KR20180032024A - Contamination detection auto cleaning robot using air-motor - Google Patents

Abstract

The present invention relates to an automatically cleaning robot for detecting contamination using an air motor. More specifically, the present invention relates to an automatically cleaning robot for detecting contamination using an air motor which floats above a surface of a solar cell panel by a predetermined height while moving along the solar cell panel, thereby minimizing a contact with the solar cell panel and cleaning contaminants. The automatically cleaning robot for detecting contamination using an air motor comprises: a movable frame; a moving body part; a contamination inspection part; a detection sensor part; and a cleaning part.

Description

[0001] The present invention relates to an automatic cleaning robot,

The present invention relates to an automatic cleaning robot for detecting contamination using an air motor, and more particularly, to an automatic cleaning robot for cleaning contamination by minimizing contact with a solar cell panel and flooding a predetermined height above a surface of the solar panel while moving along the solar panel. The present invention relates to an automatic cleaning robot for detecting contamination using an air motor.

Generally, the method of using solar energy is divided into a method using solar heat and a method using solar battery. The method of using solar heat is heating and power generation by using water heated by the sun, and the method of using a solar cell is to generate electricity by using sunlight and to operate various machines or apparatus by the generated electricity , And the latter is commonly referred to as solar cell power generation.

Among the methods using solar energy, solar power generation generates electricity using a photovoltaic effect. The photovoltaic effect is a phenomenon in which a pn junction is performed by n-type doping on a silicon crystal When a solar cell is irradiated on a battery cell plate, an electromotive force due to the electron-hole is generated by the light energy.

For this purpose, a solar cell for collecting solar cells, a photovoltaic module for collecting solar cells, and a solar array for uniformly arranging solar cells are required.

For example, when light is incident on the solar cell module from the outside, electrons in the conduction band of the p-type semiconductor are excited into the valance band by the incident light energy, One electron-hole pair (EHP) is formed in the p-type semiconductor. The electrons in the electron-hole pair are generated by an electron field existing between the p- And the current is supplied to the outside.

On the other hand, unlike existing energy sources such as fossil raw materials, solar cell power generation is a clean energy source that does not have any danger of global warming such as greenhouse gas emission, noise and environmental destruction, and there is no fear of depletion. In addition, unlike other wind and seawater powers, solar power generation facilities have the advantages of being free to install and low maintenance cost.

However, such a solar cell module has disadvantages that dust can be easily accumulated on the solar panel due to weather phenomenon such as yellow dust and bad weather. If dirt accumulates on the solar cell module, the solar cell module may significantly lower the light absorption rate, and consequently the power generation efficiency may deteriorate.

In addition, when rain or snow falls on the solar panel in winter, the power generation efficiency may decrease. It is necessary to periodically clean the solar cell module in order to prevent deterioration of power generation efficiency due to such dirt, snow, and rain.

However, cleaning a large number of large-area solar cell modules requires a lot of time and manpower. Therefore, it is a reality that it is desired to develop a device capable of cleaning solar cell modules with a minimum of manpower in a short time.

Meanwhile, global solar cell production has been rapidly increasing in recent years. As a result, solar cell technology has already become an industry in Japan, Germany, and the United States, and many companies are participating in related fields such as solar cell, which is a key technology. In Korea, according to the government's technology development and supply support policy, the number of companies that are gradually expanding into the solar cell field or wishing to enter the market is increasing. However, they are investing heavily in the production and development of solar cells, but their maintenance and management are weak.

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

17 European companies have invested 400 billion euros (about 620 trillion won) in the Sahara Desert until 2025 to build a solar power plant with a capacity of 25 GW and start the Desertec Project, which produces 15% of the total electricity demand in Europe . As a result of this project, we are trying to solve the problem of efficiency reduction due to sand and dust in the Sahara Desert. In China, where the market is big, solar panel (module) cleaning technology is also necessary because yellow sand is a serious area.

In order to solve the cleaning problem of the solar panel (module), a robot apparatus for cleaning a solar panel is proposed in Japanese Patent Application No. 10-1034192 and shown in Fig.

The robot apparatus for cleaning a solar panel proposed in the patent is a cleaning robot apparatus for cleaning the solar panel in a solar cell array having a plurality of solar panels arranged thereon, A pair of conveyors each having a conveying carriage reciprocating along each of the corners; A cleaning liquid spraying unit having a pair of conveyance units coupled to both ends thereof and having a transfer tube for transferring the cleaning liquid and a cleaning liquid spray nozzle for spraying the cleaning liquid of the transfer tube; And a cleaning robot which is transported by the transporting car and moves between the pair of transporting cars to clean the solar cell panel, the cleaning robot comprising: a body; A driving unit mounted on the body and having a motor for driving the moving wheels; An air pressure forming part having an impeller rotated by the motor and discharging air at the time of rotation; An air injection unit having a first pipe for transferring the air discharged from the impeller and an air injection nozzle for spraying the air of the first pipe to the solar cell panel; And a wiper which is coupled to the body and selectively closes the solar panel to remove the cleaning liquid, wherein a guide groove is formed concavely between the plurality of solar panels, and when the cleaning robot moves And the moving wheel is inserted into the guide groove and guided.

However, in the cleaning robot apparatus and the related art disclosed in the above patent, there are many parts in which the solar panel and the robot apparatus can be physically contacted, so that a scratch may occur during cleaning of the solar panel or a foreign substance may be present between the solar panel and the robot apparatus There was a problem such as being caught in the gap.

Accordingly, development of a solar panel cleaning robot capable of efficiently cleaning a wide range of installed solar panels (modules) while minimizing physical contact has been urgently required.

Korean Patent No. 10-1034192, entitled " Robot Device for Cleaning Solar Panels " (Registered on May 23, 2011). Korean Patent No. 10-0888395, entitled " Surface Cleaning System for Solar Panels " (Registered on Mar. 5, 2009).

Disclosure of the Invention The present invention has been made in view of the above-mentioned problems and needs, and it is an object of the present invention to provide a solar cell module, a solar cell module, The object of the present invention is to provide an automatic cleaning robot for detecting contamination.

According to an aspect of the present invention, there is provided a robot for detecting contamination using an air motor, the robot including a pair of guide rails disposed parallel to one side and the other side of the solar cell panel, A movable body part reciprocating by an air motor along the guide rail; a movable body part mounted on one side of the movable body part for measuring contamination degree of the surface of the solar cell panel; And a cleaning unit installed on one side of the moving body to clean contaminants on the surface of the solar cell panel.

The moving body includes a plurality of air inlet pipes formed at a predetermined spacing in the transverse direction of the traveling direction of the moving body portion and arranged above the moving body portion to allow air to flow therein, And a plurality of air injection tubes for spraying the air introduced by the air motor onto the surface of the solar cell panel in the lower part of the moving body part.

According to the automatic cleaning robot for detecting contamination using the air motor proposed in the present invention, the moving body can be moved up to a predetermined height by using an air motor, and can be moved and cleaned.

In addition, since the movable body is floated so as to be spaced apart by a predetermined height, physical contact with the solar cell panel is minimized, thereby reducing the damage of the solar cell panel.

In addition, there is an advantage in that dust and contaminants are removed by using the flow of air due to air rising of the cleaning robot.

1 is an exemplary diagram showing a cleaning apparatus for a conventional solar cell panel.
2 is a block diagram showing the configuration of a cleaning robot apparatus according to an embodiment of the present invention.
3 is a schematic perspective view illustrating a configuration of a cleaning robot apparatus according to an embodiment of the present invention.
4 is a perspective view showing a state after a cleaning robot is seated on a solar cell panel in the structure of a cleaning robot apparatus according to an embodiment of the present invention.
5 is a view showing a cleaning robot of the cleaning robot apparatus according to an embodiment of the present invention.
6 is an explanatory view of the operation of the pollution inspection unit according to an embodiment of the present invention.
7 is a block diagram of a remote control system for a cleaning robot apparatus according to an embodiment of the present invention.
8 is a view showing an example of a first cleaning area map according to an embodiment of the present invention.
9 is an internal configuration diagram of a server according to an embodiment of the present invention.
10 is a signal flow diagram illustrating a signal flow between configurations of a remote control system for a cleaning robot apparatus according to an embodiment of the present invention.
11 is a flowchart illustrating a method of operating a server for remote control of a cleaning robot apparatus according to an embodiment of the present invention.
12 is a schematic view showing a contamination detection automatic cleaning robot using an air motor according to another embodiment of the present invention.
13 is an enlarged view showing a lower surface of the portion "A" in Fig.
14 is a view showing an automatic cleaning robot for detecting contamination using an air motor according to another embodiment of the present invention.
15 is a view showing the side surface of Fig.
Fig. 16 is a partial enlarged view of the injection guide of Fig. 14; Fig.

Hereinafter, embodiments of the present invention will be described with reference to the accompanying drawings. Although the present invention has been described with reference to the embodiments shown in the drawings, it is to be understood that the technical idea of the present invention and its essential structure and operation are not limited thereby.

FIG. 2 is a block diagram illustrating a configuration of a cleaning robot apparatus according to an embodiment of the present invention. FIG. 3 is a schematic perspective view illustrating a configuration of a cleaning robot apparatus according to an embodiment of the present invention. 1 is a perspective view showing a state after a cleaning robot is seated on a solar cell panel in the configuration of a cleaning robot apparatus according to an embodiment of the present invention;

2 to 4, the cleaning robot apparatus 1 according to an embodiment of the present invention mainly includes a cleaning robot for removing foreign substances on the surface of the solar cell panel 5 while moving along the solar panel 5, And a mounting device 20 for securely mounting the cleaning robot 10 on the solar panel 5 and replenishing and charging water and power.

The cleaning robot 10 is provided with a pair of guide rails 111 located parallel to one side and the other side of the solar cell panel 5 and is reciprocated by the movable motor 115 in the longitudinal direction of the solar cell panel A moving body 120 which reciprocates by a rotary motor along a guide rail 111 of the movable frame 110 and a movable body 120 which is mounted on one side of the movable body 120 and is connected to the solar cell panel 5 A detection sensor 140 installed at each corner of the mobile body 120 to sense a position of the mobile body 120 and a sensor unit 140 coupled to the mobile body 120, And a cleaning unit 170 for cleaning contaminants on the surface of the wafer 5.

The pollution inspection unit 130 includes a light emitting unit 131 that sends signals to the solar cell panel 5 with a predetermined angle of inclination and a receiving unit 133 that receives signals sent from the light emitting unit 131, The light emitting unit 131 and the receiving unit 133 may be an infrared sensor by comparing the magnitude of the signal transmitted from the transmitter 131 and the signal received by the receiver 133 to measure the degree of contamination.

The cleaning unit 170 includes a water splitting unit 171 for spraying washing water on the surface of the solar cell panel 5, a rotating motor, a rotating shaft that rotates in conjunction with the rotating motor, A brush unit 172 for cleaning the surface of the panel 5, a steam nozzle unit 173 for spraying the heater and the steam heated by the heater, air supplied to the blower and the blower, As shown in FIG.

The cleaning robot 10 of the embodiment of the present invention has a structure that can be attached to and detachable from the solar cell panel 5 so that the cleaning robot 10 can be automatically controlled through the mounting device 20, 5), it can be attached to another solar cell panel and operated, and it is easy to repair in case of failure.

Here, the solar cell panel 5 is a part for converting the solar cell into electricity. In order to generate a large amount of electricity, a plurality of solar cells are assembled to constitute a solar cell module, and a plurality of modules are assembled again to constitute a solar cell panel 5 .

3 to 4, in an embodiment of the present invention, an inclined surface is formed in accordance with the angle of incidence of the solar cell, and a solar cell module composed of a plurality of solar cells is arranged in a side- (5).

At this time, a guide lane 4 for guiding the moving wheel 113 of the cleaning robot 10 when the cleaning robot 10 moves can be formed on the inclined surface for supporting the solar cell panel 5. [ As a result, the cleaning robot 10 cleans the entire solar cell panel 5.

FIG. 5 is a view showing a cleaning robot of the cleaning robot apparatus according to an embodiment of the present invention, and FIG. 6 is an explanatory diagram illustrating an operation of the contamination inspection unit according to an embodiment of the present invention.

The configuration of the cleaning robot 10 according to an embodiment of the present invention will be described as follows.

The movable frame 110 includes a pair of guide rails 111 positioned parallel to one side and the other side of the solar cell panel 5 and is reciprocally translated by the movable motor 115 in the longitudinal direction of the solar cell panel do.

5, the movable frame 110 includes two parallel guide rails 111, one side of which is bent like a hook so as to be seated on one end of an upper side of an inclined surface where the solar cell panel 5 is formed, 111 and a movable motor 113 driven by the guide lane 4 of the solar panel 5 and a movable motor 115 driving the movable wheel 113. [

Accordingly, the movable frame 110 can move along the longitudinal direction of the solar cell panel 5, that is, along the both side guide lanes 4, and can be mounted or supported by the following components, It is possible to perform the reciprocating translational motion in the longitudinal direction of the drum.

The movable frame 110 is provided with a detection sensor 140 for detecting the position of the movable body 120 so that the cleaning robot 10 can reciprocate safely on the solar panel 5 So that the movement of the movable frame 110 can be restricted.

Although the method of moving the movable frame 110 using the roller type moving wheel 113 has been described in the embodiment of the present invention, the moving method of the movable frame 110 is not limited to the present embodiment, A variety of moving modes can be applied.

The movable body 120 is reciprocally moved by the rotary motor along the guide rails 111 of the movable frame 110 and functions to fixedly support various components of the cleaning robot 10. [

That is, the moving body 120 according to an embodiment of the present invention includes a pair of guide rails 111, which are coupled with the guide rails 111 of the movable frame 110 in a rack and pinion manner, And is formed in a plate shape for mounting and supporting parts of the cleaning robot (10).

Here, a pinion 121 is installed on one side of the movable body 120 so as to reciprocate along a pair of guide rails 111, and a rotary motor (not shown) for rotating the pinion 121 of the movable body 120 The reciprocating translational movement is possible.

More specifically, the movable frame 110 has a rack gear formed at one side of the guide rail 111 and a pinion 121 moving along the guide rail 111 formed with the rack gear The pinion 121 is rotated by a rotating motor (not shown) installed on the moving body 120 and is translated along a rack of the pair of guide rails 111.

In the present embodiment, a method of moving the moving body 120 along the guide rail 111 of the movable frame 110 using a rack and pinion method has been proposed. However, in the moving body 120, Is not limited to the present embodiment, and various moving methods according to known techniques may be applied.

In this embodiment, a rack and a pinion are used to move along the guide rail 111. However, a ball screw, a roller, or the like may be used in some cases.

The cleaning robot 10 according to an embodiment of the present invention may include a contamination inspection unit 130 mounted on one side of the moving body 120 to measure the contamination degree of the surface of the solar cell panel 5, And a detection sensor 140 installed at an edge of the cleaning robot 10 to detect the position of the cleaning robot 10. [

And a cleaning unit 170 coupled to the moving body 120 to clean contaminants on the surface of the solar cell panel 5.

The pollution inspection unit 130 includes a light emitting unit 131 and a receiving unit 133. The light emitting unit 131 and the receiving unit 133 are composed of a plurality of infrared sensors.

6, the pollution inspection unit 130 includes a light emitting unit 131 for emitting a signal with a predetermined angle to the solar panel 5 and a receiving unit for receiving signals transmitted from the light emitting unit 131 133). The reflectance of a signal reflected varies depending on the amount of foreign matter such as dust contained on the surface of the solar cell panel (FIGS. 6A, 6B, 6C, and 6D).

Accordingly, the reflectance of the signal transmitted from the light emitting unit 131 and the signal received by the receiving unit 133 can be detected to read the pollution degree data, and the degree and position of the pollution can be known.

The detection sensor 140 detects an obstacle or a moving direction of the surrounding robot while the cleaning robot 10 is driven, and transmits the detection result to the control unit 160. For this, the detection sensor 140 may include a position sensor, a velocity sensor, an acceleration sensor, a proximity sensor, a torque sensor, and a distance detector. The position sensor may be a potentiometer, an encoder, a linear variable differential type transformer, a resolver, a travel time displacement sensor, or the like. As the velocity sensor, an encoder, a tachometer, a derivative of a position signal, and the like can be used. Proximity sensors may include magnetic proximity sensors, optical proximity sensors, ultrasonic proximity sensors, inductive proximity sensors, capacitive proximity sensors, and eddy current proximity sensors. And an ultrasound distance detector and an optical distance detector may be used as the distance detector. The sensing sensor 140 may be applied in consideration of performance, price, size, output type, interfacing, and resolution of the sensor. Also, the sensing sensor 140 can be applied considering sensitivity, linearity, range, response time, frequency response, reliability, accuracy, and repeat accuracy.

The battery unit 150 supplies power to the cleaning robot 10 and is attached to the movable frame 110 or the movable frame 120, A power source, and a rotation motor. When the power source has a certain value or less, the power source is connected to a specific socket to charge the power source.

The battery unit 150 can be formed as a battery type capable of continuous operation for 2 hours or more. That is, the battery 150 may be formed of a nickel battery, a lithium battery, or the like, but it is possible to use a lithium polymer battery in consideration of efficiency of use.

When the battery unit 150 has a power amount less than a predetermined level, the battery unit 150 may be automatically moved to the charging socket under the control of the controller 160 to charge the power source.

The control unit 160 receives signals from the contamination checking unit 130 and the detection sensor 140 and controls the cleaning robot 10. The mobile body 120 and the cleaning unit 170 by receiving data (signals) input from the pollution inspection unit 130 and the detection sensor 140. [

The cleaning unit 170 includes a water distributing unit 171, a brush unit 172, a steam nozzle unit 173, and an air blower 174.

The water splash part 171 functions to spray washing water on the surface of the solar cell panel 5. [

The brush unit 172 serves to clean the surface of the solar cell panel by being coupled to the outer circumferential surface of the rotating shaft, the rotating shaft rotating in conjunction with the rotating motor, and the rotating shaft.

The steam nozzle unit 173 serves to inject steam heated by the heater and the heater.

The air blower 174 functions to blow air supplied to the blower and the blower onto the surface of the solar cell panel 5.

The mounting apparatus 20 is a mnipulator that moves a workpiece, that is, a machine having a function similar to that of a human's arm. Here, the mounting apparatus 20 includes various apparatuses for mounting the cleaning robot 10 on the solar panel 5 .

That is, the cleaning robot apparatus 1 according to an embodiment of the present invention comprises a cleaning robot 10 and a mounting apparatus 20 for detaching the cleaning robot 10 on the solar panel 5.

The mounting device 20 includes a fixed frame 210 mounted on the moving means 8, a robot arm 220 extending from the fixed frame 210 and capable of being moved up and down by one side in a joint motion by a driving device, And an infrared camera 230 for measuring the length and inclination of the solar cell panel.

The configuration of the mounting apparatus 20 according to an embodiment of the present invention will be described in detail as follows.

The moving means 8 referred to in the present invention may be a truck or an automobile that is moved to an internal combustion engine that is generally used, or an electric vehicle that is moved by electricity. In the mounting apparatus 20 according to the embodiment of the present invention, And may be provided specially manufactured.

The stationary frame 210 fixes and supports the robot arm 220 so that one side of the robot arm 220 can be moved to a specified position by smooth movement of the robot arm 220 by a driving device (not shown).

A water tank 240 for supplying water to or supplying water to the cleaning robot 10 may be installed in the fixed frame 210 and a charging unit 250 for supplying or charging power to the cleaning robot 10 may be installed .

The mounting apparatus 20 further includes a controller 260 for controlling the robot arm 220 to operate safely using image data read by the infrared camera 230 from the position and inclination of the solar panel 5 can do.

The robot arm 220 may be controlled by a person but may be controlled to automatically mount the cleaning robot 10 on the solar panel 5 by the image data received from the infrared camera 230 .

In particular, the cleaning robot 10 has a hook type guide rail 111 whose one side is curved like a ring, and the guide rail 111 is hung by the robot arm 220 on the upper side inclined to the solar panel 5, And is seated on the panel 5.

The infrared camera 230 reads comprehensive image data such as the width, the length and the inclined angle of the solar cell panel 5. Based on the read image data, the mounting apparatus 20 automatically controls the robot arm 220 to operate.

The water tank 240 is connected to one side of the cleaning robot 10 through a detachable hose to supply or replenish water or washing water to the cleaning robot 10.

The charger 250 is connected to one side of the cleaning robot 10 and a detachable type jack to supply power to the cleaning robot 10. If the battery is mounted on the cleaning robot 10, .

The control unit 260 operates the robot arm 220 based on the image data read by the infrared camera 230 and the signal received from the cleaning robot 10 to place the cleaning robot 10 on the solar panel 5 Or to separate and supply water and power.

The environment measuring unit 270 measures the ambient environment in which the solar panel 5 is installed, that is, temperature, humidity, wind speed, and wind direction, so that the mounting apparatus 20 safely mounts the cleaning robot 10 on the solar panel 5, The cleaning robot 10 may be provided with data so that the cleaning robot 10 can efficiently clean the surface of the solar cell panel 5 and the cleaning robot 10 may be operated by the supplied data.

The environment measuring unit 270 may include a sunlight level meter, a solar altimeter, an anemoscope / anemometer, an atmospheric dust meter, a nephometer, and a rainfall meter.

The sunlight amount measurement system can provide the environment measurement unit 270 with information on the date and time of operation of the solar panel cleaning robot apparatus and the amount of sunshine according to the latitude and longitude of the operation site.

The solar altimeter can provide the environment measurement unit 270 with information on the date and time of operation of the solar panel cleaning robot apparatus, and the altitude of the sun according to latitude and longitude, which are operating positions.

The wind direction / anemometer can provide the environment measurement unit 270 with information on wind direction and wind speed according to the operating position of the solar panel cleaning robot apparatus.

The atmospheric dust meter can provide the environment measuring unit 270 with information on the atmospheric dust concentration according to the operating position of the solar panel cleaning robot apparatus.

The cloud system can provide the environment measurement unit 270 with information on the amount of cloud according to the operating position of the cleaning robot apparatus for the solar panel.

The rainfall gauge can provide the environment measurement unit 270 with information on the amount of rainfall according to the operating position of the cleaning robot apparatus for the solar panel.

Such various weather conditions are applied to the environment measurement unit 270 so that the data provided by the environment measurement unit 270 to the control unit 260 and the cleaning robot 10 can be more precise.

The cleaning robot 10 receiving the data moves on the surface of the solar panel 5 independently and can perform an efficient cleaning function.

Therefore, the cleaning robot apparatus 1 according to the embodiment of the present invention can securely mount the cleaning robot 10 on the solar panel 5 by the mounting apparatus 20, The surface of the panel 5 can be efficiently cleaned. When the cleaning robot 10 lacks water and a power source, water and power are supplied or charged.

7 is a configuration of a remote control system for a cleaning robot apparatus for removing dust on a solar cell panel according to an embodiment of the present invention.

The system of FIG. 7 includes a cleaning robot 10, a mounting apparatus 20, a network 30, a server 40, and a database 50.

Generally, the solar panels 5 are installed in different areas. For example, a plurality of solar panels 5 may be installed in the same area, but the installed places may be spaced apart from each other by a predetermined distance.

In the present invention, the cleaning robot 10 includes a robot communication unit 180 and communicates with the server 40 through the robot communication unit 180 and the network 30.

The network 30 is a communication network for connecting the robot communication unit 180 and the server 40 of the cleaning robot 10. [

The server 40 can provide the information of the area set in the cleaning robot 10 and can update and manage various information in the database 50. [

The cleaning robot 10 can independently perform cleaning but may perform cleaning in connection with information stored in the database 50 for efficient management.

The database 50 may store various information so that the cleaning robot 10 can smoothly clean the solar cell panel 5. [

In FIG. 7, the server 40 and the database 50 are shown as being independent from each other, but this is for the sake of convenience in understanding the system configuration. Therefore, the server 40 may be considered to include the database 50.

The cleaning robot device for removing dust on the solar panel is configured to generate a first cleaning area map A01 as the cleaning robot 10 performs cleaning according to the cleaning execution plan stored in the database 50, And transmits the cleaning area map A01 to the server 40. [

The server 40 transmits the second cleaning area map A02 based on the first cleaning area map A01 to the cleaning robot 10 so as to perform cleaning according to the second cleaning area map A02 do. In other words, the cleaning robot 10 generates the first cleaning area map A01 while completing the cleaning or performing the cleaning according to the cleaning execution plan stored in the database 50. The cleaning robot 10 transmits the first cleaning area map A01 to the server 40 in response to the cleaning request of the server 40. [ The server 40 confirms the first cleaning area map A01 and identifies the areas that have not been cleaned due to the characteristics of the non-cleaned area or the specific structure. The server 40 creates a second cleaning area map A02 composed of the designated areas when the designated area becomes cleanable. Thereafter, the server 40 transmits the second cleaning area map A02 to the cleaning robot 10, and accordingly, the cleaning robot 10 performs cleaning according to the second cleaning area map A02.

As described above, the remote control system of the cleaning robot apparatus according to the embodiment of the present invention is configured such that the first cleaning area map A01 generated by cleaning according to the cleaning execution plan stored in the database 50 is updated according to the value set by the server 40 By performing the adjustment cleaning, it is possible to remove the repeated cleaning of the area, and to perform the cleaning only in the necessary area.

Hereinafter, each configuration of the remote control system of the cleaning robot apparatus according to the embodiment of the present invention will be described in more detail.

2, the cleaning robot 10 of the present invention includes a movable frame 110, a moving body 120, a contamination inspection unit 130, a detection sensor 140, a battery 150, a control unit (not shown) 160 and a cleaning unit 170. The robot communication unit 180 and the robot memory unit 190 are additionally configured.

The robot communication unit 180 communicates with the server 40 via the network 30.

The robot communication unit 180 transmits the first cleaning area map A01 to the server 40 through the network 30 and receives the second cleaning area map A02 transmitted by the server 40. [

The robot memory unit 190 is equipped with a memory for storing various application programs for booting the cleaning robot 10 and for operating the cleaning robot 10 in an embedding manner. The robot memory unit 190 stores a first cleaning area map A01 generated by the cleaning robot 10 according to a cleaning pattern and a cleaning execution plan stored in the database 50. [ The robot memory unit 190 may temporarily store the second cleaning area map A02 transmitted by the server 40. [

The first cleaning area map A01 includes cleaning area information for the entire area where the cleaning robot 10 has performed cleaning.

The first cleaning area map A01 may be generated in accordance with various patterns such as a predetermined pattern to be operated by the cleaning robot 10 during cleaning, for example, a date, a vertical, or a zigzag.

The control unit 160 controls the overall operation of the cleaning robot 10 and controls the signal flow between the respective components described above so that the cleaning robot 10 can clean So that the work can be performed. In other words, the control unit 160 performs cleaning according to the cleaning performance information stored in the database 50. At this time, the controller 160 controls the movable frame 110, the moving body 120, and the cleaning unit 170 according to the cleaning performance information. At this time, the control unit 160 determines the surrounding object or environment using the sensing sensor 140 and controls the operation range and the direction of the movable frame 110 or the moving body 120 according to the determined state can do. The control unit 160 controls the robot communication unit 180 to transmit the first cleaning area map A01 to the server 40 and perform cleaning according to the second cleaning area map A02 from the server 40 .

Here, the control unit 160 can efficiently control the movement for cleaning by preceding the process of extracting the shortest distance to a plurality of designated areas included in the second cleaning area map A02.

The control unit 160 may check whether the power of the battery 150 is below a certain level and search the charging unit 250 using the sensing sensor 140 or the robot communication unit 180. [ Then, the control unit 160 controls the charging unit 250 to perform charging automatically.

On the other hand, if the controller 160 can not clean the first cleaning area map A01 due to the presence of a new obstacle or debris in the first cleaning area map A01, .

8 is a diagram showing an example of a first cleaning area map of the present invention.

Here, the first cleaning area map A01 will be described in more detail with reference to FIG.

Referring to FIG. 8, the first cleaning area map A01 of the present invention is defined in the form of a matrix, and cleaning information is recorded in the divided units formed by the respective matrices. In other words, the first cleaning area map A01 describes cleaning information including the area (O) that has been cleaned, the obstacle area (X), etc. in each of the matrix areas of the map. Accordingly, the cleaning robot 10 of the present invention can check the cleaned area (O) and the obstacle area (X) through the first cleaning area map A01 to find an area that has not been cleaned. Here, the first cleaning area map A01 may also store time information on the cleaned area (O). The cleaning robot 10 may check the old cleaning area based on the time information and perform cleaning. The time information may be represented by color information. That is, the first cleaning area map A01 can display the color information in a darker color as the cleaning area O becomes longer.

FIG. 9 is an internal configuration diagram of a server according to an embodiment of the present invention, and FIG. 10 is an internal configuration diagram of a database according to an embodiment of the present invention.

The server 40 receives the first cleaning area map A01 from the cleaning robot 10 via the network 30 and transmits the second cleaning area map A02 to the cleaning robot 10 in response to the first cleaning area map A01.

The server 40 includes a map information setting module capable of editing the first cleaning area map A01. The server 40 may temporarily or semi-permanently store the first cleaning area map A01 and the second cleaning area map A02 received via the network 30. [ Such a server 40 can be divided into a program area and a data area which is a database 50. [

Here, the program area may be displayed on a monitor (not shown) for editing the first cleaning area map A01 when the map information setting module is activated.

The data area is an area in which data generated according to use of the server 40 is stored and stores a first cleaning area map A01 and a second cleaning area map A02 in which the first cleaning area map A01 is edited do. The first cleaning area map A01 may include not only the cleaning area of the cleaning robot 10 but also the cleaning related information of each area such as the photographing information of the obstacle and the position of the obstacle.

The server control unit 420 controls the overall operation of the server and the signal flow between the internal blocks of the server.

In particular, the server control unit 420 controls the server receiving unit 410 to request the cleaning robot 10 for a cleaning history corresponding to the first cleaning area map A01. Then, the server control unit 420 receives the first cleaning area map A0. At the time of displaying the first cleaning area map A01, the server control part 420 can activate the map information setting module and edit the first cleaning area map A01.

Then, the server control unit 420 creates a second cleaning area map A02 based on the designated area transmitted to the server receiving unit 410 on the editing screen. When a signal corresponding to the transmission of the second cleaning area map A02 is inputted and the second cleaning area map A02 is completed, the server control part 420 transmits the second cleaning area map A02 to the cleaning robot 10 send.

Here, the server control unit 420 may receive an ACK (acknowledgment) for completion of receiving the second cleaning area map A02 from the cleaning robot 10. If the ACK signal is not received, the server control unit 420 may control to repeatedly transmit the second cleaning area map A02 after waiting for a predetermined time.

The server receiving unit 410 receives the cleaning robot control mode corresponding to the terminal input signal of the terminal input unit 283. Referring to the cleaning robot control mode, the server receiving unit 410 requests the first cleaning area map A01 of the cleaning robot 10. The server receiving unit 284 can also receive a cleaning robot status item that can check the status of the cleaning robot 10. Other cleaning items Various items related to robot control and cleaning can be additionally received according to the needs of the designer. Upon obtaining the cleaning history, the server control unit 420 creates a cleaning history request message and controls the cleaning robot 10 to transmit the cleaning history request message to the cleaning robot 10. Then, the first cleaning area map A01 is received from the cleaning robot 10. Although not shown in the detailed description of the present invention, when the state of the cleaning robot is selected, the server control unit 420 creates a cleaning robot state information request message and transmits the message to the cleaning robot 10. In response to this, the cleaning robot 10 can create the status and environment information of the cleaning robot 10 and transmit them to the server 40. Here, the state of the cleaning robot 10 may include the amount of the battery, the amount or the number of times the cleaning is performed, the planned schedules, and the like. The environment information may include information of the cleaning robot 10, that is, the type of the cleaning robot 10, the year of manufacture, the number of years of use, the status of software update,

The server receiving unit 410 stores the first cleaning area map A01 received from the cleaning robot 10 in the program.

The server receiving unit 410 can display the color in the cleaned area when displaying the cleaned area O in the first cleaning area map A01. In addition, the server receiving unit 410 may display an area that has not been cleaned in the first cleaning area map A01. The area where the cleaning robot 10 has failed to perform the cleaning may be an area where the obstacle is located or an obstacle that the cleaning robot 10 can not move. Here, when the server receiving unit 410 selects an area in which the obstacle or the like is disposed in the first cleaning area map A01, the server receiving unit 410 can display the cleaning information for the selected area. That is, when the first cleaning area map A01 links and stores the photographing information in the obstacle area, the server receiving unit 410 can display the photographing information corresponding to the obstacle area on the screen.

Accordingly, the user who has confirmed the first cleaning area map A01 confirms the area where the cleaning robot 10 has failed to perform cleaning, and if there is an obstacle, the obstacle is removed, have. Accordingly, when the cleaning non-performing area is converted into the cleaning possible area, the server 40 creates the second cleaning area map A02 by designating the cleanable areas according to a predetermined process.

The server receiving unit 410 of the present invention receives the second cleaning area map A02 having only the area set by the server 40. [ At this time, the second cleaning area map A02 can be displayed not only in the cleanable area but also in the area determined to be repeatedly required, even if the cleaning is completed.

On the other hand, when the cleaning robot 10 receives the second cleaning area map A02, the cleaning robot 10 extracts information on the cleaning areas included in the second cleaning area map A02. Then, the cleaning robot 10 calculates a path through which the cleaning areas can be moved by the shortest distance based on a predetermined algorithm. When the calculation is completed, the cleaning robot 10 starts to clean the cleaning areas designated respectively in the second cleaning area map A02 based on the path.

Hereinafter, a remote control method for a cleaning robot apparatus according to an embodiment of the present invention will be described.

FIG. 10 is a signal flow diagram illustrating signal flows between respective components of the remote control system of the cleaning robot apparatus of the present invention, and FIG. 11 is a flowchart illustrating a remote control method of the cleaning robot apparatus of the present invention.

10 and 11, in the remote control method of the cleaning robot apparatus of the present invention, first, the cleaning robot 10 performs cleaning according to the cleaning execution plan, and generates a first cleaning area map A01 corresponding thereto And updates the first cleaning area map A01 while the cleaning is continued (S101).

On the other hand, the server 40 confirms whether it is the cleaning robot control mode (S102). The cleaning robot control mode can be activated through the process of the server 40. [ Next, when the server 40 selects an item for acquiring the cleaning history in the cleaning robot control mode, the server 40 transmits a cleaning history request message requesting the cleaning robot 10 to the first cleaning area map A01 (S103).

When the cleaning robot 10 receives the cleaning history request message, the cleaning robot 10 transmits the first cleaning area map A01 to the server 40. The server 40 receives the first cleaning area map A01 from the cleaning robot 10, (A01) (S105). Here, the first cleaning area map A01 can store information on the location of obstacles, obstacles, and the like occurring during the display and cleaning of the cleaned area while the cleaning robot 10 performs cleaning according to the cleaning plan have. In addition, when there is an obstacle or an obstacle, the first cleaning area map A01 may be information obtained by photographing using infrared camera 230 through communication, and storing photographing information together with information on the obstacle and obstacle have. The first cleaning area map A01 is a map storing cleaning related information for the entire cleaning area after completion of cleaning according to the cleaning execution plan set in the cleaning robot 10. [ When the cleaning robot 10 is in a state in which the cleaning robot 10 is not completed, the first cleaning area map A01 indicates a state in which cleaning has been performed up to now in the entire cleaning execution plan, and the area in which cleaning is to be performed may be separately displayed. The area that has been cleaned on the first cleaning area map A01 may perform the same marking and may be displayed in different colors for later cleaning as time elapses.

Next, the server 40 performs the editing operation on the received first cleaning area map A01 according to the set process (S106). The editing operation on the first cleaning area map A01 is performed by the user selecting the areas requiring cleaning on the first cleaning area map A01, .

In step S106, the server 40 creates a second cleaning area map A02 in which an area to be additionally cleaned is designated according to the data input on the first cleaning area map A01 (S107).

Next, the server 40 transmits the second cleaning area map A02 to the cleaning robot 10 (S108), and confirms whether or not the ACK corresponding thereto is received (S109). If the ACK is not received within the predetermined time in step S109, step S108 may be repeated.

On the other hand, the cleaning robot 10 receives the second cleaning area map A02, performs cleaning according to the second cleaning area map A02, performs cleaning on the second cleaning area map A02 The related information is updated (S110). When the second cleaning area map A02 is completed, the cleaning robot 10 may transmit a message of cleaning completion to the server 40. [ In step S110, the cleaning robot 10 performs a shortest distance algorithm operation on the scheduled cleaning areas included in the second cleaning area map A02, and performs cleaning according to the calculation result.

FIG. 12 is a schematic view showing a contamination-detecting automatic cleaning robot using an air motor according to another embodiment of the present invention, FIG. 13 is an enlarged view showing a lower surface of the "A" 1 is a view showing a moving body of a contamination-detecting automatic cleaning robot using an air motor according to another embodiment.

Fig. 15 is a side view of Fig. 14, and Fig. 16 is a partial enlarged view of the injection guide of Fig.

Referring to FIG. 12, the contamination detecting automatic cleaning robot 10 using an air motor according to another embodiment of the present invention moves the surface of the solar cell panel 5 while floating on a surface of the solar panel 5 at a predetermined height It is a cleaning device.

Here, the cleaning robot 10 includes a pair of guide rails 111 positioned parallel to one side and the other side of the solar cell panel 5, and is movable by the movable motor 115 in the longitudinal direction of the solar cell panel A moving body 120 moving along the guide rail 111 of the movable frame 110 by the air motor 123 while lifting the surface of the solar panel 5 by a predetermined height, A contamination inspection unit 130 mounted on one side of the body 120 to measure the degree of contamination on the surface of the solar cell panel 5, a detection sensor unit 140 installed on each corner of the moving body 120, And a cleaning unit 170 coupled to the moving body 120 to clean contaminants on the surface of the solar cell panel 5.

A battery unit 150 for supplying power to the cleaning robot 10 and a control unit 160 for overall control may be installed in the movable frame 110 or the movable frame 120, An air compressor (not shown) may be mounted on one side of the moving body 120 to supplement the function of the motor 123.

12, the configuration of the cleaning robot 10 according to another embodiment of the present invention will be described in detail as follows.

The movable frame 110 has a pair of guide rails 111 positioned parallel to one side and the other side of the solar cell panel 5 and is moved back and forth by the movable motor 115 in the longitudinal direction of the solar cell panel .

12, the movable frame 110 includes two parallel guide rails 111 which can be seated on one side of the solar cell panel 5 and a pair of parallel guide rails 111 supporting the guide rails 111, A moving wheel 113 driven along the guide lane 4 of the driving wheel 5 and a movable motor 115 driving the moving wheel 113. [

Accordingly, the movable frame 110 can move along the longitudinal direction of the solar cell panel 5, that is, along the guide lane 4 at the side end, and can be mounted or supported by the following components and equipment, Backward movement in the longitudinal direction of the main body 5.

In addition, the movable frame 110 is provided with a sensing sensor unit 140 for sensing the position of the movable body 120, so that the cleaning robot 10 can safely move on the solar panel 5 The position of the movable frame 110 may be sensed and movement may be restricted.

In another embodiment of the present invention, a method of moving the movable frame 110 using the roller type moving wheel 113 has been described. However, the moving method of the movable frame 110 is not limited to the present embodiment, And can be applied as a substitute.

The moving body 120 is moved by the air motor 123 along the guide rails 111 of the movable frame 110 and serves to fix and support various components and equipments of the cleaning robot 10. [

That is, the moving body 120 according to another embodiment of the present invention moves along the guide rails 111 of the movable frame 110, and as shown in FIG. 13, on the lower surface of the moving body 120 And can be moved on the surface of the solar cell panel 5 by a predetermined height by the air injected through the disposed air holes.

14 and 15, the moving body 120 for air lifting includes a plurality of air inflow pipes 122, an air motor 122 for enforcing air inflow into the air inflow pipe 122, An air injection pipe 125 as a passage through which the air introduced by the air motor 123 is injected and an injection guide 127 for adjusting the injection angle of the air injection pipe 125.

As shown in FIG. 14, a plurality of air inlet pipes 122 are formed on the upper surface of the moving body 120, and holes are formed at left and right sides of the moving direction, .

Specifically, a plurality of air inlet pipes 122 formed at predetermined intervals in the transverse direction of the moving body 120 are installed at predetermined intervals along the moving direction of the moving body 120.

In addition, the air inlet pipe 122 may be formed with a mesh network at the entrance thereof to prevent dust and foreign substances from entering the air.

The air motor 123 is electrically driven and forms an S line flow path for inducing natural air movement as shown in FIG. 15 to efficiently discharge the air introduced into the air inlet pipe 122, (Not shown).

That is, the air introduced into the air inlet pipe 122 is discharged through the air spray pipe 125 by the air motor 123. At this time, the moving body 120 can be lifted up to a predetermined height above the surface of the solar cell panel 5 by the discharged air.

The air injection pipe 125 is connected to an outlet of the air motor 123 as shown in FIGS. 14 and 15, and is connected to an air hole disposed on the lower surface of the moving body 120.

A plurality of air spray tubes 125 are installed at a predetermined distance apart from each other along the transverse direction of the moving body 120 in the lower direction of the moving body 120. The distance and the distance may be appropriately set in consideration of the weight of the moving body 120, the moving speed, and the like.

The injection guide 127 is provided at the outlet of the air injection tube 125 and is designed to be rotated at a predetermined angle. As shown in FIG. 16, the injection guide 127 has a trapezoidal shape when viewed from the front, Shape.

This is because the width of the injection guide 127 in the moving direction of the moving body part 120 is widened and the longitudinal direction of the moving body part 120 is narrowed so that the air floating force is sufficiently To maintain a proper injection pressure so that the injection pressure can be maintained.

In addition, the jetting guide 127 is formed to be inclined toward the direction opposite to the traveling direction of the air jetting tube 1250 by a predetermined angle. At this time, the inclination angle with respect to the horizontal direction is preferably in a range of 0 to 20 degrees. This is a range in which the propulsive force and the levitating force are simultaneously considered to the rear of the moving body portion 120. [

Further, the angle of the injection guide 127 can be freely adjusted for the forward and backward adjustment. That is, a rotation device for adjusting a predetermined angle is provided at one side of the injection guide 127 to control the weight of the moving body 120, the moving speed, the moving distance, the forward / backward direction, Respectively.

The cleaning robot 10 according to another embodiment of the present invention may include a contamination inspection unit 130 mounted on one side of the moving body 120 to measure the contamination degree of the surface of the solar cell panel 5, 130 are as described above.

Here, the solar cell panel 5 is a part for converting the solar cell into electricity. In order to generate a large amount of electricity, a plurality of solar cells constitute a solar cell module, and a plurality of modules are assembled again to constitute a solar cell panel 5 .

6, in an embodiment of the present invention, a slope is formed in accordance with the angle of incidence of the solar cell, and a general solar cell panel 5, in which solar cell modules composed of a plurality of solar cells are arranged side by side, .

At this time, a guide lane 4 for guiding the cleaning robot 10 when the cleaning robot 10 moves can be formed on an inclined surface for supporting the solar panel 5. As a result, the cleaning robot 10 cleans the entire solar cell panel 5.

The cleaning robot 10 according to another embodiment of the present invention may include a detection sensor unit 140 installed at an edge of the moving body 120 to detect the position of the cleaning robot 10, (140) are as described above.

The battery unit 150 supplies power to the cleaning robot 10 and supplies power to driving devices such as a movable motor and an air motor and various sensors mounted on the movable frame 110 or the movable frame 120, A warning alarm may be generated.

The battery unit 150 can be formed as a battery type capable of continuous operation for 2 hours or more. That is, the battery 150 may be formed of a nickel battery, a lithium battery, or the like, but it is possible to use a lithium polymer battery in consideration of efficiency of use.

When the battery unit 150 has a power amount less than a predetermined level, the battery unit 150 may be automatically moved to the charging socket under the control of the controller 160 to charge the power source.

The control unit 160 receives signals from the contamination checking unit 130 and the detection sensor unit 140 and controls the cleaning robot 10. The mobile body 120 and the cleaning unit 170 by receiving data (signals) input from the pollution inspection unit 130 and the detection sensor unit 140. [

The cleaning unit 170 is composed of a water splasher, a brush, a steam nozzle, and an air blower.

That is, the cleaning unit 170 includes a water distributing unit for spraying washing water on the surface of the solar cell panel 5, a rotating motor, a rotating shaft that rotates in conjunction with the rotating motor, A steam nozzle unit for spraying steam heated by the heater and the heater, and an air blower for spraying the air supplied to the blower and the blower onto the surface of the solar cell panel do.

However, since the cleaning unit 170 can be applied to the prior art, a detailed description thereof will be omitted.

The contamination detecting automatic cleaning robot 10 using the air motor according to another embodiment of the present invention operates as follows.

First, the cleaning robot 10 proposed by the present invention is brought close to the solar cell panel 5 requiring cleaning by using a moving means.

The adjacent cleaning robot 10 is placed on the solar cell panel 5 by a mounting device or the like.

The cleaning robot 10 mounted on the solar panel 5 moves on the surface of the solar panel 5 under the control of the control unit 160. [

The movement of the cleaning robot 10 is controlled such that the movable frame 110 is operated in the longitudinal direction of the solar panel 5 and the traveling direction of the solar panel 5, Lt; / RTI >

At this time, the movable body part 120 is operated to move the surface of the solar cell panel 5 along the pair of guide rails 111 at a predetermined height.

The air introduced into the air inlet pipe 122 is transferred to the air injection pipe 125 by the air motor 123 and reaches the injection guide 127.

The air injected from the jetting guide 127 is discharged onto the surface of the solar cell panel 5 in consideration of the weight and moving speed of the moving body 120.

The discharged air not only lifts the moving body 120 but also functions to remove dust and foreign substances from the surroundings.

As described above, the air discharged by the air motor 123 is sprayed onto the solar cell panel 5 and floated up to a predetermined height so as to form an air film on the surface of the solar cell panel 5, An air bush function can be implemented in the present invention.

The control unit 160 determines a cleaning area according to a signal sent from the contamination inspection unit 130 and the detection sensor unit 140 and operates the cleaning unit 170 starting from one side of the solar cell panel 5.

The cleaning robot 10 is not detached from the edge of the solar panel 5 by the detection sensor unit 140 and the signal of the detection sensor unit 140 is transmitted to the control unit 160 before reaching the release position The movement is stopped.

The pollution inspection unit 130 measures the degree of contamination on the surface of the solar cell panel 5 and is transmitted to the control unit 160. The control unit 160 operates the cleaning unit 170 according to the transmitted data.

In particular, depending on the degree of contamination measured by the pollution inspection part 130, the water splash part, the brush part, the steam nozzle part, and the air blow constituting the cleaning part 170 are selectively operated.

When cleaning of the solar panel 5 is completed by the cleaning robot 10, the transportation device moves to a position where the cleaning robot 10 can pick-up the cleaning robot 10.

As described above, the cleaning robot 10 proposed by the present invention independently moves the surface of the solar panel 5 and can perform an efficient cleaning function.

Therefore, the air floating solar cell panel moving and cleaning robot 10 proposed by the present invention includes a pair of guide rails 111 positioned parallel to one side and the other side of the solar cell panel 5, and the solar cell panel 5 A moving body 120 which reciprocates by the air motor 123 along the guide rail 111 and a movable body 110 which reciprocates by the moving motor 115 in the longitudinal direction of the movable body 120. [ A contamination inspection unit 130 mounted on one side of the solar cell panel 120 for measuring the contamination degree of the surface of the solar cell panel 5, a detection sensor unit 140 installed at each corner of the moving body unit 120, And a cleaning unit 170 mounted on one side of the movable body 120 to clean contaminants on the surface of the solar cell panel 5.

The moving body 120 includes a plurality of air inlet pipes 122 formed at upper portions of the moving body 120 and separated from each other by a predetermined distance in the transverse direction of the moving body 120, An air motor 123 for enforcing the inflow of air into the air inlet pipe 122 and an air motor 123 for injecting the air introduced by the air motor 123 onto the surface of the solar cell panel 5, So that the air is sprayed on the surface of the solar cell panel 5 by the air injected through the air spray pipe 125 so as to be spaced apart from the surface of the solar panel 5 by a predetermined height to form an air film .

The moving body 120 may further include an injection guide 127 installed at an outlet of the air spray tube 125 and capable of rotating at a predetermined angle.

In addition, the moving speed of the moving body 120 can be increased or decreased according to the rotation of the injection guide 127 by a predetermined angle.

The injection guide 127 has a trapezoidal shape that widens downward when viewed from the front, and a three-dimensional shape that is a funnel-shaped bottom that becomes narrower when viewed from the side. The air- .

The pollution inspection unit 130 includes a light emitting unit 131 that sends signals to the solar cell panel 5 with a predetermined angle of inclination and a receiving unit 133 that receives signals sent from the light emitting unit 131, The light emitting unit 131 and the receiving unit 133 are infrared sensors. The light emitting unit 131 and the receiving unit 133 measure the degree of contamination by comparing magnitudes of signals transmitted from the light emitting unit 131 and signals received by the receiving unit 133.

The following effects can be expected from the air cleaning solar battery panel moving robot 10 according to an embodiment of the present invention.

Air can be lifted so that the movable body part is spaced apart by a predetermined height by using an air motor, and can be used for movement and cleaning.

In addition, since the movable body is floated so as to be spaced apart by a predetermined height, physical contact with the solar cell panel is minimized, thereby reducing the damage of the solar cell panel.

In addition, there is an advantage in that dust and contaminants are removed by using the flow of air due to air rising of the cleaning robot.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit or scope of the invention as defined in the following claims And changes may be made without departing from the spirit and scope of the invention.

10: Cleaning robot proposed by the present invention
110: movable frame 120: movable body part
130: pollution inspection unit 140: detection sensor unit
150: Battery section 160: Control section
170: Cleaning section

Claims (4)

A movable frame having a pair of guide rails positioned parallel to one side and the other side of the solar cell panel and reciprocating by a movable motor in the longitudinal direction of the solar cell panel;
A moving body part reciprocating by the air motor along the guide rail,
A pollution inspection unit mounted on one side of the moving body and measuring the pollution degree of the surface of the solar cell panel,
A sensing sensor unit installed at each corner of the moving body unit for sensing a position,
And a cleaning unit mounted on one side of the moving body to clean contaminants on the surface of the solar cell panel,
The moving body portion
A plurality of air inflow pipes formed at an upper portion of the moving body portion and spaced apart from each other by a predetermined distance in a transverse direction of the traveling direction of the moving body portion,
The air motor for forcing air to flow into the air inlet pipe, and
And a plurality of air injection tubes for injecting the air introduced by the air motor onto the surface of the solar cell panel,
Wherein an air film is formed on the surface of the solar cell panel by a predetermined height so as to form an air film by the air injected through the air injection pipe. The method according to claim 1,
The moving body portion
And an injection guide installed at an outlet of the air injection tube and capable of rotating at a predetermined angle,
Wherein the movement speed of the moving body part can be increased or decreased according to the rotation of the injection guide at a predetermined angle. 3. The method of claim 2,
The injection guide
It is a trapezoidal shape with a wider bottom when viewed from the front,
Wherein the moving body portion is formed in a three-dimensional shape that is a funnel shape in which the lower portion is narrowed when seen from the side, and the air lifting efficiency of the moving body portion is higher under the same condition. The method according to claim 1,
The contamination inspection unit may include:
A light emitting unit for emitting a signal at a predetermined angle to the solar cell panel,
And a receiver for receiving a signal transmitted from the light emitting unit,
Wherein the controller measures the degree of contamination by comparing a signal transmitted from the light emitting unit with a signal received by the receiving unit, and the light emitting unit and the receiving unit are infrared sensors.

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