CN114059754B - A power equipment carrying platform for power grid infrastructure - Google Patents

Abstract

The invention provides a power equipment loading platform for power grid infrastructure, which includes a bearing component and a clamping unit. Wherein, the carrying assembly is used to be horizontally arranged between a plurality of fixed poles to carry electric equipment. There are multiple clamping units, and each clamping unit is used to correspond to each fixed rod; each clamping unit includes a first clamp, a second clamp, a telescopic structure and a connecting rod; the first clamp is set Above the second holding clip; there are at least two telescopic structures, and each telescopic structure is respectively connected to the first holding clip and the second holding clip along the vertical direction; the connecting rod is respectively connected to the first holding clip and the bearing assembly. The power equipment mounting platform for power grid infrastructure provided by the present invention changes the previous hoop mode, can ensure convenient adjustment of power equipment at any time during the grid infrastructure construction process, saves time and effort, is simple to operate, and has strong practicability.

Description

A power equipment carrying platform for power grid infrastructure

technical field

The invention belongs to the technical field of grid infrastructure auxiliary equipment, and in particular relates to a power equipment carrying platform for grid infrastructure.

Background technique

Power grid infrastructure projects refer to power grid construction projects with the main goal of completing new construction, expansion, and other expansion of power transmission and distribution capabilities in accordance with certain project rules and procedures and a certain amount of investment. In the grid infrastructure, it is necessary to install a large number of large-scale electrical equipment outdoors, such as transformers.

In the prior art, for the installation of outdoor power equipment, usually a plurality of (at least three) fixing poles, such as utility poles, are arranged first. Then install hoops on each fixed rod, and place the electric equipment in the air through the fixed hoops and the cross arms connecting each hoop. Although this structure can ensure the placement of power equipment, in the process of power grid infrastructure construction, the height of the power equipment placed in the early stage needs to be adjusted according to the continued construction in the later stage, and the structure of the hoop is basically one-time, and it is basically difficult to adjust. Realization, unless it consumes a lot of manpower and material resources, the adjustment process is time-consuming and labor-intensive, and its practicability is poor.

Contents of the invention

An embodiment of the present invention provides a power equipment loading platform for grid infrastructure, aiming at convenient and flexible adjustment of outdoor power equipment during grid infrastructure.

In order to achieve the above object, the technical solution adopted by the present invention is to provide a power equipment carrying platform for grid infrastructure, including:

a load-bearing assembly, configured to be horizontally arranged between a plurality of fixed poles, so as to carry electrical equipment; and

There are multiple holding units, and each holding unit is configured to correspond to each fixing rod; each holding unit includes a first holding clip, a second holding clip, a telescopic structure and a connecting rod; The first holding clip is arranged above the second holding clip; there are at least two telescopic structures, each of the telescopic structures is connected to the first holding clip and the second holding clip along the vertical direction. Two holding clips; the connecting rod is respectively connected to the first holding clip and the bearing assembly;

Wherein, the first holding clip and the second holding clip are used to alternately hold the fixed rod tightly, and driven by the telescopic structure, drive the bearing assembly to move along the vertical direction.

In a possible implementation manner, the first holding clip includes:

first upper half ring;

The second upper half ring, one end of which is hinged to one end of the first upper half ring, the second upper half ring and the first upper half ring are used to fit together and form a first passage through which the fixing rod passes. hole;

There are multiple first damping elements, and the plurality of first damping elements are distributed on the first upper half ring and the second upper half ring, and are connected to the first upper half ring and/or the first upper half ring. The second upper half ring is threaded, each of the first damping members is arranged along the radial direction of the first through hole, and the end located in the first through hole is used to connect with the outer circumference of the fixed rod face to face contact; and

The first locking component is detachably arranged at the other end of the first upper half ring or the second upper half ring to lock the engaged first upper half ring or the second upper half ring tight.

In some embodiments/examples/illustrations, each of the first damping members includes a first damping screw and a first claw;

The first damping screw is threadedly connected to the first upper half ring or the second upper half ring, and one end of the first damping screw located outside the first through hole has a manual part; the first The claw is located in the first through hole, is rotatably connected to the first damping screw, and has a first rough surface for abutting against the outer peripheral surface of the fixing rod.

In a possible implementation manner, the connecting rod is arranged horizontally, and has a first end of the connecting rod and a second end of the connecting rod opposite to the first end of the connecting rod; The hinge shafts of the first upper half ring and the second upper half ring are rotatably connected, and the second end of the connecting rod is used for sliding connection with the bearing assembly.

In a possible implementation manner, the carrying component includes:

flat;

There are multiple sets of sets, and each set of sets is set in one-to-one correspondence with each of the clamping units; each set of sets is horizontally rotated on the flat plate, and each set of sets The piece has a collar through which the second end of the connecting rod passes, and the collar is arranged below the flat plate.

In a possible implementation manner, the second holding clip includes:

first lower half ring;

The second lower half-ring, one end of which is hinged to one end of the first lower half-ring, the second lower half-ring and the first lower half-ring are used to fit together and form a second passage through which the fixing rod passes. hole;

A plurality of second damping elements are provided, and the plurality of second damping elements are distributed on the first lower half ring and the second lower half ring, and are connected to the first lower half ring and/or the second lower half ring. The second lower half ring is threaded, each of the second damping members is arranged radially along the second through hole, and the end located in the second through hole is used to connect with the outer circumference of the fixed rod face contact;

The second locking component is detachably arranged at the other end of the first lower half-ring or the other end of the second lower half-ring to lock the engaged first lower half-ring or the second lower half-ring tight.

In some embodiments/examples/illustrations, each of the second damping members includes a second damping screw and a second claw;

The second damping screw is threadedly connected to the first lower half ring or the second lower half ring, and one end of the second damping screw located outside the second through hole has a manual part; the second The claw is located in the second through hole, is rotatably connected with the second damping screw, and has a second rough surface for abutting against the outer peripheral surface of the fixing rod.

In some embodiments/examples/illustrations, the first locking component and the second locking component have the same structure, and the first locking component or the second locking component includes a locking bolt and lock nut;

Wherein, the other end of the first upper half-ring, the other end of the second upper half-ring, the other end of the first lower half-ring and the other end of the second lower half-ring are provided with The through hole through which the above-mentioned locking bolt passes.

In some embodiments/exemplary/illustrated, the other end of the first upper half-ring and the other end of the second upper half-ring are groove-and-groove butt joint structures;

The other end of the first lower half-ring and the other end of the second lower half-ring are tongue-and-groove butt joint structures.

In a possible implementation manner, there are two telescopic structures;

The fixed end of one of the telescopic structures is fixedly connected to the first lower half ring, and the telescopic end is fixedly connected to the first upper half ring; the fixed end of the other telescopic structure is connected to the second lower half ring Fixedly connected, the telescopic end is fixedly connected to the second upper half ring.

In this implementation/application example, a plurality of clamping units are provided, which can respectively correspond to the fixing rods on the outside of the bearing assembly, and each clamping unit is clamped on the corresponding fixing rod, which can ensure the installation of the bearing assembly and its top. The power equipment is suspended in the air, waterproof and moisture-proof, while ensuring the utilization of its space. Each holding unit is provided with a first holding clip, a second holding clip, a telescopic structure and a connecting rod, the first holding clip and the second holding clip are connected through a telescopic structure, and the first holding clip and the second holding clip can be It is alternately clamping the fixing rod or releasing the clamping with the fixing rod, and then driven by the telescopic structure, it can drive the load-bearing component to move up or down to change the height of the electric equipment. The connecting rod can ensure the connection with the load-bearing component . This kind of structure has changed the way of hoop in the past, can ensure the convenient adjustment of power equipment at any time during the grid infrastructure construction process, saves time and effort, and is easy to operate and has strong practicability.

Description of drawings

Fig. 1 is a schematic structural diagram of a power equipment carrying platform for power grid infrastructure provided by an embodiment of the present invention;

Fig. 2 is a structural schematic diagram of a clamping unit of a power equipment mounting platform for grid infrastructure provided by an embodiment of the present invention;

Fig. 3 is a structural schematic diagram II of a clamping unit of a power equipment mounting platform for grid infrastructure provided by an embodiment of the present invention;

Fig. 4 is a schematic structural diagram of a set of components of a power equipment carrying platform for power grid infrastructure provided by an embodiment of the present invention;

Explanation of reference signs:

10. Bearing component; 11. Flat plate; 12. Set piece;

20. Clamping unit; 21. First clamp; 211. First upper half ring; 212. Second upper half ring; 213. First damping member; 214. First locking assembly; 215. First damping screw ; 216, the first claw; 22, the second clamp; 221, the first lower half ring; 222, the second lower half ring; 223, the second damper; 224, the second locking assembly; 225, the second Damping screw; 226, second claw; 23, telescopic structure; 24, connecting rod;

30, fixed rod.

Detailed ways

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

It should be noted that the terms "length", "width", "height", "thickness", "top", "bottom", "front", "back", "left", "right", "vertical" , "horizontal", "top", "bottom", "inner", "outer", "head", "tail" and other indicated orientations or positional relationships are based on the orientations or positional relationships shown in the drawings, and are only for It is convenient to describe the present invention and simplify the description, but does not indicate or imply that the device or element referred to must have a specific orientation, be constructed and operate in a specific orientation, and thus should not be construed as limiting the present invention.

It should also be noted that terms such as "installation", "connection", "connection", "fixation" and "setup" should be understood in a broad sense unless otherwise clearly stipulated and limited, for example, it can be fixed connection or It is a detachable connection, or integrated; it can be a mechanical connection or an electrical connection; it can be a direct connection or an indirect connection through an intermediary, and it can be the internal communication of two components or the interaction relationship between two components. Those of ordinary skill in the art can understand the specific meanings of the above terms in the present invention according to specific situations.

In addition, the terms "first" and "second" are used for descriptive purposes only, and cannot be interpreted as indicating or implying relative importance or implicitly specifying the quantity of indicated technical features. Thus, a feature defined as "first" and "second" may explicitly or implicitly include one or more of these features. In addition, the meanings of "plurality" and "several" are two or more, unless otherwise clearly and specifically defined.

Please refer to FIG. 1 to FIG. 4 together. Now, a power equipment loading platform for grid infrastructure provided by the present invention will be described. The power equipment carrying platform for grid infrastructure includes a carrying component 10 and a holding unit 20 . Wherein, the carrying assembly 10 is used to be horizontally arranged between a plurality of fixing rods 30 to carry electric equipment. There are multiple clamping units 20, and each clamping unit 20 is used to correspond to each fixed rod 30; each clamping unit 20 includes a first clamp 21, a second clamp 22, a telescopic structure 23 and a connection Rod 24; the first holding clip 21 is arranged above the second holding clip 22; at least two telescopic structures 23 are provided, and each telescopic structure 23 is connected to the first holding clip 21 and the second holding clip 22 along the vertical direction; The rod 24 connects the first clamp 21 and the bearing assembly 10 respectively.

The first holding clip 21 and the second holding clip 22 are used to hug the fixed rod 30 alternately, and driven by the telescopic structure 23, the first holding clip 21 and the second holding clip 22 move alternately along the vertical direction , and drive the carrying assembly 10 to move along the vertical direction, so that the height of the electrical equipment on the carrying assembly 10 is adjusted.

Compared with the prior art, the power equipment carrying platform for power grid infrastructure provided by this embodiment is provided with a plurality of clamping units 20, which can respectively correspond to the fixed rods 30 on the outside of the bearing assembly 10, and each clamping unit 20 embraces Clamping on the corresponding fixing rod 30 can ensure that the bearing assembly 10 and the electrical equipment placed above it are suspended in the air, waterproof and moisture-proof, and also ensure the utilization rate of its space. Each holding unit 20 is provided with a first holding clip 21, a second holding clip 22, a telescopic structure 23 and a connecting rod 24, and the first holding clip 21 and the second holding clip 22 are connected by the telescopic structure 23, and the first The holding clip 21 and the second holding clip 22 can alternately hold the fixed rod 30 or release the holding clip with the fixed rod 30, and then driven by the telescopic structure 23, can drive the bearing assembly 10 to move up or down to change The height of the electrical equipment, the connecting rod 24 can ensure the connection with the bearing assembly 10 . This kind of structure has changed the way of hoop in the past, can ensure the convenient adjustment of power equipment at any time during the grid infrastructure construction process, saves time and effort, and is easy to operate and has strong practicability.

In some embodiments, the above-mentioned first holding clip 21 may adopt a structure as shown in FIG. 2 and FIG. 3 . Referring to FIG. 2 and FIG. 3 , the first clamp 21 includes a first upper half ring 211 , a second upper half ring 212 , a first damping element 213 and a first locking component 214 . Wherein, one end of the second upper half-ring 212 is hinged with one end of the first upper half-ring 211, and the second upper half-ring 212 and the first upper half-ring 211 are used to abut and form a first opening for the fixed rod 30 to pass through. through hole. There are multiple first damping members 213, and the plurality of first damping members 213 are distributed on the first upper half ring 211 and the second upper half ring 212, and are connected with the first upper half ring 211 and/or the second upper half ring 212 are threaded, and each first damping member 213 is arranged along the radial direction of the first through hole, and the end located in the first through hole is used to abut against the outer peripheral surface of the fixing rod 30 . The first locking component 214 is detachably disposed on the other end of the first upper half ring 211 or the other end of the second upper half ring 212 to lock the engaged first upper half ring 211 or the second upper half ring 212 .

Both the first upper half ring 211 and the second upper half ring 212 have a semi-circular shape structure, and the two can be combined to be sleeved on the outside of the fixing rod 30 , which is more convenient for disassembly and assembly. The first locking component 214 can lock the mated first upper half ring 211 and the second upper half ring 212 to ensure the connection strength of the two, thereby ensuring the stability of the clamp. The first damping member 213 can be in contact with the outer peripheral surface of the fixed rod 30 , and can be snapped on the outer peripheral surface of the fixed rod 30 because of its high pressure on the fixed rod 30 , thereby ensuring the stability of the bearing assembly 10 .

In some embodiments, the above-mentioned first damping member 213 may adopt a structure as shown in FIG. 2 and FIG. 3 . Referring to FIG. 2 and FIG. 3 , each first damping member 213 includes a first damping screw 215 and a first claw 216 . Wherein, the first damping screw 215 is threadedly connected with the first upper half ring 211 or the second upper half ring 212, and one end of the first damping screw 215 located outside the first through hole has a manual portion; the first claw 216 is located at the first The through hole is connected to the first damping screw 215 in rotation, and has a first rough surface for abutting against the outer peripheral surface of the fixing rod 30 .

Since the first claw 216 has a first rough surface, it can increase the pressure with the outer peripheral surface of the fixing rod 30 , thereby ensuring the stability of abutting or clamping. The first damping rod can be fed by manually rotating the handle part, and the handle part can be rotated manually or with a tool.

In some embodiments, the above-mentioned connecting rod 24 may adopt a structure as shown in FIG. 2 and FIG. 3 . Referring to Fig. 2 and Fig. 3, the connecting rod 24 is arranged horizontally, has the first end of the connecting rod 24 and the second end of the connecting rod 24 opposite to the first end of the connecting rod 24; The hinge shaft of the ring 211 and the second upper half ring 212 is rotatably connected, and the second end of the connecting rod 24 is used for sliding connection with the bearing assembly 10 .

Because the connecting rod 24 needs to hold up the bearing assembly 10 in the vertical direction, the first end of the connecting rod 24 needs to be fixed, and the axis of the hinge axis of the first upper half ring 211 and the second upper half ring 212 is along the vertical direction. It is arranged in a vertical direction, so when the first end of the connecting rod 24 is rotatably connected to the hinge shaft, it can only rotate horizontally, thereby ensuring its support of the bearing assembly 10 . Moreover, the structure of the connecting rod 24 can also prevent the connecting rod 24 from rotating with the first upper half ring 211 and the second upper half ring 212 , which has higher flexibility and strong practicability.

In addition, the connecting rod 24 may also be directly fixedly connected to the first upper half ring 211 and the second upper half ring 212 .

The connecting rod 24 is connected with the first clamp 21, which can ensure the support of the first clamp 21 and the second clamp 22 at the same time, which can ensure the stability of the support.

In some embodiments, the above-mentioned bearing assembly 10 may adopt the structure shown in FIG. 1 and FIG. 4 . Referring to FIG. 2 and FIG. 3 , the carrier assembly 10 includes a flat plate 11 and a sleeve 12 . Wherein, there are multiple sleeves 12, and each sleeve 12 is arranged in one-to-one correspondence with each holding unit 20; each sleeve 12 is horizontally rotated and arranged on the flat plate 11, and each sleeve 12 has a A collar through which the second end of the connecting rod 24 passes, and the collar is arranged under the plate 11 .

The setting of the flat panel 11 can ensure the placement of the electric equipment, but because the position of the connecting rod 24 is uncertain, so in order to ensure the accurate and fast connection between the connecting rod 24 and the flat panel 11, a sleeve 12 is provided, and the sleeve 12 It can rotate horizontally on the flat plate 11, and has a collar for sliding connection of the second end of the connecting rod 24. This structure can ensure the flexibility of connecting the connecting rod 24 and the flat plate 11, is more convenient for installation, and can offset the connection between the fixed rod 30 and the flat plate 11. The error between the plates 11 and other installation errors have a simple structure and strong practicability.

In some embodiments, the above-mentioned second holding clip 22 may adopt the structure shown in FIG. 2 and FIG. 3 . Referring to FIG. 2 and FIG. 3 , the second clamp 22 includes a first lower half ring 221 , a second lower half ring 222 , a second damper 223 and a second locking component 224 . Wherein, one end of the second lower half-ring 222 is hinged with one end of the first lower half-ring 221, and the second lower half-ring 222 and the first lower half-ring 221 are used for abutment, and form a second hole for the fixed rod 30 to pass through. through hole. The second damping member 223 is provided with a plurality of second damping members 223 distributed on the first lower half ring 221 and the second lower half ring 222, and is connected with the first lower half ring 221 and/or the second lower half ring 222 are threaded, each second damper 223 is arranged along the radial direction of the second through hole, and the end located in the second through hole is used to abut against the outer peripheral surface of the fixing rod 30 . The second locking component 224 is detachably disposed on the other end of the first lower half-ring 221 or the other end of the second lower half-ring 222 to lock the engaged first lower half-ring 221 or second lower half-ring 222 .

Both the first lower half-ring 221 and the second lower half-ring 222 have a semi-circular shape structure, and the two can be combined to be sleeved on the outside of the fixing rod 30 , which is more convenient for disassembly and assembly. The second locking component 224 can lock the matched first lower half-ring 221 and the second lower half-ring 222 to ensure the connection strength of the two, thereby ensuring the stability of the clamp. The second damping member 223 can be in contact with the outer peripheral surface of the fixed rod 30 , and because it exerts relatively high pressure on the fixed rod 30 , it can be clipped on the outer peripheral surface of the fixed rod 30 , thereby ensuring the stability of the bearing assembly 10 .

In some embodiments, the above-mentioned second damping member 223 may adopt a structure as shown in FIG. 2 and FIG. 3 . Referring to FIG. 2 and FIG. 3 , each second damping member 223 includes a second damping screw 225 and a second claw 226 . The second damping screw 225 is threadedly connected with the first lower half ring 221 or the second lower half ring 222, and the second damping screw 225 has a hand-operated part at one end outside the second through hole; the second claw 226 is located at the second through hole , and is rotatably connected with the second damping screw 225 , and has a second rough surface for abutting against the outer peripheral surface of the fixing rod 30 .

Since the second claw 226 has a second rough surface, it can increase the pressure with the outer peripheral surface of the fixing rod 30 , thereby ensuring the stability of abutting or clamping. By manually rotating the handle part, the second damping rod can be fed, and the handle part can be rotated manually or with a tool.

In some embodiments, the above-mentioned first locking component 214 and the second locking component 224 may adopt structures as shown in FIG. 2 and FIG. 3 . Referring to FIG. 2 and FIG. 3 , the first locking component 214 and the second locking component 224 have the same structure, and the first locking component 214 or the second locking component 224 includes a locking bolt and a locking nut. Wherein, the other end of the first upper half-ring 211, the other end of the second upper half-ring 212, the other end of the first lower half-ring 221 and the other end of the second lower half-ring 222 are provided with locking bolts to pass through. vias. The structure of the locking bolt and the locking nut has the characteristics of high connection strength, stable connection, low cost and simple operation, which can ensure the stability of the coupling connection between the first holding clip 21 and the second holding clip 22 .

In some embodiments, the first upper half ring 211 , the second upper half ring 212 , the first lower half ring 221 and the second lower half ring 222 may adopt structures as shown in FIG. 2 and FIG. 3 . Referring to FIG. 2 and FIG. 3 , the other end of the first upper half ring 211 and the other end of the second upper half ring 212 are groove-and-groove butt joint structures. The other end of the first lower half-ring 221 and the other end of the second lower half-ring 222 are tongue-and-groove butt joint structures.

The groove-and-groove butt joint structure, taking the first upper half ring 211 and the second upper half ring 212 as an example, the other end of the first upper half ring 211 has a first plug-in male end and a first plug-in female end, and the second The other end of the upper half ring 212 has a second plug female end into which the first plug male end is inserted, and a second plug male end inserted into the first plug female end. This kind of structure can guarantee the stability of the inverse connection of the two, and the connection strength is higher.

The through holes are respectively provided on the first plug male end and the second plug male end for the connection of the first locking component 214 .

In some embodiments, the telescopic structure 23 may adopt the structures shown in FIG. 2 and FIG. 3 . Referring to FIG. 2 and FIG. 3 , there are two telescopic structures 23 . The fixed end of one telescopic structure 23 is fixedly connected to the first lower half-ring 221 , and the telescopic end is fixedly connected to the first upper half-ring 211 . The fixed end of the other telescopic structure 23 is fixedly connected to the second lower half ring 222 , and the telescopic end is fixedly connected to the second upper half ring 212 .

Telescopic structure 23 can adopt hydraulic cylinder, perhaps and electric jack.

This embodiment provides a platform for carrying power equipment for grid infrastructure, and the specific working method is as follows:

1. First place the flat plate 11 between a plurality of fixing rods 30;

2. Fix each holding unit 20 on each fixing rod 30, so that both the first holding clip 21 and the second holding clip 22 are held tightly on the fixing rod 30, and in the process, the connecting rod 24 and the set piece 12 are connected to hold up the flat panel 11;

3. Release the abutment between the first damping member 213 and the fixed rod 30, and control the elongation of each telescopic structure 23, so as to lift each of the first clamps 21 and the flat plate 11 upward to a certain height;

4. Keep the first damping member 213 in contact with the fixed rod 30, and release the contact between the second damper 223 and the fixed rod 30, and control the contraction of each telescopic structure 23, so as to push the second clamps 22 upward. promote;

5. The second damping member 223 continues to abut or engage with the fixing rod 30 .

It should be noted that the above steps are a lifting height, and the specific lifting height can be reciprocated according to the actual needs. If it needs to be moved downward, the principle is the same.

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

Claims (7)

1. A power equipment carrying platform for grid infrastructure, characterized in that it comprises: a load-bearing assembly, configured to be horizontally arranged between a plurality of fixed poles, so as to carry electrical equipment; and There are multiple holding units, and each holding unit is configured to correspond to each fixing rod; each holding unit includes a first holding clip, a second holding clip, a telescopic structure and a connecting rod; The first holding clip is arranged above the second holding clip; there are at least two telescopic structures, each of the telescopic structures is connected to the first holding clip and the second holding clip along the vertical direction. Two holding clips; the connecting rod is respectively connected to the first holding clip and the bearing assembly; The first clamp includes a first upper half ring, a second upper half ring, a first damper and a first locking assembly; one end of the second upper half ring is hinged to one end of the first upper half ring , the second upper half ring and the first upper half ring are used to fit together, and form a first through hole for the fixing rod to pass through; the first damping member is provided with a plurality, and the plurality of the first A damper is distributed on the first upper half-ring and the second upper half-ring, and is threadedly connected with the first upper half-ring and/or the second upper half-ring, each of the first The damping elements are arranged along the radial direction of the first through hole, and the ends located in the first through hole are used to abut against the outer peripheral surface of the fixed rod; the first locking assembly is detachably arranged on The other end of the first upper half ring or the second upper half ring is used to lock the engaged first upper half ring or the second upper half ring; the connecting rod is arranged horizontally and has The first end of the connecting rod and the second end of the connecting rod opposite to the first end of the connecting rod; the first end of the connecting rod is used for the hinge shaft with the first upper half ring and the second upper half ring Rotation connection, the second end of the connecting rod is used for sliding connection with the bearing assembly; the bearing assembly includes a flat plate and a sleeve; there are multiple sleeves, each sleeve and each The clamping units are arranged in one-to-one correspondence; each of the sleeves is horizontally rotated and arranged on the flat plate, and each of the sleeves has a collar through which the second end of the connecting rod passes. The collar is arranged under the plate; Wherein, the first holding clip and the second holding clip are used to alternately hold the fixed rod tightly, and driven by the telescopic structure, drive the bearing assembly to move along the vertical direction. 2. A power equipment carrying platform for grid infrastructure according to claim 1, wherein each of the first damping members comprises a first damping screw and a first claw; The first damping screw is threadedly connected to the first upper half ring or the second upper half ring, and one end of the first damping screw located outside the first through hole has a manual part; the first The claw is located in the first through hole, is rotatably connected to the first damping screw, and has a first rough surface for abutting against the outer peripheral surface of the fixing rod. 3. The power equipment carrying platform for power grid infrastructure as claimed in claim 1, wherein the second holding clip comprises: first lower half ring; The second lower half-ring, one end of which is hinged to one end of the first lower half-ring, the second lower half-ring and the first lower half-ring are used to fit together and form a second passage through which the fixing rod passes. hole; A plurality of second damping elements are provided, and the plurality of second damping elements are distributed on the first lower half ring and the second lower half ring, and are connected to the first lower half ring and/or the second lower half ring. The second lower half ring is threaded, each of the second damping members is arranged radially along the second through hole, and the end located in the second through hole is used to connect with the outer circumference of the fixed rod face contact; The second locking component is detachably arranged at the other end of the first lower half-ring or the other end of the second lower half-ring to lock the engaged first lower half-ring or the second lower half-ring tight. 4. A power equipment carrying platform for grid infrastructure according to claim 3, wherein each of the second damping members comprises a second damping screw and a second claw; The second damping screw is threadedly connected to the first lower half ring or the second lower half ring, and one end of the second damping screw located outside the second through hole has a manual part; the second The claw is located in the second through hole, is rotatably connected to the second damping screw, and has a second rough surface for abutting against the outer peripheral surface of the fixing rod. 5. A power equipment carrying platform for grid infrastructure according to claim 3, characterized in that, the structure of the first locking component is the same as that of the second locking component, and the first locking component or The second locking assembly includes a locking bolt and a locking nut; Wherein, the other end of the first upper half-ring, the other end of the second upper half-ring, the other end of the first lower half-ring and the other end of the second lower half-ring are provided with The through hole through which the above-mentioned locking bolt passes. 6. A kind of power equipment carrying platform for grid infrastructure as claimed in claim 5, characterized in that, the other end of the first upper half ring and the other end of the second upper half ring are groove-and-groove docking structures; The other end of the first lower half-ring and the other end of the second lower half-ring are tongue-and-groove butt joint structures. 7. A kind of electric power equipment carrying platform for grid infrastructure as claimed in claim 3, is characterized in that, two telescopic structures are provided; The fixed end of one of the telescopic structures is fixedly connected to the first lower half ring, and the telescopic end is fixedly connected to the first upper half ring; the fixed end of the other telescopic structure is connected to the second lower half ring Fixedly connected, the telescopic end is fixedly connected to the second upper half ring.

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