of the auxiliary installation device for power grid planning provided by the present invention. An auxiliary installation device for power grid planning includes a support frame 100, a blocking frame 200, a lifter 300, a clamp 400, a driver 500 and a lifting mechanism 600; the support frame 100 is provided with a receiving space 110 inside, and an outlet 120 is provided on one side; a bearing plate 130 and a rotating plate 140 arranged at intervals up and down are provided in the receiving space 110; the outlet 120 corresponds to the rotating plate 140; the bearing plate 130 is provided with a first long strip opening 131 and a second long strip opening 132 arranged in parallel and adjacent to each other; the support frame 100 is provided with walking wheels 170; the blocking frame 200 is installed on the bearing plate 130, And it is located above the first long strip opening 131; the lifter 300 is installed below the carrying plate 130; a support block 310 is provided on the free end of the lifter 300, which is slidably matched with the second long strip opening 132, and the upper end surface of the support block 310 is an inclined surface 320 extending toward the first long strip opening 131; the clamper 400 is installed on both sides of the rotating plate 140, and is used to push the electric pole 800 to the center; the driver 500 is installed on the support frame 100 and is connected to the rotating plate 140, and is used to drive the rotating plate 140 to rotate; the lifting mechanism 600 is connected to the support frame 100, and is located below the outlet 120.

Compared with the prior art, the auxiliary installation equipment for power grid planning provided by the present invention is as follows: before installing the utility poles 800, a plurality of utility poles 800 are placed on the bearing plate 130 in the support frame 100 and located on one side of the blocking frame 200, and then moved to the side of the hole pile through the walking wheel 170; the lifting device 300 is started to make the support block 310 pass through the second long strip opening 132, and lift up a utility pole 800, and when the utility pole 800 is higher than the blocking frame 200, the utility pole 800 enters the blocking frame 200 under the action of the inclined surface 320, and the utility pole 800 passes through the first long strip opening 131 and falls on the rotating plate 140, and the clamp 400 is started to push the utility pole 800 to the position of the rotating plate 140 corresponding to the hole pile, and then the driver 500 is started to control the rotating plate 140 to rotate, and the utility pole 800 is in an inclined state. After that, it slides toward the exit 120, and after passing through the exit 120, one end falls into the hole pile, and then the lifting mechanism 600 is started to contact the electric pole 800 and start to move toward the side away from the hole pile, so that the electric pole 800 is completely separated from the support frame 100; then the support frame 100 is moved in the opposite direction, and the lifting mechanism 600 continuously lifts the electric pole 800 to a vertical state, so that it is accurately installed in the hole pile; in this way, the electric pole 800 is first installed on the bearing plate 130, and the electric poles 800 are entered into the rotating plate 140 one by one, and then the electric pole 800 is quickly installed in the hole pile by means of the rotation of the rotating plate 140, the lifting action of the lifting mechanism 600 and the reciprocating motion of the support frame 100, and the installation efficiency is high; and during the entire installation process, there is no high-altitude operation for the electric pole 800, and the safety is high.

The lower end of the jacking mechanism 600 is hinged to the outer surface of the support frame 100, and a limit rod is set between the jacking mechanism 600 and the support frame 100. One end of the limit rod is hinged to the jacking mechanism 600, and the other end is slidably connected to the support frame 100, which is used to adjust the angle of the jacking mechanism 600.

A connecting block is provided on one side of the support frame 100, the connecting block is located below the outlet 120, and the connecting block is rotatably connected to the support frame 100, and the lower end of the lifting mechanism 600 is hinged to the connecting block. A slide groove is provided on the side of the support frame 100, and the upper end of the limit rod is slidably connected to the slide groove.

Please refer to Figures 1 to 3, as a specific implementation of the auxiliary installation equipment for power grid planning provided by the present invention, there are two first long openings 131 and two second long openings 132, two blocking frames 200 and two lifters 300, and the first long openings 131 and the second long openings 132 are opened on both sides of the upper end surface of the supporting plate 130; the two first long openings 131 are close to the inner wall of the accommodating space 110.

First long openings 131 are provided on both sides of the upper end surface of the carrying plate 130 , and two blocking frames 200 are installed on both sides of the carrying plate 130 and are respectively connected to the two first long openings 131 .

Two second long strip openings 132 are provided and respectively installed on the inner side of the first long strip opening 131, and support blocks 310 are installed in the two second long strip openings 132, and two lifters 300 are installed at the lower end of the supporting plate 130, and the lifters 300 are fixedly connected to the support block 310, and are used to push the support block 310 to rise so that the electric pole 800 on the support block 310 moves upward, and then rolls into the blocking frame 200 under the action of the inclined surface 320.

Through this situation, the auxiliary installation device can reliably and efficiently control the utility pole 800 to pass through the first working opening and enter the rotating plate 140.

A backing plate 360 is provided on the lifter 300 for stably lifting the support block 310 and the utility pole 800 .

Please refer to Figures 1 to 4, as a specific implementation of the auxiliary installation equipment for power grid planning provided by the present invention, the inclined surface 320 is an arc-shaped concave surface, and a guide inclined surface 210 is provided on the side of the blocking frame 200 close to the support block 310, and the inclination direction of the guide inclined surface 210 is consistent with the inclination direction of the inclined surface 320.

When the electric pole 800 rolls from the support block 310 toward the blocking frame 200, the arc-shaped concave surface makes the rolling process of the electric pole 800 more stable, and it is not easy to have a strong collision and will not generate noise.

At the same time, the two side surfaces of the upper end of the blocking frame 200 are provided as guiding inclined surfaces 210 , thereby making it easier for the electric pole 800 to enter the blocking frame 200 .

The upper end surfaces of the barrier frame 200 are also provided with guide slopes 210, so that the electric pole 800 can enter the barrier frame 200 more easily. Even when the electric pole 800 is placed at an angle, the guide slopes 210 can still be used to enable the electric pole 800 to enter the barrier frame 200 quickly and accurately.

Please refer to Figure 6, as a specific implementation of the auxiliary installation equipment for power grid planning provided by the present invention, a dividing slope 330 is also provided on the support block 310, and is located on the side of the support block 310 away from the inclined surface 320; the ratio of the width of the inclined surface 320 to the width of the dividing slope 330 is 10:1-15:1.

That is, two inclined surfaces are provided on the support block 310, namely the inclined surface 320 and the separating inclined surface 320. The separating inclined surface 330 is smaller and the inclined surface 320 is larger. The inclined surface 320 supports and carries the electric pole 800, and the separating inclined surface 330 separates two adjacent electric poles 800.

When two adjacent electric poles 800 are close to each other, one of the electric poles 800 is located on the support block 310; the lifter 300 is started to push the support block 310 and the electric pole 800 upward. Since the adjacent electric poles 800 are close to each other, part of the other electric pole 800 is also supported on the support block 310. Therefore, during the upward movement of the support block 310, the two electric poles 800 are quickly separated by the separating slope 330.

The ratio of the inclined surface 320 to the dividing inclined surface 330 is set to 10:1-15:1, so that the inclined surface 320 can support the electric pole 800, while also preventing another electric pole 800 from being excessively squeezed on the dividing inclined surface 330, making it easier for the other electric pole 800 to be separated.

Please refer to Figures 1 to 3, as a specific implementation of the auxiliary installation equipment for power grid planning provided by the present invention, a mounting plate 150 is also provided in the accommodating space 110, and the mounting plate 150 is arranged between the bearing plate 130 and the rotating plate 140, and a third long strip opening 340 below the first long strip opening 131 is provided on the mounting plate 150; the lower end of the lifter 300 is installed on the mounting plate 150; a plurality of reinforcing columns 350 are also provided on the mounting plate 150, and the upper ends of the reinforcing columns 350 are supported on the lower end of the bearing plate 130.

The mounting plate 150 is disposed between the supporting plate 130 and the rotating plate 140 , and a third long opening 340 is opened on the mounting plate 150 below the first long opening 131 , so that the electric pole 800 entering the blocking frame 200 can pass through the first long opening 131 and the third long opening 340 successively and fall onto the rotating plate 140 .

The lifter 300 and the like are mounted on the mounting plate 150 , with the free end facing upward and connected to the support block 310 in the second elongated opening 132 .

A reinforcing column 350 is installed between the mounting plate 150 and the bearing plate 130 to make the bearing plate 130 more stable so as to support a plurality of electric poles 800 .

Please refer to Figures 1 and 3. As a specific embodiment of the auxiliary installation equipment for power grid planning provided by the present invention, the clamp 400 includes a first linear drive mechanism 410, a connecting rod 420 and a limit block 430. The first linear drive mechanism 410 is fixedly installed on the outer surface of the support frame 100, and a connecting hole 440 is opened at the free end; one end of the connecting rod 420 is rotatably connected to the connecting hole 440, and the other end is located in the support frame 100; the connecting rod 420 is rotatably connected to the support frame 100; the limit block 430 is fixedly installed at the other end of the connecting rod 420, for contacting the electric pole 800.

The first linear drive mechanism 410 is fixedly mounted on the outer wall of the support frame 100, and the limit block 430 is located inside the support frame 100 and above the rotating plate 140. The connecting rod 420 passes through one end of the side wall of the support frame 100 and enters into the connecting hole 440 in the free end of the first linear drive mechanism 410, and is rotatably connected to the connecting hole 440. The other end of the connecting rod 420 is connected to the limit block 430.

After the electric pole 800 falls from the carrying plate 130 onto the rotating plate 140 , the first linear drive mechanism 410 is started to push the limit block 430 toward the electric pole 800 through the connecting rod 420 , thereby pushing the electric pole 800 to a suitable working position.

The limiting block 430 is a long strip structure, so the contact area between the limiting block 430 and the electric pole 800 is relatively large, so that the electric pole 800 can move more smoothly on the supporting plate 130 .

When two clamps 400 are provided, the electric pole 800 is driven to move simultaneously by the two clamps 400 located on both sides of the rotating plate 140, so that the effect of controlling and driving the electric pole 800 to move is more accurate.

The connecting rod 420 is rotatably connected to the free end of the first linear drive mechanism 410. When the rotating plate 140 slightly contacts the stop block 430 during rotation, the stop block 430 and the connecting rod 420 rotate to avoid the rotation to a certain extent. The avoidance angle is small.

Please refer to Figures 3, 5 and 7, which are a specific implementation of the auxiliary installation equipment for power grid planning provided by the present invention. The limit block 430 is provided with a concave surface for adapting to the outer wall of the utility pole 800, and a torsion spring 450 is provided at one end of the connecting rod 420, and the torsion spring 450 is installed in the connecting hole 440.

When the first linear drive mechanism 410 drives the limit block 430 to move with the help of the connecting rod 420, the side of the limit block 430 contacts the outer wall of the electric pole 800, which also improves the accuracy and stability of the pushing effect. The side of the limit block is set to be concave and matched with the side of the electric pole 800.

When the rotating plate 140 makes slight contact with the limit block 430 during rotation, the limit block 430 and the connecting rod 420 rotate, thereby driving the torsion spring 450 to rotate together. After the electric pole 800 is installed and the rotating plate 140 is reset, the limit block 430 and the connecting rod 420 also return to their original positions under the action of the restoring force of the torsion spring 450.

Please refer to Figures 1, 3 and 5. As a specific embodiment of the auxiliary installation device for power grid planning provided by the present invention, the auxiliary installation device for power grid planning also includes a booster pusher 700, which is installed on the rotating plate 140 and is located at the end of the rotating plate 140 away from the opening; the booster pusher 700 is used to push the electric pole 800 to move toward the outlet 120; the booster pusher 700 includes a second linear drive mechanism 710 and a pushing block 720, and the pushing block 720 is provided with a limiting groove 730 for adapting to the end of the electric pole 800.

After the driver 500 is started to control the rotating plate 140 to rotate, the electric pole 800 will slide downward along the inclined rotating plate 140 and then enter the hole pile. However, due to the heavy weight of the electric pole 800, it is easy to have a large friction force and cannot slide.

The booster pusher 700 is installed at the end of the rotating plate 140 away from the opening, and the second linear drive mechanism 710 is started to make the push block 720 contact with the electric pole 800 and push the electric pole 800 to move, thereby ensuring that the electric pole 800 moves downward smoothly.

In addition, a limiting groove 730 is provided on the pushing block 720 , and one end of the electric pole 800 enters into the limiting groove 730 , so that the electric pole 800 will not deviate during the movement.

Please refer to Figures 1 and 2. As a specific implementation of the auxiliary installation equipment for power grid planning provided by the present invention, a storage box 610 is provided on the support frame 100, and a through hole is opened on the storage box 610; the fixed end of the jacking mechanism 600 is installed in the storage box 610, and the free end of the jacking mechanism 600 passes through the through hole.

A storage box 610 is arranged at the end of the support frame 100, and a through hole is opened at the upper end of the storage box 610. After the lifting mechanism 600 is installed in the storage box 610, the free end of the lifting mechanism 600 can pass through the through hole and contact the electric pole 800 to lift the electric pole 800.

When the lifting mechanism 600 is not needed, the free end of the lifting mechanism 600 is controlled to retract into the storage box 610 so that the lifting mechanism 600 will not leak out.

The storage box 610 is a long box structure and is located directly below the outlet 120 . The through hole is a long hole that is consistent with the length direction of the long box.

Please refer to Figures 1 and 5. As a specific implementation of the auxiliary installation equipment for power grid planning provided by the present invention, a plurality of vertically arranged elastic support bodies 160 are provided at the lower end of the accommodating space 110, and the plurality of elastic support bodies 160 are arranged in a rectangular array; the rotating plate 140 is supported on the plurality of elastic support bodies 160.

The rotating plate 140 is installed in the accommodating space 110. The rotating plate 140 has rotating shafts on both opposite side surfaces and is rotatably connected to the supporting frame 100. The driver 500 is installed on the outer side of the supporting frame 100, and is thus connected to the rotating plate 140 to drive the rotating plate 140, the electric pole 800, etc. to rotate.

The electric pole 800, the clamp 400 and the booster 700 are all installed on the rotating plate 140, which causes the rotating plate 140 to be heavy as a whole, posing a safety hazard of falling.

Therefore, a plurality of elastic support bodies 160 are installed in the area below the rotating plate 140. The elastic support bodies 160 are vertically arranged. With the help of the plurality of elastic support bodies 160, the rotating plate 140 is protected. The weight of the rotating plate 140 is mainly borne by the rotating shaft, and the elastic support bodies 160 play a relatively small role here. However, once a falling action occurs, the plurality of elastic support bodies 160 jointly support the rotating plate 140, and no major accidents will occur.

When the rotating plate 140 rotates, the lower end surface contacts the multiple elastic support bodies 160 and compresses the elastic support bodies 160 to deform, which can effectively support the rotating plate 140 without hindering the normal operation of the rotating plate 140 and the utility pole 800.

The above are only preferred embodiments of the present invention and are not intended to limit the present invention. Any modifications, equivalent substitutions and improvements made within the spirit and principles of the present invention should be included in the protection scope of the present invention.

Claims (10)

1. An auxiliary installation device for power grid planning, characterized in that it includes a support frame, a blocking frame, a lifter, a clamp, a driver and a lifting mechanism; a accommodating space is provided inside the support frame, and an outlet is provided on one side; a bearing plate and a rotating plate arranged at intervals up and down are provided in the accommodating space; the outlet corresponds to the rotating plate; a first long strip opening and a second long strip opening arranged in parallel and adjacent to each other are provided on the bearing plate; a walking wheel is provided on the support frame; the blocking frame is installed on the bearing plate and is located above the first long strip opening; the lifter is installed below the bearing plate; a support block that slides with the second long strip opening is provided on the free end of the lifter, and the upper end face of the support block is an inclined surface extending toward the first long strip opening; the clamper is installed on both sides of the rotating plate for pushing the electric pole to the center; the driver is installed on the support frame and connected to the rotating plate for driving the rotating plate to rotate; the lifting mechanism is connected to the support frame and is located below the outlet. 2. The auxiliary installation equipment for power grid planning as described in claim 1 is characterized in that there are two first long strip openings and two second long strip openings, there are two blocking frames and two lifters, and the first long strip openings and the second long strip openings are opened on both sides of the upper end surface of the supporting plate; the two first long strip openings are close to the inner wall of the accommodating space. 3. The auxiliary installation equipment for power grid planning as described in claim 2 is characterized in that the inclined surface is an arc-shaped concave surface, and a guide inclined surface is provided on the side of the blocking frame close to the support block, and the inclination direction of the guide inclined surface is consistent with the inclination direction of the inclined surface. 4. The auxiliary installation equipment for power grid planning as described in claim 1 is characterized in that a dividing slope is also provided on the support block, and is located on the side of the support block away from the inclined surface; the ratio of the width of the inclined surface to the width of the dividing slope is 10:1-15:1. 5. The auxiliary installation equipment for power grid planning as described in claim 1 is characterized in that a mounting plate is also provided in the accommodating space, the mounting plate is arranged between the bearing plate and the rotating plate, and a third long strip opening is provided on the mounting plate and is located below the first long strip opening; the lower end of the lifter is installed on the mounting plate; a plurality of reinforcing columns are also provided on the mounting plate, and the upper ends of the reinforcing columns are supported on the lower end of the bearing plate. 6. The auxiliary installation device for power grid planning according to claim 1, characterized in that the holder comprises: A first linear drive mechanism is fixedly mounted on the outer side of the support frame, and a connecting hole is opened at the free end; A connecting rod, one end of which is rotatably connected to the connecting hole, and the other end of which is located in the support frame body; the connecting rod is rotatably connected to the support frame body; A limit block is fixedly mounted on the other end of the connecting rod and is used for contacting the electric pole. 7. The auxiliary installation equipment for power grid planning as described in claim 6 is characterized in that the limit block is provided with a concave surface for adapting to the outer wall of the electric pole, and one end of the connecting rod is provided with a torsion spring, and the torsion spring is installed in the connecting hole. 8. The auxiliary installation device for power grid planning according to claim 1, characterized in that the auxiliary installation device for power grid planning further comprises: A booster pusher is installed on the rotating plate and is located at one end of the rotating plate away from the opening; the booster pusher is used to push the electric pole toward the outlet; the booster pusher includes a second linear drive mechanism and a pushing block, and the pushing block is provided with a limiting groove for matching with the end of the electric pole. 9. The auxiliary installation equipment for power grid planning as described in claim 1 is characterized in that a storage box is provided on the support frame, and a through hole is opened on the storage box; the fixed end of the jacking mechanism is installed in the storage box, and the free end of the jacking mechanism passes through the through hole. 10. The auxiliary installation equipment for power grid planning as described in claim 1 is characterized in that a plurality of vertically arranged elastic support bodies are provided at the lower end of the accommodating space, and the plurality of elastic support bodies are arranged in a rectangular array; the rotating plate is supported on the plurality of elastic support bodies.