CN108748073A - Substation equipment live-line maintenance operation robot - Google Patents

Substation equipment live-line maintenance operation robot Download PDF

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Publication number
CN108748073A
CN108748073A CN201810589418.9A CN201810589418A CN108748073A CN 108748073 A CN108748073 A CN 108748073A CN 201810589418 A CN201810589418 A CN 201810589418A CN 108748073 A CN108748073 A CN 108748073A
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China
Prior art keywords
arm
insulating
encircling
gear
lifting
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Application number
CN201810589418.9A
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Chinese (zh)
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CN108748073B (en
Inventor
杜军
卢刚
许玮
慕世友
任杰
鉴庆之
韩克存
傅孟潮
李建祥
赵金龙
李健
王振利
陈强
董旭
张岩
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Shandong Luneng Intelligence Technology Co Ltd
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Shandong Luneng Intelligence Technology Co Ltd
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Priority to CN201810589418.9A priority Critical patent/CN108748073B/en
Publication of CN108748073A publication Critical patent/CN108748073A/en
Application granted granted Critical
Publication of CN108748073B publication Critical patent/CN108748073B/en
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    • BPERFORMING OPERATIONS; TRANSPORTING
    • B25HAND TOOLS; PORTABLE POWER-DRIVEN TOOLS; MANIPULATORS
    • B25JMANIPULATORS; CHAMBERS PROVIDED WITH MANIPULATION DEVICES
    • B25J9/00Programme-controlled manipulators
    • B25J9/0009Constructional details, e.g. manipulator supports, bases
    • B25J9/0012Constructional details, e.g. manipulator supports, bases making use of synthetic construction materials, e.g. plastics, composites
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B25HAND TOOLS; PORTABLE POWER-DRIVEN TOOLS; MANIPULATORS
    • B25JMANIPULATORS; CHAMBERS PROVIDED WITH MANIPULATION DEVICES
    • B25J15/00Gripping heads and other end effectors
    • B25J15/04Gripping heads and other end effectors with provision for the remote detachment or exchange of the head or parts thereof
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B25HAND TOOLS; PORTABLE POWER-DRIVEN TOOLS; MANIPULATORS
    • B25JMANIPULATORS; CHAMBERS PROVIDED WITH MANIPULATION DEVICES
    • B25J5/00Manipulators mounted on wheels or on carriages
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B25HAND TOOLS; PORTABLE POWER-DRIVEN TOOLS; MANIPULATORS
    • B25JMANIPULATORS; CHAMBERS PROVIDED WITH MANIPULATION DEVICES
    • B25J9/00Programme-controlled manipulators
    • B25J9/16Programme controls
    • B25J9/1602Programme controls characterised by the control system, structure, architecture
    • B25J9/161Hardware, e.g. neural networks, fuzzy logic, interfaces, processor
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B25HAND TOOLS; PORTABLE POWER-DRIVEN TOOLS; MANIPULATORS
    • B25JMANIPULATORS; CHAMBERS PROVIDED WITH MANIPULATION DEVICES
    • B25J9/00Programme-controlled manipulators
    • B25J9/16Programme controls
    • B25J9/1694Programme controls characterised by use of sensors other than normal servo-feedback from position, speed or acceleration sensors, perception control, multi-sensor controlled systems, sensor fusion

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  • Engineering & Computer Science (AREA)
  • Robotics (AREA)
  • Mechanical Engineering (AREA)
  • Automation & Control Theory (AREA)
  • Physics & Mathematics (AREA)
  • Artificial Intelligence (AREA)
  • Evolutionary Computation (AREA)
  • Fuzzy Systems (AREA)
  • Mathematical Physics (AREA)
  • Software Systems (AREA)
  • Manipulator (AREA)

Abstract

The invention discloses a kind of substation equipment hotline maintenance robot, including robot body, the robot body includes:Mobile chassis, the insulated lift arm being set on mobile chassis, insulated lift arm front end connects small fly jib, and the live working platform for placing live line tool is arranged in the small fly jib front end, and the small fly jib is connect by Quick Connect Kit with live line tool;The live line tool includes:Foreign matter cleaning tool, conducting wire mending tool, insulator cleaning tool.Advantageous effect of the present invention:The information of robot body and ambient enviroment is perceived, the safety and reliability of robot manipulation is improved using a plurality of types of sensors installed in robot using multi-sensor information fusion technology.

Description

Live overhaul operation robot for substation equipment
Technical Field
The invention relates to the technical field of live overhaul operation of transformer substations, in particular to a live overhaul operation robot for transformer substation equipment.
Background
With the continuous development of society, the development of power grids faces the requirements of high power supply reliability, high load density and high power quality, the requirements of users on power failure time are more strict, the power failure of important key lines is difficult to arrange, and the power failure maintenance opportunities are less and less.
The transformer substation equipment is easy to generate pollution flashover phenomenon in long-term operation, so that the grounding accidents of the power system are frequent, and the safe operation of the power system is seriously influenced; in order to prevent accidents such as power failure due to contamination of insulators, it is necessary to employ methods such as cleaning insulators periodically and replacing defective insulators.
In addition, the overhead line circuit in the transformer substation is exposed to outdoor environment for a long time, the steel-cored aluminum stranded wire often has the phenomenon of strand breaking of the wire and the like when the steel-cored aluminum stranded wire is blown by wind and is exposed to the sun and the like under severe environments, the phenomenon of strand breaking of the wire due to vibration can also occur under the action of external force when the circuit runs, the wire needs to be repaired under the condition, and the mechanical strength reduction of the circuit caused by the further expansion of the steel-cored aluminum stranded wire strand scattering is prevented, so that safety accidents are caused.
According to the related regulations, when the strength loss of the wire damaged at the same position exceeds 5% but less than 17% of the total breaking force and the sectional area damage does not exceed 25% of the total sectional area of the conductive part at the same time, the repairing tube is used for repairing. At the present stage, the repairing is mainly carried out manually, the working strength is high, the efficiency is low, the automation degree is low, and certain potential safety hazards exist.
For the two situations, most of the existing working modes adopt a power failure operation mode, however, with the improvement of the requirement of power users on the reliability of power supply, the reduction of the times of power failure maintenance of the transformer substation is very important.
Therefore, the power grid has a very urgent need for advanced live overhaul operation technology. However, because of the problems of high voltage level, dense equipment in the substation, large volume and weight of the equipment and the like, the development of manual live working has great difficulty, and the application of the robot technology can effectively solve the problems.
The live working robot of transformer substation disclosed in the prior art mainly has the following disadvantages:
(1) the insulation performance requirement of hot-line work to the robot arm is higher, and the mode that current hot-line work robot arm realized insulating is for realizing insulating through set up insulating cover or other insulating material outsourcing outside the arm, and this kind of mode is implemented more difficultly, can influence the free activity of arm even. The small fly jib at the tail end of the mechanical arm is connected with the telescopic jib by adopting a connecting rod structure, and the flutter phenomenon of the connecting rod mechanism easily causes the vibration of the small fly jib in the live working process, thereby seriously affecting the working accuracy and efficiency.
(2) The existing mechanical arm structure can only be fixedly connected with one working tool, the flexible and quick replacement of the working tool cannot be realized, and the hot-line work efficiency is seriously influenced.
(3) Because the equipment in the transformer substation is numerous and the high voltage is electrified, the working tool needs to go deep into the transformer substation for working, so the tool is required to have the characteristics of miniaturization, light weight, intellectualization and the like. The existing lead repairing device and cleaning device can not realize intelligent repairing and intelligent cleaning;
(4) in the prior art, the wire repairing tool is made of metal, so that hot-line work cannot be realized, and the safety is poor. The problems of untight crimping and rotation of the wire repairing sheet inevitably occur in the crimping process, and the repairing quality of the wire cannot be ensured.
(5) The existing insulator cleaning device needs to manually lift two brushes to the position where an insulator contacts through an insulating rod after the power failure of equipment, and the brushes are driven to rotate through an insulating transmission rod by a motor arranged at the bottom of the insulating rod. The structure and the operation mode cause great physical and psychological burdens on operators, the cleaning effect is only observed from the ground manually, and the judgment error is large. And the brush head of the brush is only one, so that the insulator cannot be cleaned in an encircling manner, the automation degree is low, potential safety hazards exist, and great damage can be caused to equipment and personal safety if the brush head is not operated properly.
Disclosure of Invention
In order to solve the defects of the prior art, the invention provides the live-line maintenance operation robot for the substation equipment, and the live-line operation tool quick-change joint is arranged at the tail end of the mechanical arm, so that the robot can adapt to various different live-line operation modes.
In order to achieve the purpose, the invention adopts the following technical scheme:
the invention discloses a transformer substation equipment live overhaul operation robot, which comprises a robot body, a robot body and a control system, wherein the robot body is provided with a control system; the robot body includes: the device comprises a mobile chassis and an insulated lifting arm arranged on the mobile chassis, wherein the front end of the insulated lifting arm is connected with a small fly jib, the front end of the small fly jib is provided with a live working platform for placing a live working tool, and the small fly jib is connected with the live working tool through a quick connecting device;
the live-wire work tool includes: foreign matter cleaning tool, wire repair tool and insulator cleaning tool.
Further, the insulating lifting arm includes: the rotary platform, the main arm, the upper arm, the insulating telescopic arm and the small fly jib are connected in sequence; the device is characterized by further comprising an insulating lifting arm control system, wherein sensors for detecting the rotation angle and the position of the main arm and the upper arm are respectively arranged on the main arm and the upper arm; the insulated telescopic arms are respectively provided with a sensor for detecting the telescopic length and the position of the insulated telescopic arms; the small flying arms are respectively provided with a sensor for detecting the rotating angle and the horizontal inclination angle of the small flying arms; the insulating lifting arm control system respectively controls the motion of the main arm, the upper arm, the insulating telescopic arm and the small fly jib according to the data acquired by the sensors, and realizes one-key restoration of the insulating lifting arm system and leveling of the small fly jib according to a set priority sequence;
or,
the main arm and the upper arm both comprise two sections of metal arms and an insulating arm arranged between the two sections of metal arms; and/or the small fly arm is of a hollow rod structure made of insulating materials;
or,
the small flying arm is connected with the insulating telescopic arm and is driven by the rotary swing oil cylinder and the pitching swing oil cylinder to realize relative rotary swing and pitching swing with the insulating telescopic arm;
or,
the front end of the small fly jib is provided with a live working platform, and the small fly jib realizes leveling of the live working platform through a leveling swing oil cylinder; the live working platform is provided with a panoramic camera and a laser scanner respectively and is used for realizing image acquisition and distance measurement.
Furthermore, the wire repairing tool comprises a shell, wherein a driving mechanism is arranged in the shell, and the driving mechanism is respectively connected with the left clamping arm and the right clamping arm and drives the left clamping arm and the right clamping arm to realize opening and closing movement; and a base for fixing the repairing piece is arranged between the left clamping arm and the right clamping arm and along the direction vertical to the movement direction of the clamping arms, and wire combining devices are respectively arranged at two ends of the base.
Further, the drive mechanism includes: a worm gear transmission mechanism and a driving motor;
the driving motor drives the worm shaft to rotate through the transmission gear, two sections of spiral teeth are arranged on the worm shaft, each section of spiral teeth is connected with a worm wheel, and the worm wheels are connected with the left clamping arm and the right clamping arm respectively; the worm shaft rotates to drive the worm wheel to rotate, so that the left and right clamping arms are driven to move.
Further, the wire repair tool further comprises a repair patch, the repair patch comprising:
the wire crimping region is connected with at least two crimping teeth on one side of the wire crimping region, a gap with a set distance is formed between every two crimping teeth, and the other side of the wire crimping region is connected with crimping teeth corresponding to the gap; the tail end of the crimping tooth is bent inwards to form a set radian;
or,
openings are respectively formed in the front end and the rear end of the wire crimping area, and the size of each opening meets the requirement of transition fit with the trapezoidal pin shafts arranged at the two ends of the base;
or,
a through hole is formed in the center of the wire crimping area;
or,
the wire crimping area is an arc-shaped groove, and the bending radian of the arc-shaped groove and the inward-bending radian of the tail end of the crimping tooth are determined according to the diameter of the wire.
Further, the sweeping tool includes: the cleaning device comprises a vertical lifting mechanism, an encircling rotating mechanism and a cleaning mechanism, wherein the encircling rotating mechanism is arranged on one side of the vertical lifting mechanism, and the cleaning mechanism is arranged at two ends of the encircling rotating mechanism and can respectively horizontally rotate along the annular axis of the encircling rotating mechanism; the encircling rotating mechanism comprises an encircling support and a ring gear; the encircling support is provided with an annular inner cavity, a guide groove is formed in an inner cavity bottom plate of the encircling support, and the annular gear is limited in the guide groove and moves along the guide groove.
Further, the embracing rotation mechanism further comprises: the hydraulic motor and the rotating gear are encircled, and one side of the ring gear is exposed out through an opening arranged on one side surface of the encircling support so as to be matched with the rotating gear; the encircling hydraulic motor is used for driving the rotating gear to drive the ring gear to horizontally rotate around the axis of the encircling support in the inner cavity of the encircling support; the cleaning mechanisms are arranged on the top surface of the ring gear and are respectively positioned at two ends of the ring gear;
or,
the encircling rotating mechanism further comprises a rotating control part, the rotating control part comprises at least two encircling limit position proximity switches and stop irons, and the stop irons are respectively arranged on the cleaning mechanism; the encircling limit position proximity switches are respectively arranged on the encircling support and used for sending an electric signal to a proportional direction valve of the encircling hydraulic motor when the position of the stop iron is sensed so as to change the direction of the proportional direction valve, and thus the rotating gear is driven to rotate;
furthermore, a T-shaped guide groove is formed in an inner cavity bottom plate of the encircling support, and a T-shaped sliding block matched with the T-shaped guide groove is arranged on a gear ring of the annular gear; the T-shaped sliding block moves in the T-shaped guide groove.
Further, the vertical lifting mechanism comprises an insulating slide rail, a connecting support, a lifting hydraulic motor and a lifting gear, wherein the connecting support is arranged on the insulating slide rail, and the lifting hydraulic motor and the lifting gear are arranged on one side, opposite to the surrounding rotating mechanism, of the connecting support; the lifting hydraulic motor is connected with the lifting gear through a worm gear speed reducer, the lifting gear and the insulating slide rail form a transmission pair, and the lifting hydraulic motor is used for driving the lifting gear to move up and down along the insulating slide rail so as to drive the connecting support to move up and down along the insulating slide rail.
Further, the sweeping mechanism includes: the cleaning device comprises a brush, a rotary motor and a cleaning motor support, wherein the cleaning motor support is fixed on the encircling rotary mechanism, the rotary motor is arranged on the cleaning motor support, and the brush is connected to a rotary shaft of the rotary motor and driven to rotate by the rotary motor.
Compared with the prior art, the invention has the beneficial effects that:
(1) each part of mechanical arm comprises an insulating section and a metal section, so that the material cost can be saved, the weight of the whole mechanical arm is reduced, and the stability of the gravity center of the robot in the operation process is facilitated.
(2) The small fly arm is changed into an insulating material hollow rod structure from a link mechanism. Its main advantage lies in: the stability of the structure is increased, the vibration phenomenon of the connecting rod mechanism in the operation process is effectively prevented, and the assembly and the maintenance are convenient. The driving mechanism of the device is changed from a linear oil cylinder to a swing oil cylinder, so that the installation of a sensor is convenient, and the control precision is improved. On the basis of the original pitching freedom degree, the small flying arm is additionally provided with a rotary freedom degree and a platform fine-tuning freedom degree, so that the platform is more convenient to control and move.
(3) The operation arm sets up quick-change head, and the operation instrument that can be different fast provides work efficiency.
(4) The robot adopts a multi-sensor information fusion technology, and senses information of a robot body and the surrounding environment by using various types of sensors arranged on the robot, so that the safety and the reliability of the operation of the robot are improved.
(5) In order to facilitate the development of the recovery work after the operation of the robot is finished, the project adopts a one-key automatic intelligent recovery design, the robot automatically establishes a distribution database such as distance, magnetic field and the like in an operation space range by utilizing various sensors installed on a robot body in the operation development process, and after the operation is finished, a safety path planning algorithm is adopted, so that the safe path of the robot can be installed and the robot returns to a default state, and the one-key automatic intelligent recovery is realized. Ensuring the safe distance between the robot and the live equipment is an effective way to ensure insulation safety, so the design of the distance measuring sensor is very important.
Drawings
The accompanying drawings, which are incorporated in and constitute a part of this specification, are included to provide a further understanding of the invention, and are incorporated in and constitute a part of this specification, illustrate embodiments of the invention and together with the description, serve to explain the invention and not to limit the invention.
FIG. 1 is a schematic view of the operation of the insulator cleaning tool of the present invention;
FIG. 2 is a front view of the insulated lift arm system;
FIG. 3 is a top view of the insulated lift arm system of the present invention;
FIG. 4 is a side view of the insulated lift arm system configuration of the present invention;
FIG. 5 is a schematic diagram of a live-wire repairing system for a transformer substation according to the present invention;
FIG. 6 is a schematic view of a patch sheet of the live-wire work lead system of the transformer substation according to the present invention;
FIG. 7 is a schematic structural diagram of a live-line cleaning system for post insulators of a substation;
FIG. 8 is a schematic view of an encircling rotating mechanism according to the present invention;
FIG. 9 is a schematic view of the vertical lift mechanism of the present invention;
FIG. 10 is a schematic view of a T-shaped chute of the present invention.
Detailed Description
It is to be understood that the following detailed description is exemplary and is intended to provide further explanation of the invention as claimed. Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs.
It is noted that the terminology used herein is for the purpose of describing particular embodiments only and is not intended to be limiting of example embodiments in accordance with the invention. As used herein, the singular forms "a", "an" and "the" are intended to include the plural forms as well, and it should be understood that when the terms "comprises" and/or "comprising" are used in this specification, they specify the presence of stated features, steps, operations, devices, components, and/or combinations thereof, unless the context clearly indicates otherwise.
In order to solve the defects of the prior art pointed out in the background art, the invention provides a live overhaul operation robot for substation equipment, which comprises: the robot comprises a robot body and a remote control terminal; the remote control terminal is communicated with the robot body to realize remote control of the robot body.
The robot body includes: the device comprises a mobile chassis and an insulated lifting arm arranged on the mobile chassis, wherein the front end of the insulated lifting arm is connected with a small fly jib, the front end of the small fly jib is provided with a live working platform for placing a live working tool, and the small fly jib is connected with the live working tool through a quick connecting device;
the live-wire work tool includes: a wire repairing tool, an insulator cleaning tool;
the operation platform is mainly used for placing parts such as a wire repairing tool, an insulator cleaning tool and an electric cabinet, and is provided with control monitoring components such as a panoramic camera, a laser range finder and an ultrasonic sensor.
The remote control terminal comprises a remote control module and a wireless communication module, wherein the remote control module comprises an industrial personal computer, a liquid crystal display screen and a handle key; the industrial personal computer is communicated with the main controller of the robot body through the wireless communication module. The wireless communication module is composed of a network bridge and an antenna and adopts a 2.4G wireless communication mode. The handle button includes: a key for controlling the cleaning direction of the cleaning mechanism; a button for controlling the pitch/rotation of the mechanical arm; the key is used for controlling the hydraulic support leg of the movable chassis; a one-key reset control button and a manual/automatic switching button, etc.; the robot body and the live working tool are remotely controlled through the remote control terminal.
The robot needs to move with the help of a moving tool in the transformer substation during walking operation, and the transformer substation live-line maintenance robot adopts a crawler-type moving chassis structure. The crawler-type mobile chassis is composed of a chassis, a crawler frame, a driving wheel, a bearing wheel, a crawler, a tensioning buffer device and four hydraulic support legs at two sides, can realize barrier-free movement under various complex road conditions, and provides a mobile platform support for an overhaul operation robot.
The movable chassis for the live-line overhaul robot of the transformer substation adopts an electro-hydraulic driving scheme, namely a single motor, a single hydraulic pump and a hydraulic motor driving scheme, a motor (usually a direct current motor) is adopted to drive a hydraulic pump, the electric chassis comprises a hydraulic motor and a speed reducer integrated walking device, a rubber track, a driving wheel, a guide wheel, a tensioning mechanism and the like, and the movable chassis has the advantages that an upper insulating part and a supporting part of the robot can share one set of hydraulic system with the chassis, and the redundancy of the system is reduced.
A lithium battery pack and a battery management system, a high-voltage control box, a charger, a chassis control valve group, a chassis control box, a hydraulic oil tank, a high-power motor, a hydraulic pump, a hydraulic radiator, a storage battery and the like are respectively arranged in the mobile chassis; the crawler-type electric chassis structure is adopted, and for a chassis with 3-3.5 tonnage, the electric mode is adopted in China, so that the crawler-type electric chassis structure belongs to the first case, has the functions of low noise, energy conservation, environmental protection and energy conservation, and has very important significance for environmental protection.
In order to ensure the overall stability of the robot body, the layout of the mobile chassis is optimally arranged, and the layout is mainly embodied in the following aspects:
(1) the battery position is optimized, adjusted and arranged in the center of the chassis, so that the overall stability of the chassis is improved;
(2) the battery high-voltage system and the charger are positioned at the front part of the chassis and are close to the battery, and the connection between the battery high-voltage system and the charger and the battery is convenient, so that the maintenance is convenient;
(3) the hydraulic oil tank and the corresponding hydraulic accessories are positioned at the right rear side of the center of the chassis, so that the overall stability of the chassis is improved, and the effective utilization space in the chassis is saved;
(4) the motor and the hydraulic pump are positioned at the lower part of the left rear part of the center of the chassis and are symmetrically arranged with the oil tank, so that the overall stability of the chassis is improved, and the distance between the hydraulic pump and the oil tank is short, thereby being beneficial to the oil discharge of hydraulic oil;
(5) the arrangement of two storage batteries is added, the storage battery (24V) is mainly used for providing a low-voltage power supply for a BMS system of the battery, a hydraulic radiator, a motor controller and electric equipment of the chassis, and the storage battery is arranged at the upper parts of the motor and the hydraulic pump, so that the internal space of the chassis is effectively utilized;
(6) the chassis control box is positioned at the upper part of the storage battery, and the storage battery is close to the chassis control box, so that power supply is facilitated;
(7) the chassis control valve group is positioned on the right part of the rear part of the chassis, so that the manual operation of an operator is facilitated;
(8) the hydraulic radiator is adjusted to be the tail part of the chassis, hydraulic oil circulates through the oil pump, the executing part and the hydraulic radiator, and the hydraulic radiator flows back to the oil tank after radiating, so that the radiating of the hydraulic oil is facilitated.
An insulated lifting arm system for live overhaul work of a transformer substation, as shown in fig. 2, includes: the device comprises a rotary speed reducer, a rotary platform, a main arm, an upper arm, an insulating telescopic arm and a small fly jib;
the main arm is connected with the amplitude-variable oil cylinder, and the pitching of the main arm is realized through the stretching of the amplitude-variable oil cylinder;
as shown in fig. 3, the main arm is rotatably connected with the upper arm, and the upper arm is driven by the upper arm swing cylinder to realize the pitch-up movement relative to the main arm; the upper arm swing oil cylinder is arranged to realize the pitching lifting of the upper arm, and compared with a traditional luffing oil cylinder, the arrangement space of the mechanical arm is saved, and the structure compactness and the operation stability are improved.
The upper arm is fixedly connected with the insulating telescopic arm, the insulating telescopic arm adopts a synchronous telescopic structural mode, and all sections of telescopic arms are simultaneously telescopic at the same stroke ratio in the telescopic process of the arm support. The insulating telescopic arm is driven by a linear oil cylinder arranged in the insulating telescopic arm to realize the telescopic action; the telescopic device of the insulating arm is used for realizing the telescopic effect of the insulating arm, the telescopic speed ratio of the chain telescopic device is set to be 1:2 by utilizing the principle of a movable pulley and a fixed pulley, namely the oil cylinder extends out by 100mm, and the insulating telescopic arm extends out by 200 mm. The telescopic mode can effectively shorten the length of the insulated telescopic arm and increase the insulation distance.
The front end of the insulated telescopic arm is provided with an ear plate for mounting the small fly arm and is used for connecting the small fly arm; the small fly jib is movably connected with the telescopic inner jib and is of an insulating material hollow rod structure, so that the stability of the structure is improved, the flutter phenomenon of a connecting rod mechanism in the operation process is effectively prevented, and the assembly and maintenance are convenient. The small fly arm driving mechanism is a swing oil cylinder, so that the sensor is convenient to mount, and the control precision is improved. The small flying arm is driven by the rotary swing oil cylinder and the pitching swing oil cylinder to realize relative rotary swing and pitching swing with the telescopic inner arm; the small fly arm realizes the fine adjustment of the platform through the leveling swing oil cylinder; the small flying arm is provided with a pitching degree of freedom, a rotation degree of freedom and a platform fine tuning degree of freedom, so that the platform is more convenient to control and move.
The main arm comprises two sections of metal arms and an insulating arm arranged between the two sections of metal arms; the upper arm comprises two sections of metal arms and an insulating arm arranged between the two sections of metal arms; the insulating telescopic arm comprises an insulating outer arm and a telescopic inner arm; the small fly jib comprises two sections of metal arms and an insulating arm arranged between the two sections of metal arms; the arrangement mode of the mechanical arm material can realize good insulation on one hand, meets the requirement of live working, reduces the whole weight of the mechanical arm on the other hand, and improves the whole stability of the mechanical arm.
As shown in fig. 4, the front end of the small fly jib is provided with a live working platform, and the live working platform is provided with a panoramic camera and a laser scanner respectively for realizing image acquisition and ranging.
The hot-line work platform is mainly provided with a hot-line work special device such as a hydraulic mechanical arm (foreign matter cleaning tool), an insulator cleaning tool, a dry ice cleaning tool and the like. Therefore, the leveling precision and the leveling reliability of the hot-line work platform directly influence the effect and the efficiency of the hot-line work.
In order to ensure that the hot-line work platform has higher leveling precision and leveling reliability in the working process, an electro-hydraulic automatic leveling method is adopted in the design process of the leveling system. Once the hot-line work platform is inclined in the working process, the angle sensor arranged on the hot-line work platform sends a detected corresponding signal to the driving circuit, so that the electro-hydraulic reversing valve is controlled to act, the position of the leveling swing oil cylinder is adjusted, and the working platform is adjusted to be in a horizontal state again.
The live working tool and the small fly jib are connected through the quick connecting device, and the hydraulic pipelines are connected through the quick change coupler, so that the quick switching of different working tools is realized.
The main arm and the upper arm are respectively provided with an encoder and a proximity switch, and the rotation angle and the position information of the main arm and the upper arm can be obtained; the three side surfaces of the upper arm elbow joint are respectively provided with 3 ultrasonic sensors which are used for collecting the distance from the elbow joint to equipment in the transformer substation; the insulating telescopic boom is provided with a laser ranging sensor, so that the telescopic length of the telescopic inner boom can be obtained; the small fly jib is respectively provided with an inclination angle sensor and a horizontal rotary encoder, so that the rotation angle and the horizontal inclination angle of the small fly jib can be obtained; one-key restoration of the insulating lifting arm system and leveling of the small fly arm are achieved according to a set priority sequence by fusing data of multiple sensors.
The working process of the insulating boom is as shown in fig. 4, and the live working tool is accurately conveyed to a target position by controlling the pitching of the main boom and the upper boom, the stretching of the insulating telescopic boom and the fine adjustment of the precision of the small fly boom.
The invention relates to an insulation lifting arm system for live-line maintenance operation of a transformer substation, which further comprises: insulating lifing arm control system, said insulating lifing arm control system includes: the system comprises a main controller, an auxiliary controller and a signal acquisition module; the main controller is communicated with the auxiliary controller through optical fiber signal acquisition modules;
the signal acquisition module is used for acquiring upper arm rotation angle information and main arm safety protection information and transmitting the acquired information to the main controller; (3 ultrasonic sensors are respectively arranged on three side surfaces of the elbow joint and used for collecting the distance from the elbow joint to equipment in the transformer substation);
the auxiliary controller collects data of the ultrasonic sensor arranged on the upper arm to obtain a voltage signal, and the voltage signal is converted into distance information to control the hydraulic proportional valve of the elbow joint.
The auxiliary controller collects data of a laser ranging sensor arranged on the insulating telescopic boom to obtain the distance between the insulating telescopic boom and substation equipment, so that the telescopic length of the insulating telescopic boom is controlled;
the auxiliary controller collects data of an inclination angle sensor arranged on the automatic operation platform to obtain the rotation angle of the small fly jib, so that the rotation angle of the small fly jib is controlled;
the auxiliary controller collects data of a horizontal rotary encoder arranged on the small fly arm to obtain a horizontal inclination angle of the small fly arm, so that the horizontal inclination angle of the small fly arm is controlled;
the main controller respectively collects data of encoders arranged on the main arm and the upper arm to obtain the rotating angles of the main arm and the upper arm, so that the control of the rotating angles of the main arm and the upper arm is realized;
the main controller respectively collects data of proximity switches installed on the main arm and the upper arm to obtain position information of the main arm and the upper arm, and accordingly position control of the main arm and the upper arm is achieved.
Insulating lifing arm control system includes: little fly jib leveling control system specifically includes: the device comprises an inclination angle sensor, a leveling electromagnetic valve and a signal input/output terminal; the inclination angle sensor is connected with a main controller through a signal input and output terminal, and the main controller is connected with the electromagnetic valve;
the inclination angle sensor detects the inclination angle of the automatic operation platform and outputs the inclination angle in the form of a voltage signal, the controller reads the numerical value through the signal input and output terminal, the obtained inclination angle data is compared with the allowable error, and when the inclination angle data is larger than the allowable error, the control over the leveling swing oil cylinder is realized by adjusting the opening degree and the movement direction of the valve core of the leveling electromagnetic valve, so that the leveling operation is realized.
Insulating lifing arm control system still includes: the insulating lifting arm one-key reduction control system; the method comprises the following steps: the device comprises a rotary shaft valve group, a coder, a telescopic shaft valve group, a telescopic shaft laser ranging sensor, a leakage current sensor and an ultrasonic sensor;
wherein, the positions of the main arm and the upper arm are respectively provided with an encoder for realizing the measurement of the rotating angles of the main arm and the upper arm;
a telescopic shaft laser ranging sensor is arranged on the telescopic inner arm and used for measuring the telescopic distance of the telescopic arm;
setting a leakage current sensor to realize measurement of a leakage current value;
and an ultrasonic sensor is arranged at the position of the upper arm and used for measuring the distance information between the upper arm and the substation equipment.
The telescopic arm is controlled to stretch through the telescopic shaft valve group, and the rotation of the rotary platform is controlled through the rotary shaft valve group.
The process for realizing the one-key reduction of the insulating lifting arm comprises the following steps:
restoring the rotating shaft of the insulating arm
When the rotating shaft of the insulating arm is recovered, the rotating shaft valve group drives the rotating shaft to move, the corresponding encoder detects the angle value of the rotating shaft in real time, and when the numerical value of the encoder is 0, the recovery is considered to be completed;
② recovering the telescopic shaft of the insulating arm
When the telescopic shaft is recovered, the telescopic shaft valve group drives the telescopic shaft to move, the telescopic shaft laser ranging sensor detects the length of the telescopic shaft in real time, and when the value of the laser ranging sensor is 0, the recovery is considered to be completed;
in the process of recovering the insulating arm, the leakage current sensor and the ultrasonic sensor detect the whole leakage current value of the robot and the distance between the corresponding part and the substation equipment in real time; when the leakage current value exceeds a safety value, all actions of the whole robot are stopped; when the value of the ultrasonic sensor exceeds the safety value, the valve group at the corresponding part stops working.
The one-key restoration is to trigger the robot to automatically reset by one key so as to reset the robot from the working state to the pre-working state. The reset process realizes the monitoring of each joint and the obstacle avoidance with equipment in the transformer substation, and the one-key reset function is realized by the fusion of multiple sensors based on a robot.
After the robot works, the supporting legs of the robot chassis are opened, the insulating arm extends and rotates to different degrees, and the special working tool is in a working state. After one-key restoration, the supporting legs of the robot chassis are recovered and leveled to the chassis, the insulating arm is recovered and rotated to be in a minimum space state, and the working tool is recovered to be in the minimum space state.
And after the one-key restoration system is triggered, comparing the current state and the initial state of each actuator, and finishing restoration when the difference value between the current state and the initial state is less than a certain error value.
Trigger the automatic system of retrieving of insulating arm through a key, the recovery process: the leakage current sensor detects the magnitude of the leakage current of the whole robot, the ultrasonic sensor detects the distance between each part and the substation equipment, the encoder compares the real-time value with the initial value, and when the error between the real-time value and the initial value is smaller than a certain value, the inclination angle sensor detects the inclination angle of the chassis and controls the landing leg motor to be in a horizontal value. And finishing the recovery operation. The reduction process is completed according to the priorities of the sensors and the actuators.
When the leakage current value and the distance value are within the normal range, the actuators are recovered in the order of top to bottom. The method comprises the steps of firstly recovering each tool, then recovering a small fly jib, a telescopic jib, an upper jib and a main jib respectively, and finally leveling a chassis through a support oil cylinder.
The operation of one-bond reduction is mainly divided into: telescopic reduction, rotary reduction and tool reduction. Wherein:
the telescopic reduction mainly refers to the reduction of the telescopic arm, a detection component for the reduction of the telescopic arm is a laser ranging sensor, and when the error between the sensor data and a set value is less than 10mm, the reset operation is considered to be finished;
the rotary restoration mainly means that each joint is rotated and restored, a detection component for rotary restoration is an encoder, and when the data error of the encoder is less than 1 degree, the restoration operation is considered to be completed;
the tool restoration mainly refers to restoration of each tool subsystem, state judgment is respectively carried out according to technical indexes, and when the difference value between real-time data and set data is smaller than an allowable error, the restoration operation is considered to be finished.
In the process, the states of the actuators are monitored in real time, collision between the actuators and substation equipment is avoided, leakage current is prevented from being overlarge, and the robot is guaranteed to be in a safe operation state.
The safety protection comprises robot operation safety protection and motion control safety protection, wherein the operation safety protection associated sensor is as follows: the device comprises a laser scanner, a laser ranging sensor, a leakage current sensor and an encoder; the motion control safety protection related sensor comprises: ultrasonic sensor, tilt sensor and proximity switch. And the ultrasonic sensors are arranged at the tail end of the telescopic arm, the elbow and the tail end of the small arm for ranging, and the distance is smaller than a safety value to decelerate and stop.
A leakage current sensor is arranged in front of the tool, the leakage current is greater than 1mA, and a warning lamp flickers.
After the multi-sensor fusion system is triggered, the leakage current value, the distance value, the encoder value and the chassis inclination angle value of the whole machine are detected in sequence, the data are judged according to the sequence, and when all the data are in the normal range, the corresponding actuators perform resetting operation in sequence. In the detection and execution, simultaneous determination may occur in each sensor and actuator, so it is necessary to prioritize them according to the degree of urgency.
Different types of actuators and sensors respectively have different priorities according to functions, wherein in the sensors, a leakage current sensor has the highest priority, and then an ultrasonic sensor, an inclination angle sensor and an encoder are arranged, and the sensor with the lowest priority is a laser sensor and a visual sensor; among the actuators, the insulated arm action actuator has the highest priority, followed by the work tool, and the lowest priority actuator is the chassis drive and leg control actuator.
In the robot operation process, the condition that one sensor corresponds to a plurality of actuators can occur, so that the priorities are the same, system misjudgment can occur, the judgment priority is introduced to avoid the occurrence of similar conditions, and the judgment priority is as follows: any actuator priority is multiplied by the priority of its associated actuator. Therefore, when the above situation occurs, the system determines the action sequence of the actuators by judging the priority, namely when a plurality of sensors simultaneously judge, the action of the corresponding actuators is controlled according to the judging priority.
Taking an ultrasonic sensor as an example:
the priority of the chassis driving protection ultrasonic sensor is as follows:
2 (ultrasonic transducer) × 3 (chassis drive) ═ 6
The priority of the telescopic boom rotating ultrasonic sensor is as follows:
2 (ultrasonic sensor) × 1 (telescopic arm rotation) ═ 2
Obviously: 2<6, so when both ultrasonic sensors make a determination at the same time, the robot arm rotation will first slow down to stop.
In the process of recovering the insulating arm, the leakage current sensor and the ultrasonic sensor detect the leakage current value of the whole robot and the distance between the corresponding part and the substation equipment in real time. When the leakage current value exceeds a safety value, all actions of the whole robot are stopped; when the value of the ultrasonic sensor exceeds the safety value, the valve group at the corresponding part stops working.
The live-wire operation wire repair tool for the transformer substation comprises a shell, wherein an opening is formed in the shell, a driving mechanism is arranged at the opening, and the driving mechanism is connected with a left clamping arm and a right clamping arm respectively and drives the left clamping arm and the right clamping arm to move in an opening and closing manner; and a base for fixing the repairing piece is arranged between the left clamping arm and the right clamping arm and along the direction vertical to the motion direction of the clamping arms, and two ends of the repairing piece base are respectively provided with a thread combining device.
The base is in the shape of an inwards concave arc, and trapezoidal fixed pin shafts are arranged at two ends of the base and used for fixing the repairing piece.
The preferred structure of the drive mechanism includes: a worm gear transmission mechanism and a driving motor;
the driving motor is connected with the transmission mounting seat through a bolt; the worm shaft is connected with the worm key, the left and right clamping arms are respectively connected with the worm wheel through bolts, a through hole is formed between the clamping arms and the worm wheel, the transmission gear is connected with the motor shaft/worm shaft key, the shell, the clamping arms and the worm wheel are in clearance fit through a connecting shaft, and the connecting shaft is fixed through a retaining ring.
The driving motor drives the worm shaft to rotate through the transmission gear, two sections of spiral teeth are arranged on the worm shaft, each section of spiral teeth is connected with a worm wheel, and the worm wheels are connected with the left clamping arm and the right clamping arm respectively; the worm shaft rotates to drive the worm wheel to rotate, so that the left and right clamping arms are driven to move.
The start and stop of the driving motor are realized through a control panel arranged in a control box; the control box is also internally provided with a wireless transceiver module which is provided with a buckle and clamped on an installation slide rail, the installation slide rail is fixed on the lower plate of the control box shell by a bolt, and the wireless transceiver module is used for remote wireless communication. The wireless transceiver module receives a control signal for the driving motor and transmits the control signal to the control board, and the control board controls the start and stop of the driving motor so as to control the working state of the lead repairing device.
A battery seat is further fixed on the shell of the wire repairing device, the battery is in clearance fit with the battery seat, and the battery is mainly used for supplying power to a control panel, a wireless transceiving module, a driving motor, an information acquisition device and the like of the wire repairing device.
The control box shell is also provided with a switch; the switch is provided with threads and a nut, a through hole is formed in the shell of the control box, and the switch penetrates through the through hole and is tightened automatically; the switch has the function of enabling the lead repairing device to be powered on when in work and powered off when not in work, and is beneficial to energy conservation.
It should be noted that the drive mechanism of the present invention may also adopt other drive forms known to those skilled in the art, such as: the left and right clamping arms are driven to rotate by a driving motor or directly driven to rotate back and forth by a stepping motor.
The wire combining device comprises grooves which are respectively arranged at the two ends of the base and used for collecting wires, and the top end of each groove is opened in a funnel shape; the scattered wires are convenient to gather; two sides of the groove close to the bottom are respectively connected with the wire-closing heads with opposite openings; as shown in FIG. 5, the joint line adopts a 3/4 round structure design, the lower edge is a 1/4 round, the upper edge is a 1/2 round, and the joint line is connected with the bolt of the joint line device and can rotate around the bolt; the wire binding head is used for further gathering the gathered loose strand wires together.
The invention further discloses a system for repairing the live-wire operation wire of the transformer substation, which comprises: the device comprises a control system, an information acquisition device, an automatic operation mechanical arm, a lead repairing device and a repairing sheet; the information acquisition device is connected with the lead repairing device through a bolt, comprises a panoramic camera, a laser scanner and other equipment and is mainly used for detecting the specific position of the lead to be repaired; the automatic operation mechanical arm clamps the wire repairing device through clamping the clamping handle, and the repairing sheet presses the wire under the action of the wire repairing device.
As shown in fig. 6, the patch sheet includes:
the wire crimping region is connected with at least two crimping teeth on one side of the wire crimping region, a gap with a set distance is formed between every two crimping teeth, and the other side of the wire crimping region is connected with crimping teeth corresponding to the gap; the tail end of the crimping tooth is bent inwards to form a set radian.
Openings are respectively arranged at the front end and the rear end of the wire crimping area, the size of each opening meets the requirement of transition fit with trapezoidal fixed pin shafts arranged at the two ends of the base, and the openings are positioned by bolts. The fixing problem of the repair piece is effectively solved, and the rotation problem of the repair piece in the wire crimping process is prevented.
The through hole is formed in the center of the lead crimping area, so that weight can be reduced.
The conductor crimping area is an arc-shaped groove, the bending radian of the arc-shaped groove and the inward bending radian of the tail end of the crimping tooth are determined according to the diameter of the conductor, for example, for a 400-type conductor, the bending radian of the arc-shaped groove is designed to be 40 degrees; the bending radius is 15.5 mm; the tip of the crimp tooth is bent inward with a bend radius of 12 mm. Through these two radians of reasonable settlement, can guarantee that two crimping teeth can detain on the wire like the buckle, can also prevent the resilience of crimping back crimping tooth.
The repairing piece is made of an aluminum sheet with the thickness of 2mm, and the aluminum sheet is too thick and is not beneficial to bending and clamping; the thickness of the aluminum sheet is too thin, so that the rebound of the aluminum sheet is easy to influence the crimping effect.
In the embodiment of the invention, the wire repairing device is carried by the live working robot to perform the repairing operation of the wire in the overhead line. The live working robot comprises a movable chassis, an insulating telescopic arm fixed on the movable chassis and an automatic working platform fixed at the front end of the insulating telescopic arm; the automatic operation mechanical arm and the information acquisition device can be fixed on the automatic operation platform, the automatic operation platform is connected with the insulated telescopic arm, and the insulated telescopic arm is fixed on the movable chassis; the telescopic cylinder is used for realizing the telescopic action of the insulating telescopic arm, so that the automatic operation platform is driven to reach an operation position.
It should be noted that both the automatic operation mechanical arm and the insulating telescopic arm are required to have good insulating property, and the specific insulating form may be a form in which an insulating sleeve is added to the mechanical arm, or a form in which the mechanical arm is arranged in an insulating material section and a metal material section which are alternately arranged.
The specific working process of the live-wire operation wire repairing system of the transformer substation is as follows:
the wire repairing tool is clamped by an automatic operation mechanical arm to perform operation, the automatic operation mechanical arm clamps the wire repairing tool to enter the wire from the undamaged side of the wire, and the wire is aligned through the information acquisition device;
the automatic operation arm centre gripping wire repair tools moves to impaired position by the undamaged side, and disconnected strand wire draws in under the effect of wire repair tools line device and closing end: when the wire repairing tool is fed from the undamaged side of the wire, the wire enters the wire repairing tool through the groove of the wire combining device, meanwhile, the wire is contacted with the lower edge of the wire combining head, when the wire enters the wire repairing tool, the wire combining head rotates, the upper edge of the wire combining head is contacted with the wire, the upper semicircle of the wire is surrounded, the wire and the lower end of the groove in the wire combining device together surround the outer diameter of the wire, and when the wire repairing tool travels along the wire, the lower semicircle of the wire is always contacted with the upper edge and the lower edge of the wire combining head, so that the wire combining head does not rotate; a certain gap exists between the wire and the wire combining device and between the wire combining heads, and the scattered wires are gathered under the action of the wire combining device and the wire combining heads.
When the center position of the to-be-repaired piece is opposite to the broken strand of the lead, the automatic operation mechanical arm stops moving, and the driving mechanism of the lead repairing tool drives the clamping arm to press the repaired piece for automatic repairing operation;
after the operation is finished, the clamping arm rotates reversely under the action of the driving motor, and after the clamping arm is completely opened, the driving mechanism is controlled to stop moving;
the automatic operation mechanical arm clamps the wire repairing tool to move towards the right lower part of the wire, and the wire repairing tool is removed from the wire.
The advantages of the wire repair system of the present invention are as follows:
(1) the automatic operation mechanical arm clamping wire repairing device is used for conducting wire repairing operation, has the advantages of being high in mechanical degree, high in automation degree and the like, meets the requirement of wire compression joint in a transformer substation, and guarantees operation safety of operating personnel. The device can effectively reduce the working strength of manual operation, improve the crimping efficiency and the automation level, and has a positive reforming effect on the crimping and repairing operation mode of the transformer substation conductor in China.
(2) The both ends opening and the trapezoidal fixed pin axle transition fit of repair piece, the effectual fixed problem of solving repair piece, and prevented the rotatory problem of repair piece among the wire crimping process.
(3) The worm and gear transmission adopts a split combined structure, so that the processing difficulty of the worm shaft is greatly reduced, the processing precision of the transmission is improved, and the processing cost of the worm and gear is reduced.
(4) Two thread-combining heads are added at the front part of the thread-combining device, and the thread-combining devices are arranged at the two ends of the clamping arm, so that the thread-combining effect is improved.
It should be noted that the foreign matter cleaning tool disclosed by the invention is realized by an automatic operation mechanical arm, namely, the automatic operation mechanical arm and the information acquisition device are arranged on the self-action platform.
As shown in fig. 7, the live-line cleaning tool for a post insulator of a substation according to the present invention includes: the cleaning device comprises a vertical lifting mechanism, an encircling rotating mechanism and two cleaning mechanisms, wherein the encircling rotating mechanism is arranged on the vertical lifting mechanism and can move up and down on the vertical lifting mechanism; the surrounding rotating mechanism is used for arranging the cleaning mechanism on the surrounding rotating mechanism and can drive the cleaning mechanism to horizontally rotate around the axis of the post insulator of the transformer substation; the cleaning mechanism is used for cleaning the post insulator of the transformer substation. Fig. 1 shows an operation schematic diagram of a live cleaning tool for a post insulator of a transformer substation.
Specifically, as shown in fig. 9, the vertical lift mechanism includes a mounting base, an insulating slide rail, a connecting bracket, a lift hydraulic motor, and a lift gear. The mounting base is used for bearing the weight of the cleaning device and can be fixed on the lifting platform when the cleaning device works, so that the lifting platform can convey the cleaning device to a high position to contact the post insulator. Therefore, the mounting base is provided with a connecting structure such as a connecting hole for connecting with the lifting platform.
The insulating slide rail is fixed on the mounting base, and one side of the insulating slide rail is provided with a rack. The connecting bracket is arranged on the insulating sliding rail, and the lifting hydraulic motor and the lifting gear are arranged on one side of the connecting bracket, which is opposite to the rack; the whole transmission gear assembly for lifting is moved to the rear of the rack, so that the condition that the whole cleaning executing mechanism is inclined forwards can be improved, and the functions of positioning in the front and the rear and balancing the counter weight are achieved.
The lifting hydraulic motor is connected with the lifting gear through a worm and gear speed reducer, the hydraulic motor can be prevented from descending along the direction of the rack due to internal leakage, and the cleaning executing mechanism can be stopped at any position of the insulated lifting rack by utilizing the self-locking function of the worm and gear speed reducer.
The lifting gear and the rack on the insulating slide rail form a first transmission pair which can move up and down along the insulating slide rail under the driving of the lifting hydraulic motor, so that the connecting support is driven to move up and down along the insulating slide rail.
The connecting support is also provided with two surrounding limit position proximity switches, the two surrounding limit position proximity switches are electrically connected to the electromagnetic valve of the lifting hydraulic motor and used for sending an electric signal to the electromagnetic valve of the lifting hydraulic motor when the connecting support runs to the upper limit position and the lower limit position on the insulating slide rail, and the electromagnetic valve controls the lifting hydraulic motor to stop running, so that the movement of the connecting support is ensured not to exceed the limit position on the insulating slide rail.
The vertical lifting mechanism can also be provided with a drag chain, one end of the drag chain is arranged on the mounting base, and the other end of the drag chain is connected with the connecting bracket for stabilizing and protecting the operation of the connecting bracket.
In this embodiment, the first transmission pair composed of the insulating slide rail and the lifting gear is made of an insulating material such as Polyoxymethylene (POM) to perform an insulating protection function and prevent the cleaning device and the lifting platform from being broken down.
As shown in fig. 8, the encircling rotation mechanism includes an encircling bracket, a ring gear, an encircling hydraulic motor, and a rotation gear. The encircling support is arranged on one side of the connecting support of the vertical lifting mechanism, is semi-annular and is provided with a semi-annular inner cavity, and two end parts and the top surface of the encircling support are both in an opening shape. The ring gear is disposed in the inner cavity of the surrounding bracket, and one side of the ring gear is exposed through an opening disposed on a side surface of the surrounding bracket (in this embodiment, the ring gear is an outer ring gear, so the side surface is an outer side surface, but not limited thereto), and the ring gear is also semi-annular and can move horizontally in the surrounding bracket to penetrate through the end portion of the surrounding bracket. The encircling hydraulic motor and the rotating gear are both arranged on the connecting support, the rotating gear and the annular gear exposed through the opening on the outer side surface of the encircling support form a second transmission pair which can rotate under the driving of the encircling hydraulic motor, so that the annular gear is driven to horizontally rotate around the axis of the encircling support (namely, the annular axis where the encircling support is located) in the inner cavity of the encircling support.
In this embodiment, the surrounding bracket, the ring gear and the rotating gear are all made of insulating materials so as to play a role in insulation and protection.
In order to limit the running position of the ring gear in the encircling support so as to prevent the ring gear from moving in the encircling support and deviating from the running position so as not to be tightly matched with the encircling support, a T-shaped guide groove is arranged on a bottom plate of an inner cavity of the encircling support, and a T-shaped sliding block matched with the T-shaped guide groove is arranged on a gear ring of the ring gear, as shown in FIG. 10; the positioning and sliding of the gear ring are realized through the T-shaped guide groove, so that the positioning of the gear ring can be realized, the friction resistance in the motion process can be reduced, and the head warping phenomenon of the encircling mechanism in the motion process is avoided.
The two cleaning mechanisms are arranged on the top surface of the ring gear surrounding the rotating mechanism and are respectively positioned at two ends of the ring gear, so that the two cleaning mechanisms can be driven by the ring gear to horizontally rotate around the axis of the surrounding support. Each cleaning mechanism comprises a brush, a rotary motor and a motor bracket, wherein the motor bracket is fixed on the ring gear; the rotating motor is arranged on the motor bracket; the brush is connected to a rotation shaft of the rotation motor, and in this embodiment, it may be connected to the rotation shaft of the rotation motor through a flat key and a set screw, and is driven by the rotation motor to rotate. The brush filaments of the brush can be made of nylon materials, so that dirt on the surface of the post insulator can be effectively removed, and the outer surface of the post insulator can be protected from being damaged to the maximum extent.
Therefore, the brush can not only rotate, but also rotate horizontally around the axis of the encircling support because the cleaning mechanism can be driven by the ring gear to operate. In order to ensure that the brush can continuously rotate in a reciprocating manner around the axis of the encircling support, the ring gear can rotate in a reciprocating manner around the axis of the encircling support, therefore, the encircling rotating mechanism is also provided with a rotating control part for controlling the operation of the ring gear, the encircling rotating mechanism comprises two encircling limit position proximity switches and a stop iron, the stop iron is arranged at the central position of the top of the encircling support, and the two encircling limit position proximity switches are respectively arranged at the outer sides of the motor supports of the two cleaning mechanisms. When the ring gear rotates 90 degrees from the initial position (namely the ring gear is completely positioned in the encircling support, and the two cleaning mechanisms are respectively positioned at the two end parts of the encircling support), the encircling limit position proximity switch at the outer side of the motor support of the cleaning mechanism close to the central position of the encircling support senses the position of the iron block, and immediately sends an electric signal to the proportional directional valve encircling the hydraulic motor to change the direction of the proportional directional valve, so that the rotating gear turns to drive the ring gear to rotate reversely. After the ring gear rotates 180 degrees in the reverse direction, the other encircling limit position proximity switch sends an electric signal to the proportional direction valve encircling the hydraulic motor, the proportional direction valve is reversed again, the reciprocating circulation is carried out, the ring gear rotates around the axis of the encircling support in a reciprocating mode, and the brush can continuously rotate around the axis of the encircling support in a reciprocating mode. The brush can rotate and rotate around the axis of the surrounding bracket in a reciprocating way, and the aim of efficiently cleaning the post insulator can be achieved when cleaning operation is carried out.
It should be noted that, in this embodiment, the rotation control unit may also be implemented by using an optical fiber sensor and an optical fiber sensor baffle.
When the transformer substation post insulator cleaning device is used for cleaning transformer substation post insulators, the mounting base is fixed on the lifting platform, and the lifting platform conveys the cleaning device to a high position to be close to the post insulators. When the cleaning device is close to the post insulator, the post insulator is positioned between the brushes of the two cleaning mechanisms and contacts the two brushes, and at the moment, the axis of the post insulator is approximately superposed with the axis of the encircling support. Starting the lifting hydraulic motor, encircling the hydraulic motor and the rotating motor, so that the insulating slide rail forms a first transmission pair through the rack and the lifting gear, and the rotating motion of the lifting hydraulic motor is converted into the vertical linear motion of the brush along the surface of the support insulator; the rotary gear and the ring gear form a second transmission pair, and the rotary motion of the encircling hydraulic motor is converted into horizontal rotary motion of the brush around the axis of the post insulator; the rotating motor drives the brush to rotate. Therefore, the brush can efficiently clean the post insulator in all directions.
In order to ensure that the transformer substation post insulator live cleaning device keeps a sufficient safe distance with a live body during operation, the connecting bracket can be also provided with a position ultrasonic sensor for sensing the live body; and in order to keep the proper distance between the cleaning device of the post insulator of the transformer substation and the post insulator during operation, an infrared sensor used for sensing the position of the post insulator can be arranged on the encircling support.
Furthermore, the invention also discloses a control system of the live-line cleaning tool for the post insulator of the transformer substation, which is used for controlling the operation of the live-line cleaning device for the post insulator of the transformer substation, wherein the live-line cleaning device for the post insulator of the transformer substation is carried by a live-line operation robot to clean the post insulator of the transformer substation.
The control system comprises a control module, a signal transceiving module, a driving module and a protection module, wherein the control module is used for generating and outputting a control instruction; the signal transceiver module is used for transmitting the control instruction output by the control module to the drive module and transmitting the limit signal generated by the protection module to the control module; the driving module is used for driving the electrified cleaning tool to operate according to the control instruction; the protection module is used for monitoring the operation position of the electrified cleaning tool, generating a limit signal when the electrified cleaning tool operates to the limit position, and feeding the limit signal back to the control module.
In detail, the control module comprises a remote control terminal and a main controller, and the remote control terminal is in wireless communication connection (such as WIFI) with the main controller. When a remote control handle of the remote control terminal is operated or a key is pressed, the remote control terminal sends a control signal to the main controller, the main controller controls the live cleaning device of the post insulator of the transformer substation, and the control signal is a multi-way switching value signal or an analog value signal. The main controller also receives a limit signal from the protection module, wherein the limit signal is a switching value signal. When the main controller receives a control signal from the remote control terminal or a limit signal from the protection module, a control instruction is correspondingly output to the signal transceiver module. The control command is an analog quantity signal of 0-5V, and if the main controller receives a switching quantity signal of-127 output by the remote control terminal 10, the digital-to-analog conversion processing is carried out on the switching quantity signal so as to output the analog quantity signal of 0-5V.
The signal transceiving module receives a control instruction from the main controller and sends the control instruction to the driving module; and receiving the limiting signal from the protection module and sending the limiting signal to the main controller. The signal receiving and transmitting module comprises an analog quantity signal wireless receiving and transmitting module and a switching value signal wireless receiving and transmitting module.
The analog quantity signal wireless receiving and transmitting module is used for collecting and remotely transmitting analog quantity signals and comprises an analog quantity input module, an analog quantity wireless transmitting module, an analog quantity wireless receiving module and an analog quantity output module. The analog quantity wireless transmitting module is connected with the analog quantity wireless transmitting module, the analog quantity wireless receiving module is connected with the analog quantity output module, the analog quantity wireless transmitting module is in wireless communication connection with the analog quantity wireless receiving module, and the analog quantity wireless receiving module outputs '0-5V' analog quantity signals. When the analog input module receives a control instruction output by the main controller, the control instruction is output to the analog wireless transmitting module, is sent to the analog wireless receiving module by the analog wireless transmitting module, is output to the analog output module by the analog wireless receiving module, and is output to the driving module by the analog output module. Ether CAT communication is adopted between the analog quantity output module and the driving module.
The switching value signal wireless receiving and transmitting module is used for collecting and remotely transmitting switching value signals and comprises a switching value input module, a switching value wireless transmitting module, a switching value wireless receiving module and a switching value output module, wherein the switching value input module is connected with the switching value wireless transmitting module, the switching value wireless receiving module is connected with the switching value output module, and radio frequency communication is adopted between the switching value wireless transmitting module and the switching value wireless receiving module. When the switching value input module receives the limiting signal output by the protection module, the limiting signal is output to the switching value wireless transmitting module, is sent to the switching value wireless receiving module by the switching value wireless transmitting module, is output to the switching value output module by the switching value wireless receiving module, and is output to the main controller by the switching value output module.
The driving module is used for receiving the control instruction transmitted by the signal receiving and transmitting module and driving the charged cleaning tool to operate according to the control instruction or stopping the operation of the charged cleaning tool. The driving module comprises a servo valve and a hydraulic motor, wherein the servo valve receives a control instruction output by the analog quantity output module and controls the hydraulic motor to move according to the control instruction, so that the live cleaning tool is driven to clean the post insulator of the transformer substation.
The protection module comprises a photoelectric switch and a proximity switch and is used for monitoring the running position of the electrified cleaning tool so as to limit the electrified cleaning tool. When the charged cleaning tool moves to the limit position, the photoelectric switch and/or the proximity switch are triggered, and the photoelectric switch and/or the proximity switch output limit signals to the switching value input module.
If the photoelectric switch or the proximity switch outputs a high level of 5V to the switching value input module, the switching value input module outputs the high level to the switching value wireless transmitting module, the switching value wireless transmitting module is communicated with the switching value wireless receiving module, the switching value wireless receiving module synchronously outputs a relay signal, if a 12V signal is provided for the switching value wireless receiving module, the output of the switching value wireless receiving module is a high level of 12V, the switching value wireless transmitting module is connected with the switching value output module and outputs the signal to one channel, and when the photoelectric switch and/or the proximity switch correspondingly outputs the high level and the low level, the main controller correspondingly receives the high level and the low level.
In the invention, a vertical lifting mechanism, an encircling rotating mechanism and at least two cleaning mechanisms,
the operation of the vertical lifting mechanism and the surrounding rotating mechanism is driven by a hydraulic oil cylinder of the driving module; the photoelectric switch monitors the running position of the vertical lifting mechanism, when the vertical lifting mechanism moves to the limit position, the photoelectric switch is triggered, and the photoelectric switch outputs a limit signal (a first limit signal) to the switching value input module; the proximity switch monitors the running position of the encircling rotating mechanism, when the encircling rotating mechanism moves to the limit position, the proximity switch is triggered, and the proximity switch outputs a limit signal (a second limit signal) to the switching value input module.
The switching value signal wireless transceiving module transmits the first limit signal and/or the second limit signal to the main controller, the main controller correspondingly outputs a control instruction, and the servo valve of the driving module is controlled to control the hydraulic oil cylinder to move, so that the vertical lifting mechanism and the surrounding rotating mechanism are controlled to stop running, for example, the operation of the vertical lifting mechanism and the surrounding rotating mechanism is stopped, even if the live cleaning device continuously performs the cleaning operation of the support insulator or stops the operation of the live cleaning device.
The above is merely an example, and the arrangement of the protection module and the photoelectric switch and the proximity switch thereof is not limited thereto.
When the control system controls the live cleaning device for the post insulator of the transformer substation to operate, the remote control terminal is firstly operated, and a control signal is sent to the main controller through the remote control terminal. When the main controller receives the control signal, if the control signal is a switching value signal, the main controller firstly converts the switching value signal into an analog signal in a digital-analog mode, and outputs a control instruction as the analog signal to the analog signal wireless transceiving module; if the control signal is an analog quantity signal, a corresponding control instruction which is the analog quantity signal is output to the analog quantity signal wireless transceiving module. The control instruction is transmitted by the analog quantity signal wireless transceiving module and finally output to a servo valve of the driving module so as to start the hydraulic motor to work. Then, the hydraulic motor drives the live cleaning device to operate, and performs cleaning work on the post insulator of the substation.
During the operation of the electrified cleaning device, the photoelectric switch and the proximity switch monitor the operation position of the electrified cleaning tool. When the electrified cleaning tool moves to the limit position, the photoelectric switch and/or the proximity switch can be triggered to output a limit signal to the switching value input module, and the limit signal is transmitted and output to the main controller through the switching value signal wireless transceiver module. When the main controller receives the limiting signal, a corresponding control instruction is output, and the servo valve of the driving module is controlled to control the hydraulic oil cylinder to move, so that the electrified cleaning device is controlled to stop working. The control instruction is also an analog quantity signal and is transmitted to the driving module through the analog quantity signal wireless transceiving module.
Therefore, the control system can control the live cleaning device for the post insulator of the transformer substation.
When the device is specifically implemented, the main controller, the analog quantity input module, the analog quantity wireless transmitting module, the switching value wireless receiving module and the switching value output module are arranged on a moving vehicle body of the live working robot, and the driving module, the protection module, the analog quantity wireless receiving module, the analog quantity output module, the switching value input module and the switching value wireless transmitting module are arranged on a live cleaning tool borne by the live working robot.
The control system of the transformer substation post insulator live cleaning device can help an operator to remotely control and monitor the running mode and the state of a live cleaning tool, and improve the insulativity, stability and safety of robot operation.
The live cleaning tool for the post insulator of the transformer substation has the following advantages:
(1) the transformer substation post insulator can be cleaned in an encircling manner by the encircling rotating mechanism, the surface of the post insulator can be cleaned in the vertical direction by the vertical lifting mechanism, and the brush can rotate, so that the post insulator can be cleaned efficiently from multiple angles, and the cleaning effect is good and the insulation effect is good;
(2) adopt hydraulic drive ring gear, lifting gear operation, not only have characteristics such as power is powerful, the rotational speed is fast, clean the effect good, insulating effectual, furthest has reduced the probability that personnel got into the equipment district of transformer substation, can reach the purpose of control brush rotational speed through control terminal in addition, realized that operating personnel can accomplish and clean the work not getting into the equipment district, ensured operating personnel's safety, the intensity of labour that reduces improves and cleans efficiency and automation level.
(3) Can be by setting up in lift platform and clear up the post insulator automatically, so have advantages such as degree of mechanization height, degree of automation height, satisfy the requirement that transformer substation's post insulator cleaned the operation with electricity moreover, ensured operating personnel's safety.
(4) The transmission gear assembly for lifting is integrally moved to the rear of the rack, so that the functions of positioning in the front and rear direction and balancing the counter weight are achieved, and the condition that the cleaning executing mechanism integrally tilts forward is improved.
(5) The encircling transmission mechanism is positioned by a T-shaped groove on the basis of the original mechanism of the guide wheel, so that the head warping phenomenon of the encircling mechanism in the moving process is avoided.
(6) The diameter and the length of the brush component are designed, the condition that the bristles sag is effectively changed, and weight reduction treatment is performed on the middle nylon support of the brush component. Meanwhile, the length of the insulating lifting rack is reduced, and weight reduction treatment is performed on the metal connecting frame.
(7) In order to prevent the hydraulic motor from descending along the direction of the rack due to internal leakage, a worm gear and worm speed reducer is arranged at the output end of the hydraulic motor, and the cleaning executing mechanism can be stopped at any position of the insulated lifting rack by utilizing the self-locking function of the worm gear and worm speed reducer.
(8) The control system of the live cleaning system for the post insulators of the transformer substation can help an operator to remotely control and monitor the operation mode and state of the live cleaning tool, and improves the insulativity, stability and safety of robot operation.
The above description is only a preferred embodiment of the present invention and is not intended to limit the present invention, and various modifications and changes may be made by those skilled in the art. Any modification, equivalent replacement, or improvement made within the spirit and principle of the present invention should be included in the protection scope of the present invention.

Claims (10)

1. Live overhaul work robot of substation equipment, including the robot body, its characterized in that, the robot body includes: the device comprises a mobile chassis and an insulating lifting arm arranged on the mobile chassis, wherein the front end of the insulating lifting arm is connected with a small fly jib, the front end of the small fly jib is provided with a live working platform for placing a live working tool, and the small fly jib is connected with the live working tool through a quick connecting device;
the live-wire work tool includes: foreign matter cleaning tool, wire repair tool and insulator cleaning tool.
2. The substation equipment live overhaul work robot of claim 1, wherein the insulated lift arm comprises: the rotary platform, the main arm, the upper arm, the insulating telescopic arm and the small fly jib are connected in sequence; the device is characterized by further comprising an insulating lifting arm control system, wherein sensors for detecting the rotation angle and the position of the main arm and the upper arm are respectively arranged on the main arm and the upper arm; the insulated telescopic arms are respectively provided with a sensor for detecting the telescopic length and the position of the insulated telescopic arms; the small fly arms are respectively provided with sensors for detecting the rotation angle and the horizontal inclination angle of the small fly arms; the insulating lifting arm control system respectively controls the motion of the main arm, the upper arm, the insulating telescopic arm and the small fly jib according to the data acquired by the sensors, and realizes one-key restoration of the insulating lifting arm system and leveling of the small fly jib according to a set priority sequence;
or,
the main arm and the upper arm both comprise two sections of metal arms and an insulating arm arranged between the two sections of metal arms; and/or the small fly arm is of a hollow rod structure made of insulating materials;
or,
the small flying arm is connected with the insulating telescopic arm and is driven by the rotary swing oil cylinder and the pitching swing oil cylinder to realize relative rotary swing and pitching swing with the insulating telescopic arm;
or,
the front end of the small fly jib is provided with a live working platform, and the small fly jib realizes the leveling of the live working platform through a leveling swing oil cylinder; the live working platform is provided with a panoramic camera and a laser scanner respectively and is used for realizing image acquisition and distance measurement.
3. The substation equipment live overhaul work robot of claim 1, wherein the wire repair tool comprises a housing, a driving mechanism is arranged in the housing, the driving mechanism is respectively connected with the left clamping arm and the right clamping arm, and drives the left clamping arm and the right clamping arm to realize opening and closing movement; and a base for fixing the repairing piece is arranged between the left clamping arm and the right clamping arm and in the direction vertical to the movement direction of the clamping arms, and two ends of the base are respectively provided with a thread combining device.
4. The substation equipment live overhaul work robot of claim 3, wherein the drive mechanism comprises: a worm gear transmission mechanism and a driving motor;
the driving motor drives the worm shaft to rotate through the transmission gear, two sections of spiral teeth are arranged on the worm shaft, each section of spiral teeth is connected with a worm wheel, and the worm wheels are connected with the left clamping arm and the right clamping arm respectively; the worm shaft rotates to drive the worm wheel to rotate, so that the left and right clamping arms are driven to move.
5. The substation equipment live overhaul work robot of claim 3, wherein the wire repair tool further comprises a repair patch comprising:
the wire crimping region is connected with at least two crimping teeth on one side of the wire crimping region, a gap with a set distance is formed between every two crimping teeth, and the other side of the wire crimping region is connected with crimping teeth corresponding to the gap; the tail end of the crimping tooth is bent inwards to set a radian;
or,
openings are respectively formed in the front end and the rear end of the wire crimping area, and the size of each opening meets the requirement of transition fit with the trapezoidal pin shafts arranged at the two ends of the base;
or,
a through hole is formed in the center of the wire crimping area;
or,
the wire crimping area is an arc-shaped groove, and the bending radian of the arc-shaped groove and the inward-bending radian of the tail end of the crimping tooth are determined according to the diameter of the wire.
6. The substation equipment live overhaul work robot of claim 1, wherein the cleaning tool comprises: the cleaning device comprises a vertical lifting mechanism, an encircling rotating mechanism and a cleaning mechanism, wherein the encircling rotating mechanism is arranged on one side of the vertical lifting mechanism, and the cleaning mechanism is arranged at two ends of the encircling rotating mechanism and can respectively horizontally rotate along the annular axis of the encircling rotating mechanism; the encircling rotating mechanism comprises an encircling support and a ring gear; the encircling support is provided with an annular inner cavity, a guide groove is formed in an inner cavity bottom plate of the encircling support, and the annular gear is limited in the guide groove and moves along the guide groove.
7. The substation equipment live overhaul work robot of claim 6, wherein the surrounding rotation mechanism further comprises: the hydraulic motor and the rotating gear are encircled, and one side of the ring gear is exposed out through an opening arranged on one side surface of the encircling support so as to be matched with the rotating gear; the encircling hydraulic motor is used for driving the rotating gear to drive the ring gear to horizontally rotate around the axis of the encircling support in the inner cavity of the encircling support; the cleaning mechanisms are arranged on the top surface of the ring gear and are respectively positioned at two ends of the ring gear;
or,
the encircling rotating mechanism further comprises a rotating control part, the rotating control part comprises at least two encircling limit position proximity switches and stop irons, and the stop irons are respectively arranged on the cleaning mechanism; the surrounding limit position proximity switches are respectively arranged on the surrounding support and used for sending an electric signal to a proportional direction valve of the surrounding hydraulic motor when the position of the stop iron is sensed, so that the proportional direction valve is reversed, and the rotating gear is driven to rotate.
8. The substation equipment live overhaul work robot of claim 7, wherein a T-shaped guide groove is formed in a bottom plate of an inner cavity of the surrounding support, and a T-shaped sliding block matched with the T-shaped guide groove is arranged on a gear ring of the annular gear; the T-shaped sliding block moves in the T-shaped guide groove.
9. The substation equipment live overhaul work robot of claim 6, wherein the vertical lifting mechanism comprises an insulating slide rail, a connecting bracket, a lifting hydraulic motor and a lifting gear, wherein the connecting bracket is arranged on the insulating slide rail, and the lifting hydraulic motor and the lifting gear are arranged on the connecting bracket on the side opposite to the encircling rotation mechanism; the lifting hydraulic motor is connected with the lifting gear through a worm gear speed reducer, the lifting gear and the insulating slide rail form a transmission pair, and the lifting hydraulic motor is used for driving the lifting gear to move up and down along the insulating slide rail so as to drive the connecting support to move up and down along the insulating slide rail.
10. The substation equipment live overhaul work robot of claim 6, wherein the sweeping mechanism comprises: the cleaning device comprises a brush, a rotary motor and a cleaning motor support, wherein the cleaning motor support is fixed on the encircling rotary mechanism, the rotary motor is arranged on the cleaning motor support, and the brush is connected to a rotary shaft of the rotary motor and driven to rotate by the rotary motor.
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CN109732555A (en) * 2019-01-30 2019-05-10 华能汕头海门发电有限责任公司 A kind of robot system of robot arm end effector that playing leak stopping with twirl
CN110112666A (en) * 2019-05-27 2019-08-09 宜兴市宜安电力工具制造有限公司 Hotline maintenance robot moving trolley
CN110104572A (en) * 2019-05-27 2019-08-09 宜兴市宜安电力工具制造有限公司 Hotline maintenance robot rotary-top boom
CN110125063A (en) * 2019-05-21 2019-08-16 国网山东省电力公司经济技术研究院 A kind of transmission line of electricity clearing apparatus
CN111964717A (en) * 2020-08-07 2020-11-20 邢台职业技术学院 Environmental protection parameter quality detection system
CN112318482A (en) * 2020-11-03 2021-02-05 张梅 High-precision measuring machine arm
CN112657895A (en) * 2020-11-09 2021-04-16 国网山东省电力公司曲阜市供电公司 Live-line cleaning device for transformer substation insulator
CN112834516A (en) * 2020-12-31 2021-05-25 华东交通大学 Rail vehicle bottom detection robot and detection method thereof
CN112864920A (en) * 2021-03-05 2021-05-28 国网山东省电力公司潍坊供电公司 Disconnecting switch overhauling device
CN112859832A (en) * 2020-07-06 2021-05-28 丰疆智能(深圳)有限公司 Mobile robot with height-adjustable sensor and method for adjusting height of sensor
CN114589135A (en) * 2020-12-04 2022-06-07 国网山东省电力公司济南供电公司 Live-line radial feeding cleaning device, robot and method for transformer substation insulator
CN115122289A (en) * 2022-06-13 2022-09-30 国网天津市电力公司 Intelligent maintenance operation platform of 10kV switch

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CN109732555A (en) * 2019-01-30 2019-05-10 华能汕头海门发电有限责任公司 A kind of robot system of robot arm end effector that playing leak stopping with twirl
CN109732555B (en) * 2019-01-30 2023-09-26 华能汕头海门发电有限责任公司 Robot system with twisting and plugging mechanical arm end effector
CN110125063A (en) * 2019-05-21 2019-08-16 国网山东省电力公司经济技术研究院 A kind of transmission line of electricity clearing apparatus
CN110112666A (en) * 2019-05-27 2019-08-09 宜兴市宜安电力工具制造有限公司 Hotline maintenance robot moving trolley
CN110104572A (en) * 2019-05-27 2019-08-09 宜兴市宜安电力工具制造有限公司 Hotline maintenance robot rotary-top boom
CN110104572B (en) * 2019-05-27 2024-04-16 宜兴市宜安电力工具制造有限公司 Top rotary suspension arm of electrified overhaul robot
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CN111964717A (en) * 2020-08-07 2020-11-20 邢台职业技术学院 Environmental protection parameter quality detection system
CN112318482A (en) * 2020-11-03 2021-02-05 张梅 High-precision measuring machine arm
CN112657895A (en) * 2020-11-09 2021-04-16 国网山东省电力公司曲阜市供电公司 Live-line cleaning device for transformer substation insulator
CN114589135A (en) * 2020-12-04 2022-06-07 国网山东省电力公司济南供电公司 Live-line radial feeding cleaning device, robot and method for transformer substation insulator
CN112834516A (en) * 2020-12-31 2021-05-25 华东交通大学 Rail vehicle bottom detection robot and detection method thereof
CN112834516B (en) * 2020-12-31 2024-02-09 华东交通大学 Railway vehicle bottom detection robot and detection method thereof
CN112864920A (en) * 2021-03-05 2021-05-28 国网山东省电力公司潍坊供电公司 Disconnecting switch overhauling device
CN115122289A (en) * 2022-06-13 2022-09-30 国网天津市电力公司 Intelligent maintenance operation platform of 10kV switch

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