CN215874504U - High-altitude cleaning robot - Google Patents

Abstract

The utility model discloses a high-altitude cleaning robot, which comprises a chassis, four wheat wheel mechanisms, a cleaning mechanism, a rotor mechanism, a supply mechanism and a control mechanism, wherein the four wheat wheel mechanisms are arranged on the chassis; the four wheat wheel mechanisms are suspended and fixed on the chassis in a parallelogram shape, the cleaning structure comprises a mechanical arm, a disk brush, a water wiper and a spray head, the front end of the mechanical arm is connected with the spray head, and the rear end of the mechanical arm is connected with the water wiper; the rotor wing mechanism comprises foot frames, a protective frame, steering engines and rotatable fan blades, the plurality of fan blades are installed on the protective frame at equal intervals, and the steering engines are installed on the fan blades; the supply mechanism comprises a box body provided with a water tank and an electric box, a water delivery pipe for connecting the box body with the cleaning mechanism and a power transmission line for connecting the box body with the control mechanism; the control mechanism comprises a main control chip and at least one sensor connected with the main control chip, and the main control chip is arranged on the chassis and transmits power. The utility model has the advantages of high efficiency, safety, low cost, full-automatic wall surface cleaning, manpower liberation and the like.

Description

High-altitude cleaning robot

Technical Field

The utility model relates to the technical field of cleaning equipment, in particular to a high-altitude cleaning robot.

Background

With the continuous improvement of living standard of people, the height of buildings is higher and higher, and a plurality of problems such as cleaning work of outer glass of high-rise buildings also occur in the continuous construction of a plurality of high-rise buildings. The existing solution is still carried out by adopting a mode of manual overhead suspension operation, and the working mode has the defects of low working efficiency, high labor cost, great potential safety hazard and continuous news report overhead operation accidents. Therefore, some high-altitude cleaning robots replacing manual high-altitude operation appear in the market, for example, the prior patent with the publication number of CN207855629U, the disclosed cleaning robot has a simple structure and a simple working principle, but is not suitable for special and complex occasions; like the U.S. prior patent of USCN202408733U, the disclosed motor assembly is not ideal enough in design, is not concise enough in working, is easy to damage the service life, and is not high in cost performance; as the prior application of the utility model of CN108755631A, the structure is complex, the water area is clean, the application is not wide enough, the number of related sensors is large, the maintenance is inconvenient, and the economic cost is high; the prior patent of CN207734099U adopts a direct-push type wiping window, and the wiping cloth is easy to deform under pressure, so that the outer edge of the wiping cloth is seriously abraded, the outer edge of the wiping cloth cannot be wiped cleanly for a long time, the operation is inconvenient, and the efficiency is lower. The existing empty cleaning robot is integrally divided into a high-pressure cleaning machine and a wall cleaning vehicle, but the existing empty cleaning robot is heavy, technically difficult to break through, low in maneuverability, difficult to meet the requirement of high altitude, high in cost, incapable of meeting the requirement of the public and difficult to realize the universality of application.

SUMMERY OF THE UTILITY MODEL

The utility model aims to overcome the defects of the prior art and provide an efficient and safe high-altitude cleaning robot capable of replacing manual operation.

In order to achieve the above purpose, the solution of the utility model is:

a high-altitude cleaning robot comprises a chassis, four wheat wheel mechanisms, a cleaning mechanism, a rotor wing mechanism, a supply mechanism and a control mechanism;

the four wheat wheel mechanisms are suspended and fixed on the chassis in a parallelogram shape, the cleaning structure comprises a mechanical arm, a disk brush, a water wiper and a spray head, the mechanical arm is two bent arc hollow tubes which are connected in front and back, the joint of the two bent arcs of the mechanical arm is arranged on the chassis, the front end of the mechanical arm is connected with the spray head, and the rear end of the mechanical arm is connected with the water wiper; the rotor wing mechanism comprises a foot rest, a protective frame, a steering engine and rotatable fan blades, wherein the top end of the foot rest is connected with the protective frame, the bottom end of the foot rest is connected with the chassis, the fan blades are arranged on the protective frame at equal intervals, and the steering engine is arranged on each fan blade; the supply mechanism comprises a box body provided with a water tank and an electric box, a water delivery pipe for connecting the box body with the cleaning mechanism and a power transmission line for connecting the box body with the control mechanism; the control mechanism comprises a main control chip and at least one sensor connected with the main control chip, and the main control chip is arranged on the chassis and transmits power.

Furthermore, a check ring can be arranged at the front end of the chassis, two chassis shells which are symmetrically arranged are arranged on two sides of the chassis, and the mechanical arm is arranged between the two chassis shells.

Furthermore, each wheat wheel mechanism includes mecanum wheel, shaft coupling, bearing frame, motor, suspension arm and shock absorber, coupling joint mecanum wheel and bearing frame, the one end of shaft coupling is fixed on the wheel hub of mecanum wheel, and the other end is together fixed with the bearing frame, and the motor is installed on the shaft coupling, and the bearing frame is connected to the one end of suspension arm, and the other end is installed on the chassis shell, and the shock absorber is installed on the suspension arm that deviates from mecanum wheel one side.

Furthermore, a plurality of hollow holes are formed in the base plate; the rear end and the position near the middle of the periphery of each chassis shell form a bent arc, and two ends of the bent arc are used for connecting Mecanum wheels; the chassis is also provided with a connecting rod which protrudes out of the chassis and is used for connecting a mechanical arm of the cleaning mechanism, and the joint of two arcs of the mechanical arm is arranged on the connecting rod of the chassis and is positioned between the two chassis shells.

Furthermore, the two disc brushes are symmetrically arranged on two sides of the front end of the chassis and are respectively connected with a disc brush motor, and the disc brush motors are arranged between the chassis and the chassis shell; the front end arc of arm is equipped with a reset spring, and reset spring's one end is connected on the arm, and the other end is connected on the chassis.

Further, the foot rest of rotor mechanism is equipped with three at least, and the fender bracket is connected on the top of each foot rest, and the bottom of foot rest is connected on the chassis shell, and the one end that foot rest and fender bracket are connected forms first curved boom, and the one end that foot rest and chassis shell are connected forms the second curved boom, be equipped with the slotted hole in first curved boom and the second curved boom, the chassis shell corresponds the mounted position department of foot rest and is equipped with a spacing groove.

Further, the fender bracket comprises a central plate and a plurality of blade mounting brackets which are arranged corresponding to the number of the blades, wherein the blade mounting brackets are arranged on the periphery of the central plate at equal intervals and are connected with the central plate. The fan blades are at least three, and each fan blade is correspondingly arranged in a blade mounting frame.

Furthermore, each flabellum includes a swing arm, an installation pole, spliced pole, two at least blades and a dead lever, and the swing arm setting is on the blade mounting bracket, and swing arm and mounting bracket are connected to the installation pole, make the wobbling setting of pendulum rod on the mounting bracket, and the installation pole is the intersection setting with the dead lever, and the spliced pole setting is put the department at the central point of installation pole and dead lever, is provided with brushless motor in the spliced pole, the blade sets up in the bottom of erection column and connects brushless motor, the steering wheel setting is on the installation pole of flabellum.

Furthermore, the box of feed mechanism is the water and electricity integral type box, and the box periphery is equipped with the reel, winds on the reel and is equipped with the conveying pipeline, the power transmission line is binded in the conveying pipeline with the raceway, and the bottom of box is equipped with the barley wheel.

Further, control mechanism's main control chip and sensor are installed on the chassis, and through chassis shell shroud, control mechanism still including setting up at least a camera and a remote controller in the periphery on chassis, main control chip is connected to the camera, and remote controller and unlimited camera and main control chip are infinitely connected.

The high-altitude cleaning robot can perform cleaning operation on a non-horizontal wall surface, the robot main body has flexibility and free maneuverability through the Mecanum wheels of the wheat wheel mechanism, and the four wheat wheel mechanisms form a parallelogram suspension, so that the high-altitude cleaning robot has the advantages of strong shock absorption capability and stable motion; the lever principle of the mechanical arm skillful movement of the cleaning mechanism realizes the smooth switching between the working state and the non-working state; the rotor wing mechanism utilizes the movable fan blades to enable the rotor wing mechanism to provide stable wall-adhering force, so that the high-altitude operation is ensured; the supply mechanism adopts water and electricity integrated transmission and can be used as a safety rope to prevent high-altitude dangerous situations; the control mechanism is controlled by an STM32 chip, so that the price is low; various sensors are used for accurate operation. Wherein, the movable fan blades are separated from water and electricity, and the chip and each motor are plated with a layer of insulating glue, which can improve the safety of high-altitude operation. The high-altitude cleaning robot has the advantages of high efficiency, safety, low cost, full-automatic wall surface cleaning, manpower liberation and the like, is simple to process and easy to disassemble and assemble; can be suitable for cleaning walls of large shopping malls, office buildings and the like.

Drawings

Fig. 1 is a first perspective view of the present invention.

Fig. 2 is a second perspective view of the present invention.

Fig. 3 is a third perspective view of the present invention.

Fig. 4 is a schematic structural diagram of the chassis of the present invention.

FIG. 5 is a schematic view of the assembly of the chassis, the wheat wheel mechanism and the cleaning mechanism of the present invention.

Fig. 6 is a schematic structural view of a rotor mechanism of the present invention.

Fig. 7 is a schematic structural view of the stand of the present invention.

FIG. 8 is a schematic view of the feed mechanism of the present invention.

Detailed Description

In order to further explain the technical solution of the present invention, the present invention is explained in detail by the following specific examples.

In the description of the present invention, it is to be understood that the terms "center", "longitudinal", "lateral", "length", "width", "thickness", "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", "clockwise", "counterclockwise", etc., indicate orientations or positional relationships based on those shown in the drawings, and are used only for convenience in describing the present invention and simplifying the description, but do not indicate or imply that the device or element referred to must have a particular orientation, be constructed in a particular orientation, and be operated, and thus should not be construed as limiting the present invention. Further, in the description of the present invention, "a plurality" means two or more unless specifically defined otherwise.

In the present invention, unless otherwise expressly stated or limited, the terms "mounted," "connected," "secured," and the like are to be construed broadly and can, for example, be connected or detachably connected or integrated; can be mechanically or electrically connected; either directly or indirectly through intervening media, either internally or in any other relationship. The specific meanings of the above terms in the present invention can be understood by those skilled in the art according to specific situations.

As shown in fig. 1 to 4, the present invention discloses a high altitude cleaning robot, which comprises a chassis 10, four microphone mechanisms 20, a cleaning mechanism 30, a rotor mechanism 40, a feeding mechanism 50 and a control mechanism.

The front end of the chassis 10 can be provided with a retaining ring 11, the retaining ring 11 can prevent an interfering object from entering the chassis 10, two sides of the chassis 10 are provided with two chassis shells 12 which are stacked, the chassis shells 12 are locked on the chassis 10 through bolts, in order to reduce the weight of the chassis 10, the chassis 10 can be provided with a plurality of hollow holes 13, and the chassis 10 is further provided with a connecting rod 14 which protrudes out of the chassis 10 and is used for connecting a mechanical arm 31 of the cleaning mechanism 30. The chassis shells 12 are integrally designed in a skeleton type, a bent arc is formed at the rear end and the position close to the middle of the periphery of each chassis shell 12, two ends of the bent arc are used for connecting Mecanum wheels 21, and the design of the bent arc can reduce resistance and weight.

Four wheat wheel mechanisms 20 are the parallelogram structure and arrange, and each wheat wheel mechanism 20 includes mecanum wheel 21, shaft coupling 22, bearing frame 23, motor 24, suspension arm 25 and shock absorber, shaft coupling 22 connects mecanum wheel 21 and bearing frame 23, and the one end of shaft coupling 22 is fixed on mecanum wheel 21's wheel hub, and the other end is together fixed with bearing frame 23, and motor 24 installs on shaft coupling 22, and bearing frame 23 is connected to suspension arm 25's one end, and the other end is installed on chassis shell 12, and the shock absorber is installed on the suspension arm 25 who deviates from mecanum wheel 21 one side. The four wheat wheel mechanisms 20 form a parallelogram suspension and are connected with the Mecanum wheels 21 through the couplers 22, and when the high-altitude cleaning robot needs to cross a connection object between the glasses, the high-altitude cleaning robot can easily and stably cross obstacles through the self-suspended shock absorption capacity.

The cleaning structure 30 comprises two mechanical arms 31, two disc brushes 32, two wipers 33 and a spray head 34, wherein the mechanical arms 31 are two curved hollow tubes connected in the front and back direction, the two curved junctions of the mechanical arms 31 are arranged on the connecting rods 14 of the chassis 10, the mechanical arms 31 after the chassis 10 is installed are positioned between the two chassis shells 12, the spray head 34 is connected to the front ends of the mechanical arms 31, the wipers 33 are connected to the rear ends of the mechanical arms 31, the two disc brushes 32 are provided, the two disc brushes 32 are symmetrically installed on two sides of the front end of the chassis 10 and are connected with disc brush motors, and the disc brush motors are arranged between the chassis 10 and the chassis shells 12. The structure of the mechanical arm 31 is one of the design points of the utility model, and the streamline mechanical arm 31 can play a connecting role, reduce the air flight resistance and has the advantage of two sides. Preferably, a return spring 35 is disposed at the front end of the mechanical arm 31 in a curved arc (i.e., at the end connected to the nozzle 34), and one end of the return spring 35 is connected to the mechanical arm 31 and the other end is connected to the chassis 10.

As shown in fig. 6, the rotor wing mechanism 40 includes foot frames 41, a protection frame 42, a steering engine 43 and fan blades 44, and as shown in fig. 7, at least three foot frames 41 are provided, the top end of each foot frame 41 is connected with the protection frame 42, the bottom end of the foot frame 41 is connected to the chassis housing 12, a first bent arm 411 is formed at one end of the foot frame 41 connected with the protection frame 42, a second bent arm 412 is formed at one end of the foot frame 41 connected with the chassis housing 12, and in order to reduce weight and reduce weight, the foot frame is lightened to reduce air flight resistance, and a slot 413 is provided in the first bent arm 411 and the second bent arm 412; the first curved arm 411 and the second curved arm 412 are designed to facilitate the oscillating flight of the rotor mechanism 40 when the flight is fixed, so as to avoid the damage of the protection frame 42 caused by improper operation when the impact is large; a limiting groove 121 for the rotation of the foot rest 41 is arranged at the mounting position of the chassis shell 12 corresponding to the foot rest 41. The protective frame 42 includes a central plate 421 and a plurality of blade mounts 422 corresponding to the number of the blades 44, wherein the blade mounts 421 are disposed at equal intervals on the periphery of the central plate 421 and connected to the central plate 421. The fan blades 44 are at least three, each fan blade 44 is correspondingly installed in a blade installation frame 422, each fan blade 44 comprises a swing arm 441, an installation rod 442, a connection column 443, at least two blades 444 and a fixing rod 445, the swing arm 441 is arranged on the blade installation frame 421, the installation rod 442 is connected with the swing arm 441 and the installation frame 421, the swing arm 441 is arranged on the installation frame 421 in a swinging mode, the installation rod 442 and the fixing rod 445 are arranged in a crossed mode, the connection column 443 is arranged at the center position of the installation rod 442 and the fixing rod 445, a brushless motor is arranged in the connection column 443, and the blades 443 are arranged at the bottom of the installation column 443 and connected with the brushless motor. The steering engine 43 is arranged on a mounting rod 442 of the fan blade 44.

As shown in fig. 8, the supply mechanism 50 includes a water and electricity integrated box 51, a reel 52 disposed at the periphery of the box 51, a feed pipe disposed on the reel 52, and a barley wheel 54 (only shown in the figure) disposed at the bottom of the box 51, a high pressure washer is disposed in the box 51 to deliver the cleaning agent to the spray head 34 through a water pipe, and the feed pipe and the water pipe are bound in the feed pipe, so as to provide electric energy for the high altitude cleaning robot of the present invention, and allow the high altitude cleaning robot to continuously work for a long time. The barley wheel 54 on the box body 51 can keep the same vertical line with the box body 51, so that the conveying pipe can be used as a safety rope to prevent the high-altitude cleaning robot from falling when encountering high-altitude dangerous situations.

Control mechanism includes main control chip and connects main control chip's sensor, and control mechanism installs on chassis 10, and through chassis shell 12 shroud, in this embodiment, main control chip is the STM32 chip, the sensor includes but is not limited to gyroscope sensor, infrared sensor and camera. In order to facilitate secondary cleaning, the control mechanism can also comprise a remote controller infinitely connected with the main control chip.

The high-altitude cleaning robot mainly comprises a robot main body and a supply mechanism 50, wherein the robot main body is assembled on a chassis 10 by a wheat wheel mechanism 20, a cleaning mechanism 30, a rotor wing mechanism 40 and a control mechanism, and the supply mechanism 50 is used for supplying water and power to the robot. The four wheat wheel mechanisms 20 are suspended between the chassis 10 and the chassis shell 12 in a parallelogram manner, the stroke of the suspension mode of the parallelogram is large, the shock absorption capacity is strong, and the high-altitude cleaning robot main body can keep stable in motion through various potholes. Cleaning mechanism 30 couples together shower nozzle 34 and wiper 33 through arm 31, the shower nozzle is located the front end of robot main part, wiper 33 is located the rear end, shower nozzle 34 links to each other with the high pressure cleaner of feed mechanism 50, when shower nozzle 34 spouts the sanitizer, preceding dish brush 32 can beat the sanitizer fast evenly, when front end shower nozzle 34 work, because the blowout of high-pressure liquid, can be that arm 31 drives shower nozzle 34 up perk, because lever principle, rear end wiper 33 can extrude the wall simultaneously, play and scrape the water effect, reset spring 35 is in tensile state this moment, when shower nozzle 34 stops working, reset spring 35 resets, wiper 33 just is in unsettled state. The rotor wing mechanism 40 provides the wall adhesion force, so that the robot main body is tightly attached to the wall surface, when wind blows, the built-in gyroscope can automatically identify the wind power, the swing arm 441 angle of the fan blade 44 is adjusted to keep balance, and the movable fan blade 44 is utilized to enable the rotor wing mechanism 4 to provide stable wall adhesion force.

The calculation and analysis of the adherence force of the rotor wing mechanism 40 includes that after the total weight m of the assembled robot main body is measured (in the embodiment, the measured weight m of the robot main body is 2.86 kg), the gravity N of the robot main body is calculated according to the weight G = mg, and the calculated weight G is approximately equal to 28N; the maximum static friction force f = μ N (μ =1, N is the force provided by four brushless motors), so that f is larger than or equal to G, namely N is larger than or equal to G and approximately equal to 28N; the brushless motor of each rotor mechanism 40 need only provide a force of about 7N. Stress analysis by ANSYS: the external force applied to each brushless motor 20N is known from the stress cloud presented, and the brushless motors can completely provide the force required by the adherent motion of the robot body.

The working process of the high-altitude cleaning robot is as follows:

placing the supply mechanism 50 on the roof, and respectively connecting the power line and the water pipe of the material conveying pipe of the supply mechanism 50 with the power supply interface of the robot main body and the spray head 34;

the robot main body is attached to the wall surface, and the rotor wing mechanism 40 can automatically calculate the wind power required to be provided by the attachment according to the environment;

after the spray head 34 sprays the cleaning agent, the disc brushes 32 on the two sides of the mechanical arm 31 can quickly and uniformly beat the cleaning agent, the wiper 33 at the rear end scrapes the sewage and impurities on the wall surface downwards, and the robot body operates along a preset path;

because the robot main body is provided with the camera, in the wiping process, a worker can monitor whether the robot main body is cleaned in place through the camera, and when the worker finds out which place is not cleaned in place, the robot main body can be converted into a remote control mode to carry out secondary cleaning until the cleaning is finished.

The high-altitude cleaning robot can perform cleaning operation on a non-horizontal wall surface, the robot main body has flexibility and free maneuverability through the Mecanum wheels of the wheat wheel mechanism 10, and the four wheat wheel mechanisms form a parallelogram suspension, so that the high-altitude cleaning robot has the advantages of strong shock absorption capability and stable motion; the lever principle of the mechanical arm skillful movement of the cleaning mechanism realizes the smooth switching between the working state and the non-working state; the rotor wing mechanism utilizes the movable fan blades to enable the rotor wing mechanism to provide stable wall-adhering force, so that the high-altitude operation is ensured; the supply mechanism adopts water and electricity integrated transmission and can be used as a safety rope to prevent high-altitude dangerous situations; the control mechanism is controlled by an STM32 chip, so that the price is low; various sensors are used for accurate operation. Wherein, the movable fan blades are separated from water and electricity, and the chip and each motor are plated with a layer of insulating glue, which can improve the safety of high-altitude operation. The wall cleaning machine has the advantages of high efficiency, safety, low cost, full-automatic wall cleaning, manpower liberation and the like, is simple to process and easy to disassemble and assemble; can be suitable for cleaning walls of large shopping malls, office buildings and the like.

The above embodiments and drawings are not intended to limit the form and style of the present invention, and any suitable changes or modifications thereof by those skilled in the art should be considered as not departing from the scope of the present invention.

Claims (10)

1. A high altitude cleaning robot, comprising:

a chassis;

the four wheat wheel mechanisms are suspended and fixed on the chassis in a parallelogram shape;

the cleaning mechanism comprises a mechanical arm, a disc brush, a water wiper and a spray head, wherein the mechanical arm is two curved hollow tubes which are connected in a front-back manner, the joint of the two curved hollow tubes of the mechanical arm is arranged on the base plate, the front end of the mechanical arm is connected with the spray head, and the rear end of the mechanical arm is connected with the water wiper;

the rotary wing mechanism comprises a foot rest, a protective frame, a steering engine and rotatable fan blades, wherein the top end of the foot rest is connected with the protective frame, the bottom end of the foot rest is connected with a chassis, and the plurality of rotatable fan blades are arranged on the protective frame at equal intervals;

the supply mechanism comprises a box body provided with a water tank and an electric box, a water delivery pipe for connecting the box body with the cleaning mechanism, and a power transmission line for connecting the box body with the control mechanism; and

and the control mechanism comprises a main control chip and at least one sensor connected with the main control chip, and the main control chip is arranged on the chassis and transmits power.

2. A high altitude cleaning robot as claimed in claim 1 wherein: the front end of the chassis is provided with a check ring, two chassis shells are symmetrically arranged on two sides of the chassis, and the mechanical arm is arranged between the two chassis shells.

3. A high altitude cleaning robot as claimed in claim 2 wherein: each wheat wheel mechanism includes mecanum wheel, shaft coupling, bearing frame, motor, hangs arm and shock absorber, coupling joint mecanum wheel and bearing frame, the one end of shaft coupling is fixed on the wheel hub of mecanum wheel, and the other end is together fixed with the bearing frame, and the motor is installed on the shaft coupling, hangs the one end of arm and connects the bearing frame, and the other end is installed on the chassis shell, and the shock absorber is installed on deviating from the arm that hangs of mecanum wheel one side.

4. A high altitude cleaning robot as claimed in claim 3 wherein: a plurality of hollow holes are formed in the base plate; the rear end and the position near the middle of the periphery of each chassis shell form a bent arc, and two ends of the bent arc are used for connecting Mecanum wheels; the chassis is also provided with a connecting rod connected with a mechanical arm of the cleaning mechanism, and the joint of the two curved arcs of the mechanical arm is arranged on the connecting rod of the chassis and is positioned between the two chassis shells.

5. A high altitude cleaning robot as claimed in claim 2 wherein: the disc brush is provided with two disc brushes which are symmetrically arranged on two sides of the front end of the chassis and are respectively connected with a disc brush motor, the disc brush motors are arranged between the chassis and a chassis shell, a return spring is arranged on a front end bent arc of the mechanical arm, one end of the return spring is connected to the mechanical arm, and the other end of the return spring is connected to the chassis.

6. A high altitude cleaning robot as claimed in claim 2 wherein: the foot rest of rotor mechanism is equipped with threely at least, and the fender bracket is connected on the top of each foot rest, and the bottom of foot rest is connected on the chassis shell, and the one end that foot rest and fender bracket are connected forms first curved boom, and the one end that foot rest and chassis shell are connected forms the second curved boom, be equipped with the slotted hole in first curved boom and the second curved boom, the mounted position department that the chassis shell corresponds the foot rest is equipped with a spacing groove.

7. A high altitude cleaning robot as claimed in claim 2 wherein: the fender bracket includes central panel and corresponds a plurality of blade mounting bracket that flabellum quantity set up, and a plurality of blade mounting bracket equidistant interval sets up in the periphery of central panel and connect central panel, the flabellum has three at least, and each flabellum corresponds and installs in a blade mounting bracket.

8. A high altitude cleaning robot as claimed in claim 7 wherein: each flabellum includes a swing arm, an installation pole, spliced pole, two at least blades and a dead lever, and the swing arm setting is on the blade mounting bracket, and swing arm and mounting bracket are connected to the installation pole, make the wobbling setting of pendulum rod on the mounting bracket, and the installation pole is the setting of crossing with the dead lever, and the spliced pole setting is provided with brushless motor in the spliced pole in the central point department of putting of installation pole and dead lever, the blade setting is in the bottom of erection column and is connected brushless motor, the steering wheel sets up on the installation pole of flabellum.

9. A high altitude cleaning robot as claimed in claim 1 wherein: the box of feed mechanism is the water and electricity integral type box, and the box periphery is equipped with the reel, winds on the reel and is equipped with the conveying pipeline, the power transmission line is binded in the conveying pipeline with the raceway, and the bottom of box is equipped with the barley wheel.

10. A high altitude cleaning robot as claimed in claim 2 wherein: the control mechanism's main control chip and sensor are installed on the chassis, and through chassis shell shroud, and control mechanism still includes an at least camera and a remote controller of setting in the periphery on chassis, and main control chip is connected to the camera, and remote controller and unlimited camera and main control chip are infinitely connected.

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