CN114439304A - High-strength concrete anti-seismic electric pole - Google Patents

Abstract

A high-strength concrete anti-seismic electric pole belongs to the technical field of electric poles and aims to solve the problems that the electric pole lacks a damping mechanism, and when a geological disaster occurs, the electric pole vibrates along with the electric pole so as to cause risks of toppling, inclining and tearing off the electric pole, and the traditional electric pole is inconvenient to ship and install; the damping device comprises a base, a damping block, a first return spring, a second sliding block, a fixed rod and an arc-shaped sleeve, wherein the damping block is arranged on the inner wall of the base, the first return spring is arranged on the inner wall of the base, the second return spring is arranged on the inner wall of the base, the damping block is connected with the damping block through the second return spring, and the damping block is connected with the damping block through the second return spring.

Description

High-strength concrete anti-seismic electric pole

Technical Field

The invention relates to the technical field of telegraph poles, in particular to a high-strength concrete anti-seismic telegraph pole.

Background

The utility pole is just a pole for erecting the electric wire as the name implies, various early utility poles are started from wooden poles and even comprise high-voltage wire poles with not too high voltage grade, and later, due to the development of steel and reinforced concrete and technical requirements, the two materials replace most of the wooden poles, and applicable wood is gradually scarce, so that the wooden poles are basically difficult to see in cities.

At present common wire pole most all bury in soil and install fixedly, owing to lack damper, the wire pole can vibrate thereupon and then take place to empty and the risk of slope breaking wire when taking place geological disasters to traditional wire pole length is longer, has certain inconvenience when carrying out the consignment with the installation, the mounting bracket of the support electric wire at some wire pole tops adopts stand alone type installation more in addition, need carry out the consignment alone, still need install alone when laying the wire pole.

To solve the above problems. Therefore, a high-strength concrete anti-seismic electric pole is provided.

Disclosure of Invention

The invention aims to provide a high-strength concrete anti-seismic electric pole, which solves the problems that most common electric poles in the background art are buried in soil for installation and fixation, the electric poles vibrate along with the electric poles when a geological disaster occurs due to lack of a damping mechanism, and then the electric poles tilt and tear electric wires obliquely, the traditional electric poles are long in length, certain inconvenience exists when consignment and installation are carried out, in addition, installation frames for supporting the electric wires at the tops of the electric poles are installed independently, the independent consignment is needed, and the independent installation is needed when the electric poles are laid.

In order to achieve the purpose, the invention provides the following technical scheme: a high-strength concrete anti-seismic electric pole comprises a damping mechanism, and an assembling mechanism and a receiving mechanism which are arranged on the damping mechanism, wherein the damping mechanism comprises a base, a first pole body, a second pole body, a damping assembly and a fixing ring;

the damping assembly is provided with two layers, four groups of damping assemblies are arranged on each layer of damping assembly, eight groups of damping assemblies are radially distributed between the base and the first rod body, the damping assembly comprises a first sliding block and a fixed rod which are connected inside the annular sliding groove in a sliding mode, arc-shaped sleeves are fixedly connected to the inner sides of the first sliding block and the fixed rod, arc-shaped rods are connected between the two groups of arc-shaped sleeves in a sliding mode, and two ends, located on the arc-shaped rods, inside the arc-shaped sleeves are closed negative pressure spaces;

the damping component further comprises a fixing rod arranged on the inner side of the first sliding block, the fixing rod is connected with a rotating part in a rotating mode, the other end of the rotating part is connected with a damping block in a rotating mode, and the damping block is tightly attached to the outer surface of the first rod body.

Further, the inside of base is located fixedly connected with fixed block between first slider and the dead lever, the first reset spring of inboard fixedly connected with of fixed block, and the outside of snubber block all is equipped with the spring hole from top to bottom, and first reset spring's the other end fixed connection in the inside in spring hole.

Further, equipment mechanism includes installation component, fastening components and locking Assembly, and the installation component is including setting up the extrusion groove on the second body of rod, and the cross section in extrusion groove is right triangle, and the installation component still includes the cavity that sets up at first body of rod top, and in the bottom gomphosis of the second body of rod entered the cavity, and was provided with jacking spring between the bottom inner wall of cavity and the bottom of the second body of rod.

Furtherly, the installation component still includes the fluting of radial distribution in the first body of rod outside, and the fluting link up with the inside of the first body of rod, and grooved inside all is provided with the extrusion piece, and rotates through the pivot to connect in grooved inside the both sides below of extrusion piece, and the cross section of extrusion piece is right angled triangle.

Further, the fastening assembly comprises a first fixing ring fixedly connected to the top of the outer wall of the first rod body and a second fixing ring slidably connected to the outer wall of the first rod body, the first fixing ring is located above the extrusion block, the second fixing ring is located below the extrusion block, a first threaded rod is connected to the inner portion of the first fixing ring in a rotating mode, a first straight gear is fixedly connected to the outer wall of the top of the first threaded rod, and the first threaded rod is in threaded connection with the second fixing ring.

Further, the outer wall of the first fixing ring is provided with a rotating groove, a gear ring is rotated inside the rotating groove, and the inner side of the gear ring is in meshed connection with the first straight gear.

Further, the locking subassembly includes the casing of fixed connection at first solid fixed ring top, the top of casing is equipped with the opening, the inside below of casing is rotated and is connected with first ratchet gear, the bottom fixedly connected with second spur gear of first ratchet gear, and the bottom of second spur gear runs through the casing and is connected with the outer wall meshing of ring gear, the inside top that is located first ratchet gear of casing is rotated and is connected with second ratchet gear, and be equipped with second reset spring between the top of second ratchet gear and the top inner wall of casing, the top of second ratchet gear is provided with interior hexagonal groove.

Further, receiving mechanism includes drive assembly and supporting component, drive assembly is including rotating the first pivot pole of connection in first body of rod inside, the inside of first pivot pole is equipped with the spacing groove, sliding connection has the loose axle above the inside of spacing groove, the top fixedly connected with bevel gear of loose axle, be equipped with compression spring between the bottom of loose axle and the bottom inner wall of spacing groove, drive assembly is still including rotating the bolt of connection on first body of rod outer wall, the inboard of bolt extends to the inside of the first body of rod and is connected with face gear, the bottom fixedly connected with of first pivot pole and the bevel gear that face gear meshing is connected.

Furthermore, the transmission assembly further comprises a second threaded rod rotatably connected inside the second rod body, the bottom of the second threaded rod is fixedly connected with a meshing roller through a second transmission rod, and a groove corresponding to the bevel gear is formed in the bottom of the meshing roller.

Further, the supporting component comprises an accommodating groove and a vertical sliding groove which are formed in the outer wall of the two sides of the second rod body, the accommodating groove and the vertical sliding groove are two groups, the inside of the vertical sliding groove is connected with a second sliding block in a sliding mode, the second sliding block is connected with a nut seat in a fixed mode, the nut seat is connected with a second threaded rod in a threaded mode, a supporting rod is connected to the outer side of the nut seat in a rotating mode, the other end of the supporting rod is connected with an electric wire mounting frame in a rotating mode through a first hinge shaft, and the inner side of the electric wire mounting frame is connected to the upper portion of the inside of the accommodating groove in a rotating mode through a second hinge shaft.

Compared with the prior art, the invention has the beneficial effects that:

1. the utility model provides a high-strength concrete antidetonation pole, when taking place the earthquake, this moment under the effect in rolling ball and ball groove, base and first body of rod take place to rock around between the rolling ball, the below outer wall of the first body of rod is at the in-process extrusion snubber block that rocks, the snubber block receives to be close to the inner wall of base when the extrusion, a reset spring has played the absorbing effect at this in-process, and be close to the in-process to the base inner wall when the snubber block, contained angle increase between two sets of rotation pieces, first slider and dead lever slide and keep away from each other in the inside of annular chute, the in-process of keeping away from at first slider and dead lever is because arc sleeve is inside in the negative pressure state, the in-process that first slider and dead lever kept away from each other receives certain buffering and restoring force, the absorbing effect has been promoted.

2. The utility model provides a high-strength concrete antidetonation pole, when connecting the first body of rod and the second body of rod, hoist the second body of rod and make its bottom inject the inside of cavity, use hexagonal spanner to inject the interior hexagonal inslot on the second ratchet gear through the opening afterwards, drive first ratchet gear through second ratchet gear when clockwise rotation hexagonal spanner and rotate, and then drive second straight-tooth gear meshing ring gear and rotate, it rotates to drive first threaded rod through first straight-tooth gear when the ring gear rotates, finally make the solid fixed ring of second move up at the surface of the first body of rod, the solid fixed ring of second makes the surface of the inboard extrusion groove of extrusion piece at the in-process extrusion piece of rebound, finally make the second body of rod extrude jacking spring downwards and accomplish fixedly in the cavity under the extruded state, hexagonal spanner can not drive the ratchet principle that forms between first ratchet gear and the second ratchet gear when anticlockwise rotation First ratchet gear reverse rotation has promoted the convenience of delivery through the separation with the first body of rod and the second body of rod, has also further made things convenient for the installation on the spot.

3. The utility model provides a high-strength concrete antidetonation pole, through rotating the bolt after the installation is accomplished, make the bolt drive face gear and rotate, face gear drives first transfer line through bevel gear and rotates in the time of the pivoted, spacing inslot portion's compression spring makes the bevel gear mesh with the meshing roller mutually, and then driven second transfer line and second threaded rod and rotated, the second threaded rod drives nut seat in the inside rebound of the second body of rod in the pivoted, finally make the electric wire mounting bracket expand through the bracing piece, and electric wire mounting bracket and bracing piece can be retracted under the state of accomodating and accomodate in groove and the vertical spout, can not occupation space, the separate consignment has been avoided, installation steps have been reduced.

Drawings

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

FIG. 2 is a schematic view of the shock absorbing mechanism of the present invention;

FIG. 3 is an exploded view of the shock absorbing mechanism of the present invention;

FIG. 4 is a cross-sectional view of a base structure of the present invention;

FIG. 5 is a schematic view of the shock absorbing assembly of the present invention;

FIG. 6 is an exploded view of the shock absorbing assembly structure of the present invention;

FIG. 7 is a schematic structural diagram of an assembly mechanism according to the present invention;

FIG. 8 is a structural exploded view of the assembly mechanism of the present invention;

FIG. 9 is a schematic view of the fastener assembly of the present invention;

FIG. 10 is an exploded view of the locking assembly construction of the present invention;

FIG. 11 is a schematic structural view of a storage mechanism according to the present invention;

FIG. 12 is an exploded view of the receiving mechanism of the present invention;

FIG. 13 is an exploded view of the transmission assembly structure of the present invention;

fig. 14 is an exploded view of the support assembly structure of the present invention.

In the figure: 1. a damping mechanism; 11. a base; 111. an annular chute; 12. a first rod body; 121. rotating the ball; 13. a second rod body; 14. a shock absorbing assembly; 141. a first slider; 142. fixing the rod; 143. a rotating member; 144. a damper block; 145. a fixed block; 146. a spring hole; 147. a first return spring; 148. an arc-shaped sleeve; 149. an arcuate bar; 15. a stationary ring; 151. a ball groove; 2. an assembly mechanism; 21. mounting the component; 211. extruding a groove; 212. a jacking spring; 213. a cavity; 214. grooving; 215. extruding the block; 2151. a rotating shaft; 22. a fastening assembly; 221. a first retaining ring; 2211. a rotating groove; 222. a second retaining ring; 223. a first threaded rod; 2231. a first straight gear; 224. a ring gear; 23. a locking assembly; 231. a housing; 232. an opening; 233. a first ratchet gear; 234. a second spur gear; 235. a second ratchet gear; 236. a second return spring; 2351. an inner hexagonal groove; 3. a storage mechanism; 31. a transmission assembly; 311. a first rotating lever; 3111. a limiting groove; 3112. a compression spring; 3113. a movable shaft; 3114. a bevel gear; 312. a bevel gear; 313. a face gear; 314. a bolt; 315. a second transmission rod; 316. an engaging roller; 317. a second threaded rod; 32. a support assembly; 321. a nut seat; 322. a second slider; 323. a support bar; 324. a first hinge shaft; 325. a wire mounting bracket; 326. a second hinge shaft; 327. a receiving groove; 328. a vertical chute.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

In order to solve the technical problem, as shown in fig. 1 to 6, the following preferred technical solutions are provided:

the utility model provides a high-strength concrete antidetonation pole, including damper 1 and equipment mechanism 2 and the receiving mechanism 3 of setting on damper 1, damper 1 includes base 11, the first body of rod 12, the second body of rod 13, damper 14 and retainer plate 15, base 11's inside below is provided with annular spout 111, and annular spout 111 is provided with two sets ofly, retainer plate 15 fixed connection is in base 11's inside top, the centre of retainer plate 15 is provided with ball groove 151, fixedly connected with rolling ball 121 on the outer wall of the first body of rod 12, and rolling ball 121 activity sets up the inside at ball groove 151, the second body of rod 13 sets up the top at the first body of rod 12.

Damping component 14 is provided with two-layerly, and every layer of damping component 14 is provided with four groups, eight damping component 14 radial distribution of group are between base 11 and first body of rod 12, damping component 14 includes sliding connection at inside first slider 141 and the dead lever 142 of annular spout 111, and the equal fixedly connected with arc sleeve 148 in inboard of first slider 141 and dead lever 142, sliding connection has arc pole 149 between two sets of arc sleeve 148, and the inside both ends that are located arc pole 149 of arc sleeve 148 are inclosed negative pressure space.

Damping component 14 still includes the dead lever 142 that sets up at first slider 141 inboard, two sets of dead levers 142 all rotate and are connected with rotation piece 143, two sets of other ends that rotate piece 143 rotate and are connected with snubber block 144, and snubber block 144 hugs closely at the surface of the first body of rod 12, the inside of base 11 is located fixedly connected with fixed block 145 between first slider 141 and the dead lever 142, the first reset spring 147 of inboard fixedly connected with of fixed block 145, all be equipped with spring hole 146 about the outside of snubber block 144, and the other end fixed connection of first reset spring 147 is in the inside of spring hole 146.

Specifically, when an earthquake occurs, at this time, under the action of the rotating ball 121 and the ball groove 151, the base 11 and the first rod 12 shake around the rotating ball 121, the outer wall below the first rod 12 presses the damping block 144 in the shaking process, the damping block 144 approaches to the inner wall of the base 11 when being pressed, the first return spring 147 plays a role in damping the earthquake in the process, in the process that the damping block 144 approaches to the inner wall of the base 11, an included angle between the two sets of rotating parts 143 is increased, the first slider 141 and the fixed rod 142 slide and move away from each other in the annular sliding groove 111, and in the process that the first slider 141 and the fixed rod 142 move away from each other, because the inside of the arc-shaped sleeve 148 is in a negative pressure state, the first slider 141 and the fixed rod 142 move away from each other, and certain buffering and restoring forces are applied to the process that the first slider 141 and the fixed rod 142 move away from each other.

In order to solve the technical problem, as shown in fig. 7-10, the following preferred technical solutions are provided:

the assembling mechanism 2 comprises an installing component 21, a fastening component 22 and a locking component 23, the installing component 21 comprises an extrusion groove 211 arranged on the second rod body 13, the cross section of the extrusion groove 211 is a right triangle, the installing component 21 further comprises a cavity 213 arranged at the top of the first rod body 12, the bottom of the second rod body 13 is embedded into the cavity 213, a jacking spring 212 is arranged between the inner wall of the bottom of the cavity 213 and the bottom of the second rod body 13, the installing component 21 further comprises a slot 214 radially distributed on the outer side of the first rod body 12, the slot 214 is communicated with the inside of the first rod body 12, an extrusion block 215 is arranged inside the slot 214, the lower parts of the two sides of the extrusion block 215 are rotatably connected inside the slot 214 through a rotating shaft 2151, and the cross section of the extrusion block 215 is a right triangle.

The fastening assembly 22 comprises a first fixing ring 221 fixedly connected to the upper portion of the outer wall of the first rod 12 and a second fixing ring 222 slidably connected to the outer wall of the first rod 12, the first fixing ring 221 is located above the extrusion block 215, the second fixing ring 222 is located below the extrusion block 215, a first threaded rod 223 is rotatably connected to the inside of the first fixing ring 221, a first straight gear 2231 is fixedly connected to the outer wall of the top portion of the first threaded rod 223, the first threaded rod 223 is in threaded connection with the second fixing ring 222, the outer wall of the first fixing ring 221 is provided with a rotating groove 2211, an inner rotating gear ring 224 of the rotating groove 2211 is provided, the inner side of the gear ring 224 is in meshed connection with the first straight gear 2231, the locking assembly 23 comprises a housing 231 fixedly connected to the top portion of the first fixing ring 221, an opening 232 is provided on the top portion of the housing 231, a first ratchet 233 is rotatably connected to the lower portion of the inside of the housing 231, a second straight gear 234 is fixedly connected to the bottom portion of the first ratchet 233, and the bottom of the second spur gear 234 penetrates the housing 231 and is engaged with the outer wall of the gear ring 224, the second ratchet gear 235 is rotatably connected to the inside of the housing 231 above the first ratchet gear 233, a second return spring 236 is disposed between the top of the second ratchet gear 235 and the inner wall of the top of the housing 231, and an inner hexagonal groove 2351 is disposed at the top of the second ratchet gear 235.

Specifically, when the first rod 12 and the second rod 13 are connected, the second rod 13 is lifted and the bottom thereof is inserted into the cavity 213, and then a hexagonal wrench is inserted into the hexagonal socket 2351 of the second ratchet 235 through the opening 232, when the hexagonal wrench is rotated clockwise, the second ratchet 233 is driven to rotate by the second ratchet 235, and further the second spur gear 234 is driven to engage with the gear ring 224 to rotate, when the gear ring 224 rotates, the first threaded rod 223 is driven to rotate by the first spur gear 2231, and finally the second fixing ring 222 moves upward on the outer surface of the first rod 12, the second fixing ring 222 presses the outer surface of the pressing block 215 during the upward movement, so that the inner side of the pressing block 215 presses the surface of the pressing groove 211, and finally, in a pressing state, the second rod 13 presses the lifting spring 212 downward and is locked in the cavity 213 to complete the fixing, when the hexagonal wrench rotates counterclockwise, the first ratchet gear 233 is not driven to rotate reversely by the ratchet principle formed between the first ratchet gear 233 and the second ratchet gear 235.

In order to solve the technical problem, as shown in fig. 11-14, the following preferred technical solutions are provided:

storage mechanism 3 includes drive assembly 31 and supporting component 32, drive assembly 31 includes the first pole 311 of rotating the connection in the inside first body of rod 12, the inside of first pole 311 is equipped with spacing groove 3111, there is the loose axle 3113 inside top sliding connection of spacing groove 3111, the top fixedly connected with bevel gear 3114 of loose axle 3113, be equipped with compression spring 3112 between the bottom of loose axle 3113 and the bottom inner wall of spacing groove 3111, drive assembly 31 still includes the bolt 314 of rotating the connection on first body of rod 12 outer wall, the inboard of bolt 314 extends to the inside of first body of rod 12 and is connected with face gear 313, the bottom fixedly connected with of first pole 311 meshes the bevel gear 312 of being connected with face gear 313.

The transmission assembly 31 further comprises a second threaded rod 317 rotatably connected to the inside of the second rod 13, the bottom of the second threaded rod 317 is fixedly connected to an engaging roller 316 through a second transmission rod 315, and the bottom of the engaging roller 316 is provided with a groove corresponding to the bevel gear 3114, the supporting member 32 includes a receiving groove 327 and a vertical sliding groove 328 provided on the outer walls of both sides of the second rod body 13, two sets of the accommodating grooves 327 and the vertical sliding grooves 328 are arranged, the interior of the vertical sliding grooves 328 is connected with the second sliding block 322 in a sliding manner, and a nut seat 321 is fixedly connected between the two sets of second sliders 322, the nut seat 321 is in threaded connection with the second threaded rod 317, a support rod 323 is rotatably connected to the outer side of the nut seat 321, the other end of the support rod 323 is rotatably connected with an electric wire mounting frame 325 through a first hinge shaft 324, and the inner side of the electric wire mounting frame 325 is rotatably connected to the upper portion of the inner portion of the accommodating groove 327 through a second hinge shaft 326.

Specifically, through rotating bolt 314 after the installation is accomplished, make bolt 314 drive face gear 313 and rotate, face gear 313 drives first transfer line 311 through bevel gear 312 and rotates when rotating, the inside compression spring 3112 of spacing groove 3111 makes bevel gear 3114 mesh with meshing roller 316 mutually, and then has driven second transfer line 315 and second threaded rod 317 and rotated, second threaded rod 317 drives nut seat 321 and upwards moves in the inside of the second body of rod 13 when the pivoted, finally make electric wire mounting bracket 325 expand through bracing piece 323, and electric wire mounting bracket 325 and bracing piece 323 can retract in accomodating groove 327 and vertical spout 328 under the state of accomodating.

It is noted that, herein, relational terms such as first and second, and the like may be used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Also, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus.

The above description is only for the preferred embodiment of the present invention, but the scope of the present invention is not limited thereto, and any person skilled in the art should be able to cover the technical solutions and the inventive concepts of the present invention within the technical scope of the present invention.

Claims (10)

1. The utility model provides a high-strength concrete antidetonation pole, includes damper (1) and equipment mechanism (2) and receiving mechanism (3) of setting on damper (1), its characterized in that: the damping mechanism (1) comprises a base (11), a first rod body (12), a second rod body (13), a damping component (14) and a fixing ring (15), wherein an annular sliding groove (111) is formed in the lower portion of the inside of the base (11), two groups of annular sliding grooves (111) are formed in the annular sliding groove, the fixing ring (15) is fixedly connected to the upper portion of the inside of the base (11), a ball groove (151) is formed in the middle of the fixing ring (15), a rotating ball (121) is fixedly connected to the outer wall of the first rod body (12), the rotating ball (121) is movably arranged in the ball groove (151), and the second rod body (13) is arranged above the first rod body (12);

the damping assembly (14) is provided with two layers, four groups are arranged on each layer of damping assembly (14), eight groups of damping assemblies (14) are radially distributed between the base (11) and the first rod body (12), each damping assembly (14) comprises a first sliding block (141) and a fixed rod (142) which are connected to the inside of the annular sliding groove (111) in a sliding mode, arc-shaped sleeves (148) are fixedly connected to the inner sides of the first sliding block (141) and the fixed rod (142), an arc-shaped rod (149) is connected between the two groups of arc-shaped sleeves (148) in a sliding mode, and two ends, located on the arc-shaped rod (149), of the inside of each arc-shaped sleeve (148) are closed negative pressure spaces;

the damping component (14) further comprises fixing rods (142) arranged on the inner side of the first sliding block (141), the two groups of fixing rods (142) are connected with rotating pieces (143) in a rotating mode, the other ends of the rotating pieces (143) are connected with damping blocks (144) in a rotating mode, and the damping blocks (144) are tightly attached to the outer surface of the first rod body (12).

2. A high strength concrete earthquake-resistant pole as recited in claim 1, wherein: the inside of base (11) is located fixedly connected with fixed block (145) between first slider (141) and dead lever (142), the inboard fixedly connected with first reset spring (147) of fixed block (145), and the outside of snubber block (144) all is equipped with spring hole (146) from top to bottom, and the inside at spring hole (146) of the other end fixed connection of first reset spring (147).

3. A high strength concrete anti-seismic electric pole as recited in claim 1, characterized in that: equipment mechanism (2) are including installation component (21), fastening component (22) and locking Assembly (23), installation component (21) is including setting up extrusion groove (211) on the second body of rod (13), and the cross section in extrusion groove (211) is right angled triangle, installation component (21) are still including setting up cavity (213) at the first body of rod (12) top, in the bottom gomphosis of the second body of rod (13) enters cavity (213), and be provided with jacking spring (212) between the bottom inner wall of the bottom of cavity (213) and the bottom of the second body of rod (13).

4. A high strength concrete anti-seismic electric pole as recited in claim 3, characterized in that: the mounting assembly (21) further comprises a groove (214) which is radially distributed on the outer side of the first rod body (12), the groove (214) is communicated with the inside of the first rod body (12), the inside of the groove (214) is provided with an extrusion block (215), the lower portions of two sides of the extrusion block (215) are rotatably connected to the inside of the groove (214) through a rotating shaft (2151), and the cross section of the extrusion block (215) is in a right triangle shape.

5. A high-strength concrete anti-seismic electric pole as recited in claim 4, characterized in that: fastening components (22) include first solid fixed ring (221) of fixed connection in first body of rod (12) outer wall top and the solid fixed ring of second (222) of sliding connection on first body of rod (12) outer wall, and first solid fixed ring (221) are located the top of extrusion piece (215), solid fixed ring of second (222) is located the below of extrusion piece (215), the internal rotation of first solid fixed ring (221) is connected with first threaded rod (223), first straight gear (2231) of fixedly connected with on the top outer wall of first threaded rod (223), first threaded rod (223) and the solid fixed ring of second (222) threaded connection.

6. A high-strength concrete anti-seismic electric pole as recited in claim 5, characterized in that: the outer wall of the first fixing ring (221) is provided with a rotating groove (2211), a gear ring (224) is rotated inside the rotating groove (2211), and the inner side of the gear ring (224) is in meshed connection with the first straight gear (2231).

7. A high strength concrete anti-seismic pole as recited in claim 6, wherein: the locking assembly (23) comprises a shell (231) fixedly connected to the top of the first fixing ring (221), an opening (232) is formed in the top of the shell (231), a first ratchet gear (233) is rotatably connected to the lower portion of the inside of the shell (231), a second spur gear (234) is fixedly connected to the bottom of the first ratchet gear (233), the bottom of the second spur gear (234) penetrates through the shell (231) and is meshed with the outer wall of the gear ring (224), a second return spring (236) is arranged between the top of the second ratchet gear (235) and the inner wall of the top of the shell (231) and is rotatably connected to the upper portion of the first ratchet gear (233) in the shell (231), and an inner hexagonal groove (2351) is formed in the top of the second ratchet gear (235).

8. A high strength concrete anti-seismic electric pole as recited in claim 1, characterized in that: receiving mechanism (3) are including drive assembly (31) and supporting component (32), drive assembly (31) are including rotating first rotation pole (311) of connection in first body of rod (12) inside, the inside of first rotation pole (311) is equipped with spacing groove (3111), the inside top sliding connection of spacing groove (3111) has loose axle (3113), the top fixedly connected with bevel gear (3114) of loose axle (3113), be equipped with compression spring (3112) between the bottom inner wall of the bottom of loose axle (3113) and spacing groove (3111), drive assembly (31) still include bolt (314) of rotation connection on first body of rod (12) outer wall, the inboard of bolt (314) extends to the inside of first body of rod (12) and is connected with face gear (313), the bottom fixedly connected with of first rotation pole (311) and face gear (313) meshing connection's bevel gear (312).

9. A high strength concrete anti-seismic electric pole as recited in claim 8, characterized in that: the transmission assembly (31) further comprises a second threaded rod (317) rotatably connected inside the second rod body (13), the bottom of the second threaded rod (317) is fixedly connected with a meshing roller (316) through a second transmission rod (315), and a groove corresponding to the bevel gear (3114) is formed in the bottom of the meshing roller (316).

10. A high strength concrete anti-seismic electric pole as recited in claim 9, characterized in that: supporting component (32) are including setting up holding groove (327) and vertical spout (328) on the second body of rod (13) both sides outer wall, and hold groove (327) and vertical spout (328) and be equipped with two sets ofly, the equal sliding connection in inside of vertical spout (328) has second slider (322), and two sets of second slider (322) between fixedly connected with nut seat (321), nut seat (321) and second threaded rod (317) threaded connection, the outside of nut seat (321) is rotated and is connected with bracing piece (323), the other end of bracing piece (323) is rotated through first hank axle (324) and is connected with electric wire mounting bracket (325), the inboard of electric wire mounting bracket (325) is rotated through second hank axle (326) and is connected in the inside top of holding groove (327).

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