KR20160142571A - Large scale- solar cell cleaning robot tracking on rail of solar cell - Google Patents

Abstract

The present invention relates to a robot for cleaning a solar cell with a large capacity, which moves on a rail of a solar panel. The robot for cleaning a solar cell with a large capacity, which moves on a rail of a solar panel according to an embodiment of the present invention easily cleans dust or foreign materials on the solar panel. The robot for cleaning a solar cell with a large capacity according to the present invention includes a roller for movement and a roller for rotation. Rails are mounted on both ends of the solar panel to correspond to the roller for movement. A brush roller is installed on the outer side of a case. A brush is mounted in an inner space of the case and is connected to a rotation shaft of the brush roller.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a solar cell cleaning robot,

The present invention is characterized in that a rail is mounted on both ends of a solar panel of a large capacity and forward movement is performed by the rotation of the movable roller corresponding to the rail and at the same time the cleaning brush is operated to remove dust and foreign substances The present invention relates to a large capacity cleaning robot which is easy to clean.

   In recent years, there has been a great deal of global environmental problems such as the generation of carbon dioxide resulting from the use of fossil fuels, the global warming caused by the use of fossil fuels, and the difficulty of treating nuclear waste in nuclear power plants. ought.

   Among the energy using natural power, solar power generation using solar cell is a technology to convert sunlight directly into electric energy, and when photoelectric conversion element receives sunlight, it converts light energy into electric energy by photoelectric effect.

   Photovoltaic power generation consists of a solar cell panel including a photoelectric conversion element, a battery, and a power conversion inverter.

   In this solar power generation system, various devices are being developed to increase the power generation efficiency by installing a solar tracking device for tracking the sunlight movement according to the change of the sunshine according to the season and the sun from the morning to the evening.

   However, in the photovoltaic power generation, dust, foreign matter, snow, and rainwater accumulating on the surface of the solar battery panel cause a problem of reducing the power production efficiency of the photovoltaic power generation system. Accordingly, although various types of solar panel cleaning apparatuses have been developed, most of the apparatuses are large and complicated, which makes installation difficult and maintenance difficult in case of failure.

   In recent years, solar cell production in the world has been rapidly increasing. In Japan, Germany, and the US, solar photovoltaic technology has already become a single industry. Many companies are participating in solar cell and related fields.

   In Korea, according to the government's technology development and supply support policy, the number of companies that have entered or are interested in the field of photovoltaic is gradually increasing. However, we are investing heavily in the production and development of solar cells, but the maintenance and management are weak.

   Renewable energy is attracting attention as a solution to high oil prices and environmental pollution. Solar power accounts for a large share of renewable energy. There are various factors such as environmental factors and management factors in the solar power generation, but the management of the photovoltaic power generation system is emphasized. Especially, there are problems in management due to various installation locations.

    For example, sand and dust in the Sahara Desert are trying to solve the problem of efficiency reduction. The solar cell module cleaning technology is absolutely necessary because China, which has a large market, is also a region where yellow dust is severe.

   The solar cell module is made of tempered glass to protect the internal solar cell from external factors in the front part. The efficiency of the solar cell is reduced by 10% due to contaminants such as dust, dust, and dust in the tempered glass part.

   To solve the problem of efficiency deterioration due to contamination of solar cell module, some solar power plants are equipped with fixed sprinklers and sprinkled water, or a portable sprinkler is installed in the solar cell fixing frame to remove dust and yellow dust, In fact. This method uses water, so water must always be secured.

   The method using water can manage the module on the ground, but it is difficult to apply it to the solar cell module on the building roof or the outer wall of the building.

   In order to solve these drawbacks, a robotic vacuum cleaner is required. In particular, it is necessary to develop a solar cell module cleaning robot using an adsorption technology with an adsorption device usable for a solar cell module.

   At present, the small-scale solar cell system does not clean specifically, it is naturally cleaned by rainwater, and some of large-scale photovoltaic system is cleaned by sprinkler. Therefore, most common photovoltaic systems are not properly cleaned. At present, there is a problem that the efficiency of the solar cell module is reduced by about 10% due to various pollutants such as dust, sandstorm, and pollen.

   In addition, since the area of the solar panel is generally very large, there is a problem that an excessive time and cost are incurred to clean the entire area with one cleaning robot.

Korea Patent No. 10-1348197 Korea Patent No. 10-1272474 Korea Patent No. 10-1034192

 SUMMARY OF THE INVENTION Accordingly, it is an object of the present invention to provide a large-capacity solar cell cleaning robot for moving a solar panel rail of a large capacity, and more particularly, And a cleaning brush integrally formed with the transfer roller and a cleaning brush connected to the transfer roller are simultaneously rotated to scrape the dust on the upper surface of the solar panel, Capacity solar cell cleaning robots that interconnect solar cell cleaning robots that are removed to the outside through a suction pipe installed in the interior of a large number of solar panels with a large number of vertical lengths and clean large capacity solar panels in a short time, .

   SUMMARY OF THE INVENTION The present invention is directed to a cleaning robot for cleaning a large-capacity solar cell that moves a solar panel rail, comprising: a cleaning robot having a plurality of cases each having an upper portion closed and an upper portion opened; A moving roller and a rotating roller, which are connected to a motor mounted on one side of an inner space of the case located at both ends of the robot, for rotating the outer side of the case, And rails are attached to both ends of the cell plate so as to correspond to the moving rollers so that the robot is moved along the rails of the cell plate; A brush roller is installed on an outer side surface of the case at both ends so as to be belt-connected to be rotated together with the rotation roller;

A brush is mounted on an inner space of each of the cases, and a guide roller is installed on the rotation shaft of the brush roller so as to be attached to the lower end edge of the case at both ends, The upper surface of the connection block is formed with an upper connection hole so that the respective cases are in contact with each other so that a necessary number of cases are connected to each other in a plurality of cases and a connection hole is formed in the connection block to seat the connection coupling, To be interconnected by the connecting bolts of the connecting joints; And to provide a robot for cleaning a large-capacity solar cell that moves a solar panel rail.

  The large-capacity solar cell cleaning robot according to the present invention can clean the solar cell even during the day including the night along the rail attached to both ends of the solar panel with a large area, so that the solar cell of the daytime can be used without interruption, Since the cleaning robot for cleaning is separated from the cleaning robot, the installation can be simplified and the maintenance can be facilitated in the event of a failure.

   This is one cleaning robot that efficiently cleans a large-sized panel in a short period of time, thereby providing a robot with extremely low cost and time.

   In addition, the present invention provides a cleaning robot in which a simple structure is formed so that movement and brush cleaning are simultaneously performed by a single motor operation, simplifying parts and assembling and disassembling thereof are simplified, will be.

    Furthermore, a plurality of brush-mounted cases are connected to correspond to the required area of the required battery plate, thereby effectively cleaning the large-sized battery plate.

    This is because the size and the capacity of the cleaning robot can be easily changed by using a simple connecting structure and the advantage of effective operation and application in the field is included.

   In addition, the cleaning efficiency of the solar cell panel can be maximized by the combined cleaning of the cleaning liquid injection, wiping operation and pneumatic injection.

BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 is a schematic view showing a front surface of a cleaning robot constituting a first embodiment of a large-capacity solar cell cleaning robot according to the present invention; Fig.
BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a cleaning robot for cleaning solar cells of a large capacity.
Fig. 3 is a schematic view showing an operating state in which the solar cell cleaning robot according to the first embodiment of the present invention moves the rails of the solar panel
FIG. 4 is a schematic view showing a detailed state in which a movable roller of a solar cell cleaning robot according to the first embodiment of the present invention is mounted on a rail. FIG.
5 is a schematic view showing an operating state in which a robot for cleaning large-capacity solar cells according to the present invention moves a rail of a solar panel.
6 is a schematic view showing a robot in which robots for cleaning large-capacity solar cells of the present invention are interconnected.
7 is a schematic view showing a plane of a robot interconnected with a robot for cleaning large-capacity solar cells of the present invention.
Fig. 8 is a schematic view showing interconnecting parts of brushes constituting a large-capacity solar cell cleaning robot according to the present invention; Fig.
FIG. 9A is a schematic view showing a connecting rod of each cleaning robot constituting a large-capacity solar cell cleaning robot of the present invention; FIG.
FIG. 9B is a schematic view showing a plane of a connecting rod of each cleaning robot constituting a large capacity solar cell cleaning robot of the present invention; FIG.
Fig. 9c is a schematic view showing a cross section of a connecting rod of each cleaning robot constituting a large capacity solar cell cleaning robot of the present invention; Fig.
10 is a schematic view showing a state in which each cleaning brush for connecting a large-capacity solar cell cleaning robot according to the present invention is connected to a connecting rod.
11 is a schematic view showing a large-capacity solar cell cleaning robot according to the present invention and a brush mounted thereon.

The features and advantages of the present invention will become more apparent from the following detailed description of the present invention when taken in conjunction with the accompanying drawings.

In the following, FIG. 1 to FIG. 11 are schematic views showing the respective detailed states of the present invention.

    In detail, as a first embodiment of the present invention,

 As shown in Figs. 1 to 4,

   In order to clean a solar panel of relatively small size, a solar cell cleaning robot 100 comprising one case 160 as an embodiment of the present invention is as follows.

   The cleaning robot 100 is provided with a case 160 having an upper portion closed and an upper portion opened to form an inner space so that the following devices are connected to each other in the inner space, The foreign matter, the sticking material, and the like are washed and removed.

   First, a motor 40 is attached to one side of a case 160 in an inner space of the robot 100. One or two such motors may be installed at the center portion, and may be optionally installed. And is shown as a schematic view with two motors attached.

  A moving roller 50 and a rotating roller 10 which are connected to the rotating shaft of the motor 40 and rotate on both sides of the outer side of the robot 100 are formed respectively and the moving roller 50 and the rotating roller 10 Are mounted on the rotating shaft of the same motor 40 and are rotated together.

   The rail 201 is mounted on both ends of the solar panel 200 so as to correspond to the rotation track of the roller 50 and the forward movement of the roller 50, As shown in FIG.

   The brush roller 20 is installed on the outer side of the robot 100 so as to be belt-connected to be rotated together with the roller 20.

  A brush 70 is attached to the inner space of the robot 100 and is closely contacted with the battery panel 200 to scrape off dust and foreign matter.

  The brush 70 is in close contact with the battery panel 200 and is rotated to remove dust and foreign matter.

   The present invention advances the robot to a rail separately mounted on an electric panel as one motor, simultaneously operates a cleaning device, and operates a cleaning function.

   Further, the guide roller 60 is mounted on the lower edge of the robot 100 so that the guide roller 60 is rotated in close contact with the lower end surface of the battery panel 200 when it is moved.

   In the figure, four guide rollers 60 are mounted so as to rotate at the four corners of the robot 100 body.

   This allows the robot 100 to move forward on the rail and to prevent the wind from being blown off or unexpected shaking off the battery board 200 and falling down, The robot 100 is brought into contact with the lower end surface of the battery 200 opposite to the washing surface of the battery 200 and manually rotated so that the body of the robot 100 is not separated from the battery 200 and can be linearly moved.

   The brush 100 is closely attached to the battery panel 200 and rotates to remove dust and foreign substances and the robot 100 is moved to the outside to transfer the dust and the like removed from the battery panel 200 to the outside. And the suctioned dust and the like are sucked into the suction pump 90 and cleaned by the suction force generated by the suction force generated by the suction force generated by the suction force of the suction force Dust and the like are not generated.

  As a second embodiment of the present invention, in order to clean a large-area solar panel, if the length of the case 160 of the first embodiment is increased and the length of the brush 70 connected thereto is increased, Bending may occur and the brush may not rotate smoothly, which may result in deterioration of cleaning efficiency.

   5 to 11, as the second embodiment of the present invention, in recent years, the area of the solar cell plate is gradually increasing. Therefore, in the first embodiment, It is an object of the present invention to effectively provide a large-area cleaning of the panel by adding a configuration that can easily increase or decrease the size of the robot in proportion to an increase in the area.

   According to the present invention,

    A large-capacity solar cell cleaning robot for moving a solar panel rail,

    A cleaning robot (300) comprising a plurality of cases (160) having an upper portion closed and an upper portion opened and an inner space formed;

   A moving roller 50 rotatably connected to a motor 40 mounted on one side of an inner space of the case 160 at both ends of the robot 300 and rotating on the outer side of the case 160, Rollers 10 are respectively formed;

   A rail 201 is mounted on both ends of the battery panel 200 so as to correspond to the moving roller 50 so that the robot 300 is moved along the rails 201 of the battery panel 200;

   A brush roller 20 is installed on an outer side surface of the case 160 at both ends so as to be belt-connected to be rotated together with the rotation roller 10;

   A brush 70 is attached to the inner space of each case 160 and connected to the rotating shaft of the brush roller 20 so as to closely contact the blade 200 to scrape off dust and foreign matter;

   The guide rollers 60 are mounted on the bottom edge of the case 160 at both ends and are installed so as to be closely contacted with the lower end surface of the battery panel 200 during the movement,

    An upper connection hole 153 is formed in the upper surface of the connection block 150 so that the respective cases 160 are in contact with each other so that a necessary number of cases 160 are connected to each other. So that the bristles 154 are connected to each other by the connection bolts 171 of the connection fastening part 170 so that the connection fastening part 170 is seated therebetween. The present invention relates to a large-capacity solar cell cleaning robot for moving a solar panel rail.

  This will be described in detail as follows.

   The present invention

   The cleaning robot 300 is provided with a plurality of cases 160 having an upper portion closed and an lower portion opened to form an inner space in order to clean a large-capacity battery panel in a short time.

  The upper surface of the connecting rod 150 is formed with an upper connecting hole 153 and the case 160 is brought into contact with each other, And the two cases 160 are connected to each other through a hole 161 by a fastening means such as a normal bolt. And the necessary number of cases 160 corresponding to the capacity of the area of the battery panel are connected by a plurality of connecting rods 150 so that the size of the robot is easily changed according to the cleaning area.

   Describing the connection mechanism in detail,

    A connection hole 154 is formed in the connection block 150 and a connection coupling part 170 is seated in the connection hole 154 and the connection coupling part 170 is connected to each of the brush connection parts 71, And the connecting bolts 171 are fastened so that the two brushes 70 are interconnected.

   In order to smoothly rotate the brush 70, a normal bearing is mounted inside the connection hole 154 at the outer periphery of the connection coupling part 170 so that smooth rotation is possible even when a plurality of brushes 70 are connected will be.

     The plurality of cases 160 are connected to each other by the connecting rod 150 and the brushes 70 are connected to each other.

   A robot 300 having a plurality of cases 160 as described above is provided and the motor 40 is mounted on one side of the inner space of the case 160 located at both ends of the plurality of cases 160, A moving roller 50 and a rotating roller 10 which are connected to the motor 40 so as to rotate on the outer side of the case 160 are formed.

  This is the same as the configuration of the robot 100 of the first embodiment.

    Further, a suction pipe 91 is provided on the outer upper surface of the robot 300 having the plurality of cases, so that dust or foreign matter scraped from the inner space is vacuum-sucked to the outside;

   A cleaning pipe 81 is installed on an outer upper surface of the robot 300 to spray and fix the fixture secured to the panel 200 through the nozzle 82 with high pressure liquid or vapor;

  .

    Although there are foreign substances such as dust and the like easily removed by the operation of the brush 70, the panel plate 200 is adhered to the fixture such as the excrement of birds or a lump gathered with dust and the like, A cleaning pipe 81 is provided on the outer upper surface of the robot 100 to fix the fixture secured to the battery panel 200 through the nozzle 82, It is sprayed with high-pressure liquid or vapor and is desorbed.

  The washing pipe 81 receives hot water or steam from the washing tank 80 and is sprayed through a nozzle 82 formed in the washing pipe 81. The sprayed liquid is sprayed to the battery panel 200 at a constant pressure And to remove the fixture.

10: Roller for rotation 20: Brush roller
30: Belt 40: Motor
50: movable roller 60: guide roller
70: Brush 80: Cleaning tank
81: Cleaning pipe 82: Nozzle
90: Suction pump 91: Suction pipe
100, 300: Cleaning robot
150: connecting rod 153: upper connecting hole
154: Connection hole
160: Case 170:
171: Connecting bolts
200: Solar panel 201: Rail

Claims (1)

A large-capacity solar cell cleaning robot for moving a solar panel rail,
A cleaning robot (300) comprising a plurality of cases (160) having an upper portion closed and an upper portion opened and an inner space formed;
A moving roller 50 rotatably connected to a motor 40 mounted on one side of an inner space of the case 160 at both ends of the robot 300 and rotating on the outer side of the case 160, Rollers 10 are respectively formed;
A rail 201 is mounted on both ends of the battery panel 200 so as to correspond to the moving roller 50 so that the robot 300 is moved along the rails 201 of the battery panel 200;
A brush roller 20 is installed on an outer side surface of the case 160 at both ends so as to be belt-connected to be rotated together with the rotation roller 10;
A brush 70 is attached to the inner space of each case 160 and connected to the rotating shaft of the brush roller 20 so as to closely contact the blade 200 to scrape off dust and foreign matter;
The guide rollers 60 are mounted on the bottom edge of the case 160 at both ends and are installed so as to be closely contacted with the lower end surface of the battery panel 200 during the movement,
An upper connection hole 153 is formed in the upper surface of the connection block 150 so that the respective cases 160 are in contact with each other so that a necessary number of cases 160 are connected to each other. So that the bristles 154 are connected to each other by the connection bolts 171 of the connection fastening part 170 so that the connection fastening part 170 is seated therebetween.
Wherein the solar panel rails are movable in a vertical direction.
Claim 2
The method according to claim 1,
A suction pipe (91) is provided on an outer upper surface of the robot (300) having the plurality of cases, so that dust or foreign matter scraped in the internal space is vacuum-sucked to the outside;
A cleaning pipe 81 is installed on an outer upper surface of the robot 300 to spray and fix the fixture secured to the panel 200 through the nozzle 82 with high pressure liquid or vapor;
Wherein the solar panel rails are moved in a vertical direction.

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