CN111564807B - Stamping shockproof hammer suitable for alpine regions and installation method - Google Patents

Abstract

The invention discloses a stamping shockproof hammer suitable for alpine regions and an installation method of the stamping shockproof hammer. According to the stamping shockproof hammer suitable for the alpine regions and the mounting method, the T-shaped support A and the T-shaped support B are pressed down under the action of the pressure of frost and snow, the key switch A and the key switch B are switched on, the kickoff device is driven to reciprocate and rotate, the frost and snow accumulated on the kickoff device is shaken off to reduce the pressure on a power transmission line, so that the automatic cleaning of the frost and snow is realized, and the working stability is ensured.

Description

Stamping shockproof hammer suitable for alpine regions and installation method

Technical Field

The invention relates to the technical field of vibration dampers, in particular to a stamping vibration damper suitable for alpine regions and an installation method.

Background

The rain, snow and frost weather frequently happens in alpine regions, the vibration generated by vibration can be reduced during the installation of the shockproof hammer effect, the protection effect on the high-voltage line is achieved, but the shockproof hammer is beneficial to having disadvantages, when the shockproof hammer is used in alpine regions, ice, snow and frost can be accumulated on the shockproof hammer due to the fact that the shockproof hammer is installed, and the shockproof hammer is not changed for a long time, so that the burden of the high-voltage line is increased, the burden of a high-voltage transmission line is increased to a certain extent, the influence caused by rain, snow and frost is reduced, the shockproof hammer can be connected with a power transmission line, when the shockproof hammer meets strong wind weather, the normal swing of the shockproof hammer can be influenced, and the shockproof effect is reduced.

Based on the problems, the stamping shockproof hammer and the mounting method suitable for the alpine regions are provided, accumulated rain, snow and frost can be removed in time, and negative effects brought by the rain, snow and frost are reduced.

Disclosure of Invention

The invention aims to provide a stamping shockproof hammer and an installation method thereof, which are suitable for alpine regions, can remove accumulated rain, snow and frost in time and reduce the negative effects caused by rain, snow and frost, so as to solve the problems that ice, snow and frost are accumulated on the shockproof hammer to increase the line pressure and the shockproof hammer cannot normally swing in the background technology.

In order to achieve the purpose, the invention provides the following technical scheme: a stamping shockproof hammer suitable for alpine regions comprises a wire clamp, a steel strand wire, a first shockproof hammer and a second shockproof hammer, wherein the wire clamp is assembled on a power transmission line, the middle end of the steel strand wire is fixedly connected with the wire clamp, the first shockproof hammer and the second shockproof hammer are identical in structure, the first shockproof hammer is fixedly arranged at one end of the steel strand wire, and the second shockproof hammer is fixedly arranged at the other end of the steel strand wire; the first shockproof hammer comprises a hammer body, a steel wire twisting wire fixing device and a kickoff device, wherein a U-shaped positioning insertion hole is formed in the inner side end of the hammer body; one end of the steel wire is inserted into the U-shaped positioning jack, the bottom end of the steel wire fixing device is in a rodent shape and is a steel component, the steel wire fixing device is buckled on the U-shaped positioning jack, one end of the steel wire is fixed into the U-shaped positioning jack by the bottom end of the steel wire fixing device, and the upper end of the steel wire fixing device is fastened on the hammer body by adopting a screw rod; the other end of the hammer body is provided with a mounting groove, a pushing cylinder and a servo motor installing seat are additionally arranged in the mounting groove, the pushing cylinder is fixedly mounted on the inner side of the mounting groove, the servo motor installing seat is placed in the mounting groove, the tail end of the servo motor installing seat is fixedly connected with the output end of the pushing cylinder, a servo motor is additionally arranged at the output end of the servo motor installing seat, a material poking device is fixedly additionally arranged at the output end of the servo motor, the material poking device is cylindrical, and the inner cavity of the material poking device is sleeved on the hammer body; the upper end of the hammer body is additionally provided with a key switch A and a key switch B, the upper end of the key switch A is additionally provided with a T-shaped support A, the upper end of the key switch B is additionally provided with a T-shaped support B, and the T-shaped support A and the T-shaped support B are both flush with the end face of the hammer body; the outside of hammer block installs additional the panel, on the panel was all received to the input of propelling movement cylinder and servo motor, the output termination of propelling movement cylinder connects back to the input of panel behind the key switch A, and servo motor's output termination connects back to the input of panel behind the key switch B.

Preferably, the outer end face of the kick-out device is provided with kick-out teeth, and the kick-out teeth are stainless steel components.

Preferably, a square notch is formed in the front end of the kick-out device, and when the kick-out device is in an initial state, the key switch A and the key switch B are located on the hammer body at the square notch.

The invention provides another technical scheme that: a mounting method of a stamping shockproof hammer suitable for alpine regions comprises the following steps:

s1: firstly, fixedly installing a pushing cylinder and a battery panel in an installation groove, then fixedly installing a servo motor in an installing seat of the servo motor, assembling the installing seat of the servo motor in the installation groove, and fixedly connecting the tail end of the installing seat of the servo motor with the output end of the pushing cylinder;

s2: the kick-out device is additionally arranged at the front end of the servo motor, the key switch A and the key switch B are assembled on the hammer body, the upper end surfaces of the key switch A and the key switch B are flush with the end surface of the hammer body, the key switch A, the pushing cylinder and the battery panel are connected to form a closed loop, and the key switch B, the servo motor and the battery panel are connected to form a closed loop;

s3: and respectively fixing the first shockproof hammer and the second shockproof hammer at two ends of the steel strand, then fixedly installing the middle end of the steel strand on the wire clamp, and finally fixing the wire clamp on the power transmission line.

Compared with the prior art, the invention has the beneficial effects that: when frost and snow are accumulated on the first shockproof hammer, the T-shaped support A and the T-shaped support B are pressed down under the pressure action of the frost and snow, the T-shaped support A is pressed down to switch on the key switch A, so that the pushing cylinder is electrified to work, the servo motor is pushed to reciprocate back and forth, and the material poking device at the front end is driven to reciprocate; the T-shaped support B is pressed down to enable the key switch B to be connected, so that the servo motor is electrified to work to drive the front-end kickoff to rotate, the kickoff is separated from the power transmission line, frost and snow accumulated on the kickoff are shaken off under the action of reciprocating motion and rotation to reduce the pressure on the power transmission line, after the frost and snow are cleaned, the T-shaped support A and the T-shaped support B move upwards, the key switch A and the key switch B are disconnected, and the servo motor and the pushing cylinder stop working; therefore, the automatic cleaning of frost and snow is realized, and the working stability is ensured.

Drawings

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

FIG. 2 is a schematic view of the inner side of the first anti-vibration hammer of the present invention;

FIG. 3 is a schematic view of the outer side structure of the first anti-vibration hammer of the present invention;

FIG. 4 is an inside cross-sectional view of a first anti-rattle hammer of the present invention;

FIG. 5 is an assembly view of a T-shaped bracket A and a key switch A according to the present invention;

fig. 6 is a diagram of the connection between the T-shaped bracket B and the push switch B in the snow-covered conducting state.

In the figure: 1. wire clamps; 2. steel wire stranding; 3. a first anti-vibration hammer; 311. a hammer body; 312. a steel wire twisting wire fixing device; 313. a kick-out device; 314. a U-shaped positioning jack; 316. mounting grooves; 317. a push cylinder; 318. a servo motor is additionally provided with a seat; 319. a servo motor; 320. material shifting teeth; 321. a key switch A; 322. a key switch B; 323. a T-shaped bracket A; 324. a T-shaped bracket B; 325. a square notch; 326. a battery plate; 4. a second anti-vibration hammer.

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.

Referring to fig. 1-6, a stamping damper suitable for alpine regions comprises a wire clamp 1, a steel strand wire 2, a first damper 3 and a second damper 4, wherein the wire clamp 1 is assembled on a power transmission line, the middle end of the steel strand wire 2 is fixedly connected with the wire clamp 1, the first damper 3 and the second damper 4 have the same structure, the first damper 3 is fixedly installed at one end of the steel strand wire 2, and the second damper 4 is fixedly installed at the other end of the steel strand wire 2; the first shockproof hammer 3 comprises a hammer body 311, a steel wire twister 312 and a kickoff 313, wherein a U-shaped positioning jack 314 is formed in the inner side end of the hammer body 311, one end of a steel wire 2 is inserted into the U-shaped positioning jack 314, the bottom end of the steel wire twister 312 is in a rodent shape and is a steel member, the steel wire twister 312 is buckled on the U-shaped positioning jack 314, one end of the steel wire 2 is fixed in the U-shaped positioning jack 314 by the bottom end of the steel wire twister 312, and the upper end of the steel wire twister 312 is fastened on the hammer body 311 by a screw; the other end of the hammer body 311 is provided with a mounting groove 316, a pushing cylinder 317 and a servo motor installing seat 318 are additionally arranged inside the mounting groove 316, the pushing cylinder 317 is fixedly arranged on the inner side of the mounting groove 316, the servo motor installing seat 318 is arranged in the mounting groove 316, the tail end of the servo motor installing seat 318 is fixedly connected with the output end of the pushing cylinder 317, a servo motor 319 is additionally arranged on the output end of the servo motor installing seat 318, a kick-out device 313 is fixedly additionally arranged on the output end of the servo motor 319, the kick-out device 313 is cylindrical, and an inner cavity of the kick-out device 313 is sleeved on the hammer body 311; the upper end of the hammer body 311 is additionally provided with a key switch A321 and a key switch B322, the upper end of the key switch A321 is additionally provided with a T-shaped bracket A323, the upper end of the key switch B322 is additionally provided with a T-shaped bracket B324, and the T-shaped bracket A323 and the T-shaped bracket B324 are flush with the end surface of the hammer body 311; a square notch 325 is formed in the front end of the kick-out device 313, and when the kick-out device 313 is in an initial state, the key switch A321 and the key switch B322 are positioned on the hammer body 311 at the square notch 325; the outer side of the hammer body 311 is additionally provided with a battery panel 326, the input ends of the pushing cylinder 317 and the servo motor 319 are connected to the battery panel 326, the output end of the pushing cylinder 317 is connected with the key switch A321 and then connected back to the input end of the battery panel 326, and the output end of the servo motor 319 is connected with the key switch B322 and then connected back to the input end of the battery panel 326.

Referring to fig. 3, the outer end surface of the kick-out device 313 is provided with kick-out teeth 320, and the kick-out teeth 320 are stainless steel members.

Based on the stamping shockproof hammer suitable for the alpine region, the embodiment provides an installation method of the stamping shockproof hammer suitable for the alpine region, which includes the following steps:

the first step is as follows: firstly, a pushing cylinder 317 and a battery plate 326 are fixedly installed in an installation groove 316, a servo motor 319 is fixedly installed on a servo motor installation base 318, the servo motor installation base 318 is assembled in the installation groove 316, and the tail end of the servo motor installation base is fixedly connected with the output end of the pushing cylinder 317;

the second step is that: the kick-out device 313 is additionally arranged at the front end of the servo motor 319, the key switch A321 and the key switch B322 are assembled on the hammer body 311, the upper end surfaces of the key switch A321 and the key switch B322 are flush with the end surface of the hammer body 311, the key switch A321, the pushing cylinder 317 and the battery panel 326 are connected to form a closed loop, and the key switch B322, the servo motor 319 and the battery panel 326 are connected to form a closed loop;

the third step: the first shockproof hammer 3 and the second shockproof hammer 4 are respectively fixed at two ends of the steel stranded wire 2, then the middle end of the steel stranded wire 2 is fixedly arranged on the wire clamp 1, and finally the wire clamp 1 is fixed on a power transmission line.

The stamping shockproof hammer suitable for the alpine region and the mounting method comprise the steps that firstly, a pushing cylinder 317 and a battery plate 326 are fixedly mounted in a mounting groove 316, then a servo motor 319 is fixedly and additionally mounted on a servo motor additional mounting seat 318, the servo motor additional mounting seat 318 is mounted in the mounting groove 316, and the tail end of the servo motor additional mounting seat 318 is fixedly connected with the output end of the pushing cylinder 317; the kick-out device 313 is additionally arranged at the front end of the servo motor 319, the key switch A321 and the key switch B322 are assembled on the hammer body 311, the upper end surfaces of the key switch A321 and the key switch B322 are flush with the end surface of the hammer body 311, the key switch A321, the pushing cylinder 317 and the battery panel 326 are connected to form a closed loop, and the key switch B322, the servo motor 319 and the battery panel 326 are connected to form a closed loop; the first shockproof hammer 3 and the second shockproof hammer 4 are respectively fixed at two ends of the steel stranded wire 2, the middle end of the steel stranded wire 2 is fixedly arranged on the wire clamp 1, and finally the wire clamp 1 is fixed on a power transmission line.

In summary, according to the stamping shockproof hammer and the installation method for the stamping shockproof hammer suitable for the alpine regions, when frost and snow are accumulated on the first shockproof hammer 3, the T-shaped support a323 and the T-shaped support B324 are pressed down under the pressure of the frost and snow, the T-shaped support a323 is pressed down to switch on the key switch a321, so that the pushing cylinder 317 is electrified to work, the servo motor 319 is pushed to reciprocate back and forth, and the material poking device 313 at the front end is driven to reciprocate; the T-shaped support B324 is pressed down to switch on the key switch B322, so that the servo motor 319 is electrified to work to drive the front-end kickoff 313 to rotate, the kickoff 313 is separated from the power transmission line, meanwhile, frost and snow accumulated on the kickoff 313 are shaken off under the action of reciprocating motion and rotation to reduce the pressure on the power transmission line, after the frost and snow are cleaned, the T-shaped support A323 and the T-shaped support B324 move upwards, the key switch A321 and the key switch B322 are switched off, and the servo motor 319 and the pushing cylinder 317 stop working; therefore, the automatic cleaning of frost and snow is realized, and the working stability is ensured.

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 considered to be within the technical scope of the present invention, and the technical solutions and the inventive concepts thereof according to the present invention should be equivalent or changed within the scope of the present invention.

Claims (4)

1. The stamping shockproof hammer suitable for the alpine regions is characterized by comprising a wire clamp (1), a steel strand wire (2), a first shockproof hammer (3) and a second shockproof hammer (4), wherein the wire clamp (1) is assembled on a power transmission line, and the middle end of the steel strand wire (2) is fixedly connected with the wire clamp (1); the first shockproof hammer (3) and the second shockproof hammer (4) are identical in structure, the first shockproof hammer (3) is fixedly arranged at one end of the steel twisted wire (2), and the second shockproof hammer (4) is fixedly arranged at the other end of the steel twisted wire (2); the first shockproof hammer (3) comprises a hammer body (311), a steel wire twisting wire fixing device (312) and a kick-out device (313), wherein a U-shaped positioning insertion hole (314) is formed in the inner side end of the hammer body (311); one end of the steel wire (2) is inserted into the U-shaped positioning insertion hole (314), the bottom end of the steel wire fixing device (312) is in a rodent shape and is a steel component, the steel wire fixing device (312) is buckled on the U-shaped positioning insertion hole (314), one end of the steel wire (2) is fixed into the U-shaped positioning insertion hole (314) by the bottom end of the steel wire fixing device (312), and the upper end of the steel wire fixing device (312) is fastened on the hammer body (311) by a screw; the other end of the hammer body (311) is provided with a mounting groove (316), a pushing cylinder (317) and a servo motor installing seat (318) are additionally arranged inside the mounting groove (316), the pushing cylinder (317) is fixedly mounted on the inner side of the mounting groove (316), the servo motor installing seat (318) is placed in the mounting groove (316), the tail end of the servo motor installing seat (318) is fixedly connected with the output end of the pushing cylinder (317), the servo motor installing seat (318) is additionally provided with a servo motor (319), the output end of the servo motor (319) is fixedly additionally provided with a kick-out device (313), the kick-out device (313) is cylindrical, and an inner cavity of the kick-out device (313) is sleeved on the hammer body (311); the upper end of the hammer body (311) is additionally provided with a key switch A (321) and a key switch B (322), the upper end of the key switch A (321) is additionally provided with a T-shaped support A (323), the upper end of the key switch B (322) is additionally provided with a T-shaped support B (324), and the T-shaped support A (323) and the T-shaped support B (324) are flush with the end face of the hammer body (311); the outer side of the hammer body (311) is additionally provided with a battery panel (326), the input ends of the pushing cylinder (317) and the servo motor (319) are connected to the battery panel (326), the output end of the pushing cylinder (317) is connected to the input end of the battery panel (326) after being connected to the key switch A (321), and the output end of the servo motor (319) is connected to the input end of the battery panel (326) after being connected to the key switch B (322).

2. The ram shockproof hammer in the alpine region as claimed in claim 1, wherein: the outer end face of the kick-out device (313) is provided with kick-out teeth (320), and the kick-out teeth (320) are stainless steel components.

3. The ram shockproof hammer in the alpine region as claimed in claim 1, wherein: the front end of the kick-out device (313) is provided with a square notch (325), and when the kick-out device (313) is in an initial state, the key switch A (321) and the key switch B (322) are positioned on the hammer body (311) at the square notch (325).

4. The method for installing a ram vibration damper suitable for alpine regions according to claim 1, comprising the steps of:

s1: firstly, a pushing cylinder (317) and a battery plate (326) are fixedly installed in an installation groove (316), then a servo motor (319) is fixedly installed on a servo motor installation seat (318), the servo motor installation seat (318) is assembled in the installation groove (316), and the tail end of the servo motor installation seat is fixedly connected with the output end of the pushing cylinder (317);

s2: a kick-out device (313) is additionally arranged at the front end of a servo motor (319), a key switch A (321) and a key switch B (322) are assembled on a hammer body (311), the upper end surfaces of the key switch A (321) and the key switch B (322) are flush with the end surface of the hammer body (311), the key switch A (321), a pushing cylinder (317) and a battery panel (326) are connected to form a closed loop, and the key switch B (322), the servo motor (319) and the battery panel (326) are connected to form a closed loop;

s3: the first shockproof hammer (3) and the second shockproof hammer (4) are respectively fixed at two ends of the steel stranded wire (2), the middle end of the steel stranded wire (2) is fixedly arranged on the wire clamp (1), and finally the wire clamp (1) is fixed on a power transmission line.

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