CN216042989U - Energy-conserving electric power engineering is with laying equipment - Google Patents

Abstract

The utility model discloses laying equipment for energy-saving electric power engineering, which comprises a rod base, wherein the top end of the rod base is provided with an installation structure, an anti-collision structure and a damping structure, the installation structure is positioned at two ends of the anti-collision structure, the damping structure is positioned at one side of the anti-collision structure, and a buffering structure is arranged inside the rod base. Has the advantages that: the shock-absorbing structure is used for buffering the shock force generated when the external shock-absorbing structure collides with the telegraph pole, so that the external shock objects are protected, the shock force is conducted downwards through the shock-absorbing structure, and the shock force received by the telegraph pole is convenient to slow down.

Description

Energy-conserving electric power engineering is with laying equipment

Technical Field

The utility model relates to the technical field of electric power laying, in particular to laying equipment for energy-saving electric power engineering.

Background

The electric power engineering is the engineering related to the production, transportation and distribution of electric energy, and also comprises the engineering of applying electricity as power and energy in various fields in a broad sense, and meanwhile, the engineering of transmitting and transforming electricity can be understood, a wire pole is needed for the transmission of the electric energy, a large number of telegraph poles are arranged in places such as roads, parks, amusement parks, communities and the like, and under some unexpected conditions, vehicles and people passing through the telegraph poles collide with the telegraph poles, so that potential safety hazards are brought to people, the damaged telegraph poles need to be replaced again, and the cost is increased.

An effective solution to the problems in the related art has not been proposed yet.

SUMMERY OF THE UTILITY MODEL

The utility model provides laying equipment for energy-saving electric power engineering, aiming at the problems in the related art and aiming at overcoming the technical problems in the prior related art.

Therefore, the utility model adopts the following specific technical scheme:

the utility model provides an energy-conserving electric power engineering is with laying equipment, includes the pole base, the top of pole base is provided with mounting structure, crashproof structure and shock-absorbing structure, mounting structure is located crashproof structure's both ends, shock-absorbing structure is located one side of crashproof structure, the inside of pole base is provided with buffer structure.

Furthermore, the mounting structure comprises an installation ear ring, a nut and a bolt, the bolt penetrates through the inside of the installation ear ring, and the nut is located at the bottom end of the bolt.

Furthermore, the anti-collision structure is composed of a telegraph pole main body I, anti-collision sliding blocks, limiting blocks and a main connecting rod, wherein the anti-collision sliding blocks are located on one side of the inside of the telegraph pole main body I, the limiting blocks are located at two ends of the anti-collision sliding blocks, and the main connecting rod is located on one side of the anti-collision sliding blocks.

Furthermore, the damping structure is composed of a first connecting rod, a second connecting rod, a first sliding block, a second sliding block, a first spring and a second spring, the first sliding block is located at the top end of the first connecting rod, the first spring is located at the top end of the first sliding block, the second sliding block is located at the bottom end of the second connecting rod, and the second spring is located at the bottom end of the second sliding block.

Furthermore, a first baffle is arranged at the top end of the first spring, and a second baffle is arranged at the bottom end of the second spring.

Further, buffer structure comprises pillar, spring three and sleeve pipe, spring three is located the outside of pillar, the sleeve pipe is located the bottom of pillar.

Furthermore, a second telegraph pole main body is arranged at the top end of the first telegraph pole main body, and a double-faced guide rail is arranged on one side, away from the first connecting rod, of the first sliding block.

Furthermore, the top end of the strut is fixedly connected with the second baffle plate, and the bottom end of the strut is movably connected with the sleeve.

The utility model has the beneficial effects that: through setting up the structural sketch of the energy-conserving laying equipment for electric power engineering who comprises pole base, mounting structure, crashproof structure, shock-absorbing structure, buffer structure, installation earrings, nut, bolt, wire pole main part one and crashproof slider to alleviate the impact force that produces when external and wire pole bump through shock-absorbing structure, realize protecting the wire pole when protecting external impact thing, through buffer structure with vibrations power downwardly conducting, be convenient for slow down the impact force that the wire pole received.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings needed in the embodiments will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments of the present invention, and it is obvious for those skilled in the art to obtain other drawings without creative efforts.

Fig. 1 is a schematic structural diagram of a laying device for energy-saving electric power engineering according to an embodiment of the present invention;

fig. 2 is a schematic structural diagram of a shock-absorbing structure in a laying device for energy-saving electric power engineering according to an embodiment of the utility model;

fig. 3 is a partially enlarged view of a portion a in fig. 1.

In the figure:

1. a rod base; 2. a mounting structure; 3. an anti-collision structure; 4. a shock-absorbing structure; 5. a buffer structure; 6. installing an ear loop; 7. a nut; 8. a bolt; 9. a first telegraph pole main body; 10. an anti-collision sliding block; 11. a limiting block; 12. a main link; 13. a first connecting rod; 14. a second connecting rod; 15. a first sliding block; 16. a second sliding block; 17. A first spring; 18. a second spring; 19. a first baffle plate; 20. a second baffle plate; 21. a pillar; 22. a third spring; 23. a sleeve; 24. a second telegraph pole main body; 25. a double-sided guide rail.

Detailed Description

For further explanation of the various embodiments, the drawings which form a part of the disclosure and which are incorporated in and constitute a part of this specification, illustrate embodiments and, together with the description, serve to explain the principles of operation of the embodiments, and to enable others of ordinary skill in the art to understand the various embodiments and advantages of the utility model, and, by reference to these figures, reference is made to the accompanying drawings, which are not to scale and wherein like reference numerals generally refer to like elements.

According to an embodiment of the utility model, a laying device for energy-saving electric power engineering is provided.

The first embodiment is as follows:

as shown in fig. 1 to 3, the laying equipment for the energy-saving electric power engineering according to the embodiment of the utility model comprises a rod base 1, wherein an installation structure 2, an anti-collision structure 3 and a shock absorption structure 4 are arranged at the top end of the rod base 1, the installation structure 2 is located at two ends of the anti-collision structure 3, the shock absorption structure 4 is located at one side of the anti-collision structure 3, and a buffer structure 5 is arranged inside the rod base 1.

By means of the technical scheme, the structural schematic diagram of the laying equipment for the energy-saving electric power engineering, which is composed of the pole base 1, the mounting structure 2, the anti-collision structure 3, the shock absorption structure 4, the buffer structure 5, the mounting ear rings 6, the nuts 7, the bolts 8, the first telegraph pole main body 9 and the anti-collision sliding blocks 10, is arranged, so that impact force generated when the outside collides with the telegraph pole is relieved through the shock absorption structure 4, the telegraph pole is protected while external impact objects are protected, vibration force is conducted downwards through the buffer structure 5, and the impact force applied to the telegraph pole is relieved conveniently.

Example two:

as shown in fig. 1-3, a mounting structure 2, a crash structure 3 and a shock-absorbing structure 4 are disposed on the top end of the pole base 1, the mounting structure 2 is disposed at two ends of the crash structure 3, the shock-absorbing structure 4 is disposed at one side of the crash structure 3, a buffer structure 5 is disposed inside the pole base 1, the mounting structure 2 is composed of a mounting ear loop 6, a nut 7 and a bolt 8, the bolt 8 penetrates through the mounting ear loop 6, the nut 7 is disposed at the bottom end of the bolt 8, the crash structure 3 is composed of a utility pole main body one 9, a bump block 10, a limit block 11 and a main link 12, the bump block 10 is disposed at one side of the utility pole main body one 9, the limit block 11 is disposed at two ends of the bump block 10, the main link 12 is disposed at one side of the bump block 10, the shock-absorbing structure 4 is composed of a link one 13, a link 13, and a bolt 8, The anti-collision sliding block comprises a second connecting rod 14, a first sliding block 15, a second sliding block 16, a first spring 17 and a second spring 18, wherein the first sliding block 15 is located at the top end of the first connecting rod 13, the first spring 17 is located at the top end of the first sliding block 15, the second sliding block 16 is located at the bottom end of the second connecting rod 14, the second spring 18 is located at the bottom end of the second sliding block 16, the anti-collision sliding block 10 is protected from falling or offsetting through the limiting block 11, and external impact force is relieved through the elastic force of the first spring 17 and the second spring 18.

Example three:

as shown in fig. 1-3, a mounting structure 2, a crash structure 3 and a shock-absorbing structure 4 are arranged at the top end of the pole base 1, the mounting structure 2 is located at both ends of the crash structure 3, the shock-absorbing structure 4 is located at one side of the crash structure 3, a buffer structure 5 is arranged inside the pole base 1, a first baffle 19 is arranged at the top end of the first spring 17, a second baffle 20 is arranged at the bottom end of the second spring 18, the buffer structure 5 is composed of a pillar 21, a third spring 22 and a sleeve 23, the third spring 22 is located outside the pillar 21, the sleeve 23 is located at the bottom end of the pillar 21, a second pole body 24 is arranged at the top end of the first pole body 9, a double-faced guide rail 25 is arranged at one side of the first slider 15 away from the first connecting rod 13, and the top end of the pillar 21 is fixedly connected with the second baffle 20, the bottom end of the strut 21 is movably connected with the sleeve 23, and the strut 21 is used for positioning the telegraph pole main body-9 during installation and also for conducting impact force.

For the convenience of understanding the technical solutions of the present invention, the following detailed description will be made on the working principle or the operation mode of the present invention in the practical process.

In practical application, the pole base 1 is buried underground, concrete is poured around the pole base for fixing, the support column 21 is sleeved with the spring III 22 and then inserted into the sleeve 23, the top end of the pole base 1 is aligned with the bottom end of the pole main body I9, the bolt 8 penetrates through the mounting ear ring 6 and then is fixed by the nut 7, a plurality of pole main bodies II 24 are spliced at the top end of the pole main body I9 according to the requirement of practical height, the anti-collision slider 10 is positioned at a position with high collision frequency, after the anti-collision slider 10 is impacted, the anti-collision slider 10 is translated inwards under the pressure to drive the main connecting rod 12 to move inwards, the angle between the connecting rod I13 and the connecting rod II 14 is increased, the slider I15 and the slider II 16 reversely slide on the double-sided guide rail 25, the slider I15 and the slider II 16 respectively drive the spring I17 and the spring II 18 to shrink, so that the impact force of the impact is relieved, and after the impact force penetrates through the baffle II, the vibration force is further transmitted downwards through the support 21 and the spring III 22, so that the impact force applied to the telegraph pole is relieved.

In summary, according to the technical scheme of the utility model, by setting the structural schematic diagram of the energy-saving laying equipment for the electric power engineering, which is composed of the pole base 1, the mounting structure 2, the anti-collision structure 3, the shock-absorbing structure 4, the buffer structure 5, the mounting ear rings 6, the nuts 7, the bolts 8, the first telegraph pole main body 9 and the anti-collision sliding blocks 10, the impact force generated when the outside collides with the telegraph pole is relieved through the shock-absorbing structure 4, the telegraph pole is protected while the outside impact object is protected, and the vibration force is transmitted downwards through the buffer structure 5, so that the impact force applied to the telegraph pole is relieved.

The above description is only for the purpose of illustrating the preferred embodiments of the present invention and is not to be construed as limiting the utility model, and any modifications, equivalents, improvements and the like that fall within the spirit and principle of the present invention are intended to be included therein.

Claims (8)

1. The utility model provides an energy-conserving electric power engineering is with laying equipment, its characterized in that, including pole base (1), the top of pole base (1) is provided with mounting structure (2), crashproof structure (3) and shock-absorbing structure (4), mounting structure (2) are located the both ends of crashproof structure (3), shock-absorbing structure (4) are located one side of crashproof structure (3), the inside of pole base (1) is provided with buffer structure (5).

2. The laying equipment for the energy-saving electric power engineering according to claim 1, wherein the mounting structure (2) is composed of a mounting ear ring (6), a nut (7) and a bolt (8), the bolt (8) penetrates through the mounting ear ring (6), and the nut (7) is positioned at the bottom end of the bolt (8).

3. The laying equipment for the energy-saving electric power engineering according to claim 1, wherein the anti-collision structure (3) is composed of a first telegraph pole main body (9), anti-collision sliders (10), limiting blocks (11) and main connecting rods (12), the anti-collision sliders (10) are located on one side of the inside of the first telegraph pole main body (9), the limiting blocks (11) are located at two ends of the anti-collision sliders (10), and the main connecting rods (12) are located on one side of the anti-collision sliders (10).

4. The laying equipment for the energy-saving electric power engineering as claimed in claim 3, wherein the damping structure (4) is composed of a first connecting rod (13), a second connecting rod (14), a first sliding block (15), a second sliding block (16), a first spring (17) and a second spring (18), the first sliding block (15) is located at the top end of the first connecting rod (13), the first spring (17) is located at the top end of the first sliding block (15), the second sliding block (16) is located at the bottom end of the second connecting rod (14), and the second spring (18) is located at the bottom end of the second sliding block (16).

5. The laying equipment for the energy-saving electric power engineering is characterized in that a first baffle (19) is arranged at the top end of the first spring (17), and a second baffle (20) is arranged at the bottom end of the second spring (18).

6. The laying equipment for energy-saving electric power engineering according to claim 5, wherein the buffer structure (5) is composed of a pillar (21), a spring three (22) and a sleeve (23), the spring three (22) is located outside the pillar (21), and the sleeve (23) is located at the bottom end of the pillar (21).

7. The energy-saving paving equipment for electric power engineering according to claim 4, characterized in that the top end of the first pole body (9) is provided with a second pole body (24), and the side of the first sliding block (15) far away from the first connecting rod (13) is provided with a double-faced guide rail (25).

8. The laying equipment for the energy-saving electric power engineering as claimed in claim 6, wherein the top end of the pillar (21) is fixedly connected with the second baffle plate (20), and the bottom end of the pillar (21) is movably connected with the sleeve (23).

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