CN116625420A - High altitude detection device based on electric power detects - Google Patents

High altitude detection device based on electric power detects Download PDF

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Publication number
CN116625420A
CN116625420A CN202310700713.8A CN202310700713A CN116625420A CN 116625420 A CN116625420 A CN 116625420A CN 202310700713 A CN202310700713 A CN 202310700713A CN 116625420 A CN116625420 A CN 116625420A
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CN
China
Prior art keywords
isolation sleeve
welded
combined
clamping
block
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Granted
Application number
CN202310700713.8A
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Chinese (zh)
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CN116625420B (en
Inventor
王栓
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Zhongshan Electric Power Design Institute Co ltd
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Suzhou Electric Fish Intelligent Technology Co ltd
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Publication of CN116625420A publication Critical patent/CN116625420A/en
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    • GPHYSICS
    • G01MEASURING; TESTING
    • G01DMEASURING NOT SPECIALLY ADAPTED FOR A SPECIFIC VARIABLE; ARRANGEMENTS FOR MEASURING TWO OR MORE VARIABLES NOT COVERED IN A SINGLE OTHER SUBCLASS; TARIFF METERING APPARATUS; MEASURING OR TESTING NOT OTHERWISE PROVIDED FOR
    • G01D11/00Component parts of measuring arrangements not specially adapted for a specific variable
    • GPHYSICS
    • G01MEASURING; TESTING
    • G01RMEASURING ELECTRIC VARIABLES; MEASURING MAGNETIC VARIABLES
    • G01R31/00Arrangements for testing electric properties; Arrangements for locating electric faults; Arrangements for electrical testing characterised by what is being tested not provided for elsewhere
    • YGENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
    • Y02TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
    • Y02EREDUCTION OF GREENHOUSE GAS [GHG] EMISSIONS, RELATED TO ENERGY GENERATION, TRANSMISSION OR DISTRIBUTION
    • Y02E10/00Energy generation through renewable energy sources
    • Y02E10/50Photovoltaic [PV] energy

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  • Physics & Mathematics (AREA)
  • General Physics & Mathematics (AREA)
  • Electric Cable Installation (AREA)

Abstract

The invention discloses an overhead detection device based on electric power detection, wherein a linkage support frame is welded at one end of a linkage spring, a movable roller is clamped at the output shaft of a transmission motor, a friction sleeve is sleeved at the inner end of the movable roller, a supporting electromagnet is embedded and installed at the outer end of the movable roller, an insertion fixed block and the linkage support frame are fixedly limited through an insertion pin, the transmission motor drives the movable roller to climb a power transmission tower together with a worker under the adsorption action of the supporting electromagnet, so that equipment can be driven to move by the self transmission when the equipment is carried and carried, the weight of the equipment is reduced when the worker climbs, the position of the movable roller is regulated by the linkage spring, the movable roller can be stably clamped and combined with a cable, and the movable roller and the friction sleeve can be driven to move in a rotating friction manner by the transmission motor when the equipment is required to be detected, so that the equipment can be stably and uniformly pushed to move when the equipment is detected.

Description

High altitude detection device based on electric power detects
Technical Field
The invention relates to the technical field of high-altitude power facility detection, in particular to a high-altitude detection device based on power detection.
Background
The power network is composed of a substation and power transmission lines with different voltage levels, and is used for transmitting, controlling and distributing electric energy, cables are generally used as an infrastructure in power transmission, the cables generally need to be checked regularly when used for a long time, and a worker generally carries detection equipment to move along the cables for detection during current checking.
But when workman carries equipment to detect, because the cable is in the high altitude, and equipment has certain weight, has led to when handling equipment, needs consume a large amount of physical power of staff to need the whole operation of staff in the testing process, increased the security risk of staff when having increased operating strength, the speed is uneven when removing simultaneously, thereby can't guarantee the degree of consistency and the efficiency of detection.
Disclosure of Invention
The invention provides an overhead detection device based on electric power detection, which can effectively solve the problems that in the background technology, when a worker carries equipment for detection, because a cable is in the overhead and the equipment has a certain weight, a great amount of physical power of the worker is required to be consumed when the equipment is carried, the worker is required to operate in the whole process in the detection process, the operation intensity is increased, the safety risk of the worker is increased, and meanwhile, the moving speed is uneven when the worker moves, so that the uniformity and the efficiency of detection cannot be ensured.
In order to achieve the above purpose, the present invention provides the following technical solutions: the high-altitude detection device based on electric power detection comprises a protective isolation sleeve, wherein a deformation combination collection assembly is arranged on one side of the protective isolation sleeve, and the deformation combination collection assembly comprises a combination isolation sleeve;
the flaw detector is embedded and installed at the side ends of the protective isolation sleeve and the combined isolation sleeve, the cameras are installed at the side ends of the protective isolation sleeve and the combined isolation sleeve in a clamping mode, inner hole clamping blocks are welded at the two ends of the protective isolation sleeve and the combined isolation sleeve, a linkage spring is welded at one end of each inner hole clamping block, a linkage support frame is welded at one end of each linkage spring, a transmission motor is installed at one end of each linkage support frame through a motor seat, a movable roller is clamped and connected to an output shaft of the transmission motor, a friction sleeve is sleeved at the inner side end of the movable roller, supporting electromagnets are embedded and installed at the outer side end of the movable roller, insertion fixing blocks are welded at the two ends of the protective isolation sleeve and the two ends of the combined isolation sleeve, insertion fixing holes are formed in the tops of the linkage support frames and the insertion fixing blocks, and insertion pins are embedded and installed at the inner sides of the insertion fixing holes;
the bottom end of the combined isolation sleeve is welded with a clamping installation strip, the bottom end of the protective isolation sleeve is welded with a supporting and fixing plate, one end of the supporting and fixing plate is equidistantly welded with a plurality of limiting springs, and one end of each of the limiting springs is welded with a clamping installation box;
the bottom ends of the protective isolation sleeve and the combined isolation sleeve are hinged with a closed protective box, two ends of the closed protective box are welded with a movable limit box, one end of the inner side of the movable limit box is welded with a clamping spring, one end of the clamping spring is welded with a clamping movable column, two ends of the protective isolation sleeve and the combined isolation sleeve are welded with inner hole mounting plates, the bottom ends of the protective isolation sleeve and the combined isolation sleeve are clamped with a power supply battery, the top ends of the protective isolation sleeve and the combined isolation sleeve are embedded with a wireless transmitter, and one ends of the protective isolation sleeve and the combined isolation sleeve are embedded with a wireless receiver;
an auxiliary supporting block is welded at one end of the protective isolation sleeve and one end of the combined isolation sleeve, one end of the auxiliary supporting block is rotatably connected with a combined auxiliary plate, an installation auxiliary block is welded at one end of the protective isolation sleeve and one end of the combined isolation sleeve, and clamping pins are embedded and installed at the side ends of the installation auxiliary block;
one ends of the protective isolation sleeve and the combined isolation sleeve are connected with a hot melting frame in a clamping mode through fixing pins.
Preferably, the protection isolation sleeve is hinged with the combined isolation sleeve, the linkage support frame is rotatably arranged at the side end of the inner hole clamping block, the movable roller is rotatably arranged at the inner side of the linkage support frame, and the side end of the insertion fixing block is attached to the side end of the linkage support frame.
Preferably, the top end of the clamping installation box is in sliding fit with the bottom end of the protective isolation sleeve, the clamping installation strip is combined with the clamping installation box in a clamping mode, and the longitudinal sections of the clamping installation strip and the clamping installation box are L-shaped.
Preferably, the joint removes post and hole mounting panel joint combination, the longitudinal section of supplementary supporting shoe and installation auxiliary shoe is , flaw detector, camera, driving motor, support electro-magnet, wireless transmitter, wireless receiver and hot melt frame input all with power supply battery output electric connection, wireless transmitter signal output part and external controller signal input part wireless connection, wireless receiver signal input part and external controller signal output part wireless connection.
Compared with the prior art, the invention has the beneficial effects that: the invention has scientific and reasonable structure and safe and convenient use:
1. be provided with deformation and combine collection subassembly, insert fixed block and linkage support frame through inserting the pin and fix the restriction, drive the removal roller by driving motor again and accompany the staff to scramble the transmission tower under the adsorption of supporting electromagnet, make equipment can utilize self transmission to remove when carrying the transport, thereby the weight of carrying equipment when alleviateing the staff and scramble, fixed spacing to combination spacer and the protection spacer by supporting fixed plate and joint mounting box, and the position of removing the roller is adjusted by the linkage spring, make and remove the roller and can stabilize the joint combination with the cable, make and can utilize driving motor to drive removal roller and friction sleeve rotation friction removal when detecting, make and can stabilize at uniform velocity's propelling movement equipment when detecting, and need not the staff and pull, the operation of staff has been alleviateed, the effect of detection has been guaranteed, and through deformation combination, the weight of equipment has been alleviateed.
2. Be provided with combination self-adaptation protective component, through the mutual combination joint of support bolt and linkage operation piece with internal thread piece and support bearing bar, thereby quick installation arc guide plate, through internal thread post, spacing hawser and the spacing joint of hole fixed strip to internal thread piece, when receiving the side air current influence, the arc guide plate can shunt side air current, thereby slow down its impact, drive arc guide plate pivoted downwards through the air current, drive the spacing hawser of hole fixed strip pulling, make internal thread post and internal thread piece joint inseparabler, avoid down the air current to destroy the arc guide plate, and through turning down slightly, thereby guide the air current, reduce the impact force of air current, the safety of equipment motion has been guaranteed.
3. Be provided with and connect stable subassembly, drive closed arc board and insert the spring through reset spring and drive closed spliced pole and remove, make at the operation that the mutual joint of closed linkage ring and installation solid fixed ring and split time can be quick, thereby be convenient for staff's combination operation, drive the operation that the connection supporting shoe reset along the relay mount through the restriction spring, make when the elasticity of the powerful stay cord of needs regulation, and adsorb the joint to connection supporting shoe and relay mount through spacing electro-magnet, make and can stabilize its elasticity when staff carries equipment climbing transmission tower or a plurality of equipment mutual traction, guaranteed interconnect's effect, thereby the staff of being convenient for uses according to the environmental operation of difference.
In summary, through warp and combine collection subassembly and connect stable subassembly mutually supporting, make the equipment rely on self power to rise time can use the staff to hang the contact as the safety rope, avoid leading to equipment to drop the condition of damage to appear because of sliding, and can make up the linkage each other through a plurality of equipment when equipment detects the operation, it is supplementary to pull each other, guarantee the direction that its moved and the stability of its removal in-process, and other equipment can bring it back when single equipment appears unusual, be convenient for retrieve it, further alleviate staff's intensity of labour, combine collection subassembly mutually supporting through combining self-adaptation protective component and warp, make it receive external environment's influence at equipment operation in-process, avoid equipment and cable striking friction, thereby guaranteed the safety of equipment and cable, through combining self-adaptation protective component and connecting stable subassembly mutually supporting, make when receiving strong air current influence, the cable can support the arc guide plate, reduce its circumstances that leads to the fracture because of the rigidity impact, guarantee the safety of arc guide plate, through a plurality of components mutually supporting, the steady operation of equipment at high altitude has been guaranteed, simultaneously, staff's use risk has been reduced.
Drawings
The accompanying drawings are included to provide a further understanding of the invention and are incorporated in and constitute a part of this specification, illustrate the invention and together with the embodiments of the invention, serve to explain the invention.
In the drawings:
FIG. 1 is a schematic perspective view of the present invention;
FIG. 2 is a schematic view of the structure of the deformation-bonded collection assembly of the present invention;
FIG. 3 is a schematic view of the installation structure of the moving roller of the present invention;
fig. 4 is a schematic view of the installation structure of the power supply battery of the present invention;
FIG. 5 is a schematic structural view of the combined adaptive protection component of the present invention;
FIG. 6 is a schematic view of the mounting structure of the support bolt of the present invention;
FIG. 7 is a schematic view of the structure of the connection stabilization assembly of the present invention;
FIG. 8 is a schematic view of the mounting structure of the mounting retaining ring of the present invention;
FIG. 9 is a schematic view of the mounting structure of the closed arc panel of the present invention;
reference numerals in the drawings: 1. a protective isolation sleeve;
2. a deformation-bonded collection assembly; 201. a combined isolation sleeve; 202. a flaw detector; 203. a camera; 204. an inner hole clamping block; 205. a linkage spring; 206. a linkage support frame; 207. a drive motor; 208. moving the roller; 209. a friction sleeve; 210. supporting an electromagnet; 211. inserting a fixed block; 212. inserting into the fixing hole; 213. inserting a pin; 214. clamping and connecting the mounting strip; 215. a supporting and fixing plate; 216. a limit spring; 217. a clamping installation box; 218. closing the protective box; 219. moving the limit box; 220. a clamping spring; 221. clamping the movable column; 222. an inner hole mounting plate; 223. a power supply battery; 224. a wireless transmitter; 225. a wireless receiver; 226. an auxiliary supporting block; 227. combining auxiliary plates; 228. installing an auxiliary block; 229. clamping pins; 230. fixing pins; 231. and a hot melting frame.
3. Combining the adaptive protection components; 301. an internal thread block; 302. a support bolt; 303. a linkage operation block; 304. supporting a bearing rod; 305. an arc-shaped guide plate; 306. a blocking mounting plate; 307. combining the support holes; 308. an internal threaded post; 309. limiting mooring ropes; 310. guiding the inner orifice plate; 311. an inner hole fixing strip; 312. an inner hole limiting block; 313. closing the pin;
4. connecting a stabilizing component; 401. an internal thread cylinder; 402. installing a fixing ring; 403. closing the linkage ring; 404. a return spring; 405. closing an arc plate; 406. inserting a spring; 407. closing the connecting column; 408. closing the electromagnet; 409. inserting into the threaded hole; 410. a combination bolt; 411. a strong pull rope; 412. connecting the supporting blocks; 413. a limiting spring; 414. a relay fixing frame; 415. a power supply control group; 416. limiting electromagnet; 417. and a threading hole.
Detailed Description
The preferred embodiments of the present invention will be described below with reference to the accompanying drawings, it being understood that the preferred embodiments described herein are for illustration and explanation of the present invention only, and are not intended to limit the present invention.
Examples: as shown in fig. 1-9, the invention provides a technical scheme, namely a high-altitude detection device based on electric power detection, which comprises a protective isolation sleeve 1, wherein a deformation combination collection assembly 2 is arranged on one side of the protective isolation sleeve 1, and the deformation combination collection assembly 2 comprises a combination isolation sleeve 201;
the flaw detector 202 is embedded and installed at the side ends of the protective isolation sleeve 1 and the combined isolation sleeve 201, the protective isolation sleeve 1 is hinged with the combined isolation sleeve 201, so that the operation can be fast limited when the protective isolation sleeve 1 and the combined isolation sleeve 201 are connected and combined, the camera 203 is installed at the side ends of the protective isolation sleeve 1 and the combined isolation sleeve 201 in a clamping manner, the inner hole clamping blocks 204 are welded at the two ends of the protective isolation sleeve 1 and the combined isolation sleeve 201, the linkage springs 205 are welded at one end of the inner hole clamping blocks 204, the linkage support frame 206 is welded at one end of the linkage springs 205, the linkage support frame 206 is rotatably installed at the side end of the inner hole clamping blocks 204, the transmission motor 207 is installed at one end of the linkage support frame 206 through a motor seat, the output shaft of the transmission motor 207 is clamped with the movable roller 208, the movable roller 208 is rotatably installed at the inner side of the linkage support frame 206, the movable limiting and fixing can be achieved when the movable operation is carried out, the inner side end of the movable roller 208 is sleeved with the friction sleeve 209, the support electromagnet 210 is embedded and installed at the outer side end of the movable roller 208, the protective isolation sleeve 1 and the combined isolation sleeve 201 are fixedly inserted into the support frame 212, and the support frame 211 is fixedly inserted into the holes 212 when the two ends of the fixed insertion holes 211 are required to be inserted into the fixed insertion holes 212;
the bottom end of the combined isolation sleeve 201 is welded with the clamping installation strip 214, the bottom end of the protective isolation sleeve 1 is welded with the supporting and fixing plate 215, one end of the supporting and fixing plate 215 is equidistantly welded with the plurality of limiting springs 216, one end of the plurality of limiting springs 216 is welded with the clamping installation box 217, the top end of the clamping installation box 217 is in sliding fit with the bottom end of the protective isolation sleeve 1, the clamping installation strip 214 is combined with the clamping installation box 217 in a clamping manner, and the longitudinal sections of the clamping installation strip 214 and the clamping installation box 217 are L-shaped, so that the protective isolation sleeve 1 and the combined isolation sleeve 201 can be rapidly operated when being required to be clamped in a closing manner, and the protective isolation sleeve can be effectively supported and fixed through opposite L-shaped clamping;
the bottom ends of the protective isolation sleeve 1 and the combined isolation sleeve 201 are hinged with a closed protective box 218, the two ends of the closed protective box 218 are welded with a movable limit box 219, one end of the inner side of the movable limit box 219 is welded with a clamping spring 220, one end of the clamping spring 220 is welded with a clamping movable column 221, the two ends of the protective isolation sleeve 1 and the combined isolation sleeve 201 are welded with inner hole mounting plates 222, the clamping movable column 221 and the inner hole mounting plates 222 are clamped and combined, so that rapid combined operation can be realized when the closed protective box 218 is closed and protected, the bottom ends of the protective isolation sleeve 1 and the combined isolation sleeve 201 are clamped with a power supply battery 223, the top ends of the protective isolation sleeve 1 and the combined isolation sleeve 201 are embedded and provided with a wireless transmitter 224, and one ends of the protective isolation sleeve 1 and the combined isolation sleeve 201 are embedded and provided with a wireless receiver 225;
an auxiliary supporting block 226 is welded at one end of the protective isolation sleeve 1 and one end of the combined isolation sleeve 201, a combined auxiliary plate 227 is rotatably connected at one end of the auxiliary supporting block 226, an installation auxiliary block 228 is welded at one end of the protective isolation sleeve 1 and one end of the combined isolation sleeve 201, and the longitudinal sections of the auxiliary supporting block 226 and the installation auxiliary block 228 are , so that effective operation limiting can be realized during supporting and combining, and clamping pins 229 are embedded and installed at the side ends of the installation auxiliary block 228;
the protection isolation sleeve 1 and one end of the combined isolation sleeve 201 are clamped with a hot melting frame 231 through a fixing pin 230, and the input ends of the flaw detector 202, the camera 203, the transmission motor 207, the supporting electromagnet 210, the wireless transmitter 224, the wireless receiver 225 and the hot melting frame 231 are electrically connected with the output end of the power supply battery 223, the signal output end of the wireless transmitter 224 is in wireless connection with the signal input end of the external controller, and the signal input end of the wireless receiver 225 is in wireless connection with the signal output end of the external controller.
A combined self-adaptive protection component 3 is arranged on one side of the protection isolation sleeve 1, and the combined self-adaptive protection component 3 comprises an internal thread block 301;
the protection isolation sleeve 1 and the combined isolation sleeve 201 are symmetrically hinged with an internal thread block 301, one end of the internal thread block 301 is connected with a supporting bolt 302 through threads, one end of the supporting bolt 302 is welded with a linkage operation block 303, the longitudinal section of the middle part of the linkage operation block 303 is hexagonal, the linkage operation block 303 is connected with a supporting bearing rod 304 in a rotating way, one ends of the two supporting bearing rods 304 are welded with an arc-shaped guide plate 305, the longitudinal section of the arc-shaped guide plate 305 is U-shaped, so that air flow is split and guided to flow, the position of the protection isolation sleeve 1 and the combined isolation sleeve 201 corresponding to the internal thread block 301 is symmetrically welded with a blocking mounting plate 306, the side end of the internal thread block 301 is attached to the side end of the blocking mounting plate 306, so that position deviation can be avoided during clamping limiting, the stability of clamping is ensured, the combined support hole 307 is formed in one end of the blocking mounting plate 306 and one end of the internal thread block 301, the internal thread column 308 is embedded and mounted on the inner side of the combined support hole 307, the longitudinal section of the internal thread column 308 is T-shaped, so that the internal thread block can be effectively limited and supported during clamping and connection, a limiting cable 309 is connected to one end of the internal thread column 308 through threads, a guiding inner hole plate 310 is welded at the position of the protecting isolation sleeve 1 and one end of the combined isolation sleeve 201 corresponding to the limiting cable 309, inner hole fixing strips 311 are welded at one end of the limiting cables 309, the side ends of the inner hole fixing strips 311 are attached to the side ends of the arc-shaped guide plates 305, the limiting cables 309 are sleeved with the guiding inner hole plate 310 in a sliding mode, inner hole limiting blocks 312 are mounted at the position of the inner side ends of the arc-shaped guide plates 305 corresponding to the inner hole fixing strips 311, and closing pins 313 are embedded and mounted between the inner hole limiting blocks 312 and the inner hole fixing strips 311.
A connecting stabilizing component 4 is arranged on one side of the protective isolation sleeve 1, and the connecting stabilizing component 4 comprises an internal thread cylinder 401;
the protection isolation sleeve 1 and the combined isolation sleeve 201 are equidistantly welded with a plurality of internal thread barrels 401, the inner side of the internal thread barrels 401 is connected with a mounting fixed ring 402 through threads, the side end of the mounting fixed ring 402 is sleeved with a closing linkage ring 403, one end of the inner side of the closing linkage ring 403 is welded with a reset spring 404, one end of the reset spring 404 is welded with a closing arc plate 405, one end of the closing arc plate 405 is symmetrically welded with an inserting spring 406, one end of the inserting spring 406 is welded with a closing connecting column 407, the side end of the closing arc plate 405 is attached to the side end of the closing linkage ring 403, the closing connecting column 407 is embedded and mounted at the side end of the closing linkage ring 403, the best connecting effect is ensured through multistage limiting when the closing linkage ring 403 is clamped and combined with the mounting fixed ring 402, the closing electromagnet 408 is embedded and mounted at the position of the side end of the closing linkage ring 403 corresponding to the closing arc plate 405, one end of the closing linkage ring 403 is provided with an inserting threaded hole 409, the inner side of the insertion threaded hole 409 is connected with a combined bolt 410 through threads, one end of the combined bolt 410 is provided with a powerful pull rope 411, the powerful pull rope 411 is wound and installed at the side end of a connecting support block 412, the connecting support block 412 is rotatably installed at the inner side of a relay fixing frame 414, the longitudinal sections of the connecting support block 412 and the relay fixing frame 414 are I-shaped, so that the operation can be fast performed during shrinkage and paying-off, the side end of the connecting support block 412 is welded with a limiting spring 413, one end of the limiting spring 413 is welded with a relay fixing frame 414, the inner side of the relay fixing frame 414 is embedded and installed with a power supply control group 415, the side end of the relay fixing frame 414 is provided with a limiting electromagnet 416 corresponding to the position of the connecting support block 412, the side end of an arc-shaped guide plate 305 is provided with a threading hole 417 corresponding to the position of the powerful pull rope 411, the powerful pull rope 411 is sleeved and penetrated through the threading hole 417, the input ends of the closing electromagnet 408 and the limiting electromagnet 416 are electrically connected with the output end of the power supply control group 415.
The working principle and the using flow of the invention are as follows: when the high-altitude power transmission line is required to be inspected, a worker rotates the combined isolation sleeve 201 along the protective isolation sleeve 1, rotates the combined isolation sleeve 201 to the side end of the protective isolation sleeve 1, clamps the combined auxiliary plate 227 to the side end of the installation auxiliary block 228 through the clamping pin 229, so as to clamp and combine the protective isolation sleeve 1 and the combined isolation sleeve 201, rotates the linkage support frame 206, embeds the insertion pin 213 into the inner side of the insertion fixing hole 212, so as to combine and connect the linkage support frame 206 and the insertion fixing block 211, clamps the installation fixing ring 402 to the side end of the internal thread cylinder 401 through threads, clamps the closing linkage ring 403 to the side end of the installation fixing ring 402, clamps the closing arc plate 405 to the side end of the closing linkage ring 403 through the reset spring 404, clamps the closing connecting post 407 to the side end of the closing linkage ring 403 through the insertion spring 406, and then supplies power to the closing electromagnet 408 through the power supply control group 415, thereby combining and limiting the closed linkage ring 403 and the mounting fixed ring 402, embedding a combined bolt 410 with a powerful pull rope 411 into the inner side of an insertion threaded hole 409, clamping the closed linkage ring 403 at the other end on a waistband by a worker, placing the movable roller 208 at the side end of the high-voltage transmission tower, supplying power to the supporting electromagnet 210 and the transmission motor 207 by the power supply battery 223, enabling the movable roller 208 to be attached at the side end of the high-voltage transmission tower by the supporting electromagnet 210, driving the movable roller 208 to rotate by the transmission motor 207, thereby driving the whole equipment to move upwards, simultaneously climbing the high-voltage transmission tower by the worker, reducing the carrying weight of the worker when the worker carries the equipment, connecting and fixing the equipment and the worker by the powerful pull rope 411, enabling the worker to fall under strong wind in the ascending process of the equipment, protection can be performed by manual recovery;
when moving to the working position, a worker removes the closed linkage ring 403, loosens the clamping pin 229, the installation auxiliary block 228 and the combination auxiliary plate 227, rotates the combination isolation sleeve 201 again, combines and limits the internal thread block 301, the linkage operation block 303, the support bearing rod 304 and the arc deflector 305 through the support bolt 302, embeds the internal thread column 308 into the inner side of the combination support hole 307, clamps the limit cable 309 to the side end of the internal thread column 308 through threads, thereby limiting and combining the internal thread block 301 and the blocking mounting plate 306, then fixes the internal hole fixing strip 311 and the internal hole limiting block 312 through the closed pin 313, enables the arc deflector 305 to be quickly assembled and mounted before being used, blocks high air flow at the side end through the arc deflector 305, and shunts the air flow, so that the vibration influence caused by the high air flow can be reduced in the moving process of the equipment, the normal operation of the equipment is guaranteed, meanwhile, when the air flow is downwards-down air flow, the arc deflector 305 is pushed by the downward pressure air flow, the internal thread block 301 is downwards rotated and hinged, the internal thread block 301 can be downwards rotated, the internal thread block 301 is downwards rotated by the internal thread block 301 and the support rod 306, the slope angle is downwards pushed by the lower than the support rod 306, the inner thread is downwards pushed by the arc deflector 305, the arc deflector 305 is downwards rotated by the air flow, and the slope is conveniently and the slope angle is enabled to be more tightly deflected by the lower than the air flow, and the air flow is downwards driven by the lower than the lower pressure rod 309, and is conveniently and is downwards rotated by the lower than the slope by the pressure rod, and is caused by the lower pressure rod and is pushed by the lower pressure and is caused by the high pressure and has lower pressure effect;
the closing linkage ring 403 is clamped to the side end of the mounting fixed ring 402, the powerful pull rope 411 passes through the threading hole 417, the limiting spring 413 drives the connecting support block 412 to reset along the relay fixed frame 414, so that the powerful pull rope 411 is limited and fixed, the tightness can be adjusted according to the environment in the pulling process, the limiting electromagnet 416 is used for fixedly limiting the connecting support block 412 and the relay fixed frame 414, the fixed tightness can be kept in the running process of equipment, the mutual connection between the equipment is ensured, multiple groups of equipment are combined and connected, the equipment can be mutually pulled and guided in the moving process, the situation that the equipment rotates or overturns at a large angle due to the influence of airflow is avoided, and the equipment can be driven to move and return through mutual traction when the power supply of single equipment is insufficient, so that the situation that the equipment cannot be recovered due to the power supply deficiency is reduced;
the protective isolation sleeve 1 and the combined isolation sleeve 201 are placed at the side end of a detection cable, the clamping installation strip 214 is inserted into the side end of the clamping installation box 217, the limiting spring 216 drives the clamping installation box 217 to move along the direction of the supporting and fixing plate 215, so that the protective isolation sleeve 1 and the combined isolation sleeve 201 are fixedly clamped, the insertion pin 213 is taken out from the inner side of the insertion and fixing hole 212, the linkage spring 205 drives the linkage support 206 to rotate along the inner hole clamping block 204, the movable roller 208 is attached to the side end of the cable, the linkage spring 205 drives the linkage support 206 to rotate, when different cables are detected, the side end of the movable roller 208 can be effectively attached and clamped, the transmission motor 207 drives the movable roller 208 to rotate, so that the friction sleeve 209 is attached and rubbed with the side end of the cable, and equipment is driven to move, so that the flaw detector 202 and the camera 203 are driven to move, so that workers do not need to drag in the detection process, the labor intensity of the workers is reduced, the external control is received through the wireless receiver 225, the data shot by the wireless transmitter 224 and the flaw detector 202 and the camera 203 are transmitted to a rear stage for the workers to the actual condition of detection, and the actual condition is convenient to be detected;
when detecting a cable in an icing environment, a worker fixes a hot-melting frame 231 to the side ends of the protective isolation sleeve 1 and the combined isolation sleeve 201 through a fixing pin 230, melts ice on the surface of the cable through the hot-melting frame 231 to loosen the ice, drives a movable roller 208 to roll and crush the ice through a transmission motor 207, so that normal shooting and detection of equipment cannot be affected when the cable is used, when a power supply battery 223 needs to be replaced, a clamping movable column 221 is pulled, a closed protective box 218 is rotated, the power supply battery 223 is taken down from the positions of the protective isolation sleeve 1 and the combined isolation sleeve 201, a new power supply battery 223 is clamped to the bottom ends of the protective isolation sleeve 1 and the combined isolation sleeve 201 again, the closed protective box 218 is rotated again, and the clamping movable column 221 is driven by a clamping spring 220 to be embedded into the side ends of an inner hole mounting plate 222, so that the power supply battery 223 is protected and fixed.
Finally, it should be noted that: the foregoing is merely a preferred example of the present invention, and the present invention is not limited thereto, but it is to be understood that modifications and equivalents of some of the technical features described in the foregoing embodiments may be made by those skilled in the art, although the present invention has been described in detail with reference to the foregoing embodiments. Any modification, equivalent replacement, improvement, etc. made within the spirit and principle of the present invention should be included in the protection scope of the present invention.

Claims (10)

1. High altitude detection device based on electric power detects, including protection spacer sleeve (1), its characterized in that: a deformation combination collecting assembly (2) is arranged on one side of the protective isolation sleeve (1), and the deformation combination collecting assembly (2) comprises a combination isolation sleeve (201);
the flaw detector is embedded and installed at the side ends of the protective isolation sleeve (1) and the combined isolation sleeve (201), the camera (203) is installed at the side ends of the protective isolation sleeve (1) and the combined isolation sleeve (201) in a clamping manner, inner hole clamping blocks (204) are welded at the two ends of the protective isolation sleeve (1) and the combined isolation sleeve (201), a linkage spring (205) is welded at one end of each inner hole clamping block (204), a linkage support frame (206) is welded at one end of each linkage spring (205), a transmission motor (207) is installed at one end of each linkage support frame (206) through a motor base, a movable roller (208) is connected at the output shaft of each transmission motor (207) in a clamping manner, a friction sleeve (209) is sleeved at the inner side end of each movable roller (208), and a supporting electromagnet (210) is embedded and installed at the outer side end of each movable roller (208);
the two ends of the protective isolation sleeve (1) and the combined isolation sleeve (201) are welded with insertion fixing blocks (211), insertion fixing holes (212) are formed in the tops of the linkage support frames (206) and the insertion fixing blocks (211), and insertion pins (213) are embedded and installed in the inner sides of the insertion fixing holes (212);
the bottom end of the combined isolation sleeve (201) is welded with a clamping installation strip (214), the bottom end of the protective isolation sleeve (1) is welded with a supporting and fixing plate (215), one end of the supporting and fixing plate (215) is equidistantly welded with a plurality of limiting springs (216), and one end of each of the limiting springs (216) is welded with a clamping installation box (217);
the protection isolation sleeve (1) and the combined isolation sleeve (201) are hinged to each other, a closed protection box (218) is hinged to each of the bottom ends of the closed protection box (218), a movable limit box (219) is welded to each of the two ends of the closed protection box (218), a clamping spring (220) is welded to each of the inner sides of the movable limit box (219), a clamping movable column (221) is welded to each of one ends of the clamping spring (220), inner hole mounting plates (222) are welded to each of the two ends of the protection isolation sleeve (1) and the combined isolation sleeve (201), a power supply battery (223) is clamped to each of the bottom ends of the protection isolation sleeve (1) and the combined isolation sleeve (201), a wireless transmitter (224) is embedded into each of the top ends of the protection isolation sleeve (1) and the combined isolation sleeve (201), and a wireless receiver (225) is embedded into each of one ends of the protection isolation sleeve (1) and the combined isolation sleeve (201).
An auxiliary supporting block (226) is welded at one end of the protective isolation sleeve (1) and one end of the combined isolation sleeve (201), a combined auxiliary plate (227) is rotatably connected at one end of the auxiliary supporting block (226), an installation auxiliary block (228) is welded at one end of the protective isolation sleeve (1) and one end of the combined isolation sleeve (201), and a clamping pin (229) is embedded and installed at the side end of the installation auxiliary block (228);
one end of the protective isolation sleeve (1) and one end of the combined isolation sleeve (201) are clamped with a hot melting frame (231) through fixing pins (230).
2. The high-altitude detection device based on power detection according to claim 1, wherein the protective isolation sleeve (1) is hinged with the combined isolation sleeve (201), the linkage support frame (206) is rotatably installed at the side end of the inner hole clamping block (204), the movable roller (208) is rotatably installed at the inner side of the linkage support frame (206), and the side end of the insertion fixing block (211) is attached to the side end of the linkage support frame (206).
3. The high-altitude detection device based on power detection according to claim 1, wherein the top end of the clamping installation box (217) is in sliding fit with the bottom end of the protective isolation sleeve (1), the clamping installation strip (214) is combined with the clamping installation box (217) in a clamping manner, and the longitudinal sections of the clamping installation strip (214) and the clamping installation box (217) are all L-shaped.
4. The high-altitude detection device based on power detection according to claim 1, wherein the clamping moving column (221) is combined with the inner hole mounting plate (222) in a clamping manner, longitudinal sections of the auxiliary supporting block (226) and the mounting auxiliary block (228) are , input ends of the flaw detector (202), the camera (203), the transmission motor (207), the supporting electromagnet (210), the wireless transmitter (224), the wireless receiver (225) and the hot melting frame (231) are electrically connected with output ends of the power supply battery (223), signal output ends of the wireless transmitter (224) are wirelessly connected with signal input ends of an external controller, and signal input ends of the wireless receiver (225) are wirelessly connected with signal output ends of the external controller.
5. The high-altitude detection device based on power detection according to claim 1, wherein a combined self-adaptive protection component (3) is installed on one side of the protection isolation sleeve (1), and the combined self-adaptive protection component (3) comprises an internal thread block (301);
the protection isolation sleeve (1) and the combined isolation sleeve (201) are symmetrically hinged with an inner threaded block (301), one end of the inner threaded block (301) is connected with a supporting bolt (302) through threads, one end of the supporting bolt (302) is welded with a linkage operation block (303), one end of the linkage operation block (303) is rotationally connected with a supporting bearing rod (304), one end of the supporting bearing rod (304) is welded with an arc-shaped guide plate (305), the protection isolation sleeve (1) and one end of the combined isolation sleeve (201) are symmetrically welded with a blocking mounting plate (306) at positions corresponding to the inner threaded block (301), a combined supporting hole (307) is formed in one end of the blocking mounting plate (306) and one end of the inner threaded block (301), an inner threaded column (308) is embedded and mounted in one end of the inner threaded column (308) through threads, and a limiting cable (309) is connected with one end of the inner threaded column (307) through threads;
the protection isolation sleeve (1) and the combined isolation sleeve (201) are welded with a guiding inner hole plate (310) at positions corresponding to the limiting cables (309), a plurality of inner hole fixing strips (311) are welded at one ends of the limiting cables (309), inner hole limiting blocks (312) are mounted at positions corresponding to the inner hole fixing strips (311) at one ends of the inner sides of the arc-shaped guide plates (305), and closing pins (313) are mounted between the inner hole limiting blocks (312) and the inner hole fixing strips (311) in an embedded mode.
6. The high-altitude detection device based on electric power detection according to claim 5, wherein the longitudinal section of the arc-shaped guide plate (305) is U-shaped, the middle longitudinal section of the linkage operation block (303) is hexagonal, and the longitudinal section of the internal thread column (308) is T-shaped.
7. The power detection-based high-altitude detection device according to claim 5, wherein the side end of the internal thread block (301) is attached to the side end of the blocking mounting plate (306), the side end of the inner hole fixing strip (311) is attached to the side end of the arc-shaped guide plate (305), and the limiting cable (309) is in sliding sleeve connection with the guide inner hole plate (310).
8. The high-altitude detection device based on electric power detection according to claim 5, wherein a connection stabilizing assembly (4) is installed on one side of the protective isolation sleeve (1), and the connection stabilizing assembly (4) comprises an internal thread cylinder (401);
the protection isolation sleeve (1) and the combined isolation sleeve (201) are welded with a plurality of internal thread barrels (401) at one end at equal intervals, an installation fixing ring (402) is arranged on the inner side of the internal thread barrels (401) in a threaded connection mode, a closed linkage ring (403) is sleeved at the side end of the installation fixing ring (402), a return spring (404) is welded at the inner side of the closed linkage ring (403), a closed arc plate (405) is welded at one end of the return spring (404), an insertion spring (406) is symmetrically welded at one end of the closed arc plate (405), a closed connecting column (407) is welded at one end of the insertion spring (406), a closed electromagnet (408) is embedded and installed at the position of the side end of the closed linkage ring (403) corresponding to the closed arc plate (405), an insertion threaded hole (409) is formed in one end of the closed linkage ring (403), a combined bolt (410) is connected on the inner side of the insertion threaded hole in a threaded connection mode, a powerful pull rope (411) is installed at one end of the combined bolt (410), the powerful pull rope (411) is wound on the side end of a connecting support block (412), a relay support block (412) is welded at one end, a relay spring (414) is embedded in a welding limit fixing frame (413), limiting electromagnets (416) are installed at positions, corresponding to the positions, of the connecting support blocks (412) at the side ends of the relay fixing frames (414), and threading holes (417) are formed at positions, corresponding to the positions of the powerful pull ropes (411), at the side ends of the arc-shaped guide plates (305).
9. The high-altitude detection device based on power detection according to claim 8, wherein the side end of the closed arc plate (405) is attached to the side end of the closed linkage ring (403), the closed connecting post (407) is embedded and mounted at the side end of the closed linkage ring (403), and the strong pull rope (411) is sleeved and connected through the threading hole (417).
10. The high-altitude detection device based on power detection according to claim 8, wherein the connection supporting block (412) is rotatably installed inside the relay fixing frame (414), longitudinal sections of the connection supporting block (412) and the relay fixing frame (414) are respectively of an i-type, and input ends of the closing electromagnet (408) and the limiting electromagnet (416) are electrically connected with output ends of the power supply control group (415).
CN202310700713.8A 2023-06-14 2023-06-14 High altitude detection device based on electric power detects Active CN116625420B (en)

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