KR20130025486A - Adhesion type cleaning robot for solar battery - Google Patents

Abstract

PURPOSE: An suction type moving cleaning robot for a solar cell module is provided to easily install a cleaning device by comprising a plurality of suction bars, a plurality of forward movement units, a rotation unit, a control valve, and a vacuum pump. CONSTITUTION: An suction type moving cleaning robot for a solar cell module comprises a first upper suction bar(30), a second lower suction bar(40), a first forward movement unit, a second forward movement unit(60), a rotation unit(70), a control valve, a vacuum pump, and a control unit. The upper suction bar and the second lower suction bar move forwards or backwards and individually comprise elevating bars(31,41) and a vacuum type suction plate(32,42). The first forward movement unit and the second forward movement unit are individually connected to the first and a second upper suction bar and an upper part or a lower part body unit and move the first and the second suction bar forwards or backwards when the upper part or the lower part body unit is stopped or moves the upper or the lower body part when the first and the second upper suction bar are stopped. The rotation unit rotates the lower part body unit when the upper part body unit is stopped and rotates the upper part body unit when the lower part body unit is stopped. The control valve opens or closes from the vacuum pump to a first vacuum type suction plate or a second vacuum type suction plate.

Description

Adsorption Type Cleaning Robot For Solar Battery}

The present invention relates to an adsorption mobile cleaning robot for a solar cell module for cleaning the surface of the solar cell while moving the solar cell module in the adsorption method.

In recent years, global solar cell production has been increasing rapidly. As a result, photovoltaic technology is already becoming an industry in Japan, Germany, and the United States, and many companies are participating in related fields including solar cell, which is a core technology. In Korea, the number of companies that have entered or want to enter the solar field is gradually increasing in accordance with the government's technology development and distribution support policy. However, while investing heavily in the production and development of solar cells, the maintenance and management are weak.

The global trend is attracting new and renewable energy as a solution to high oil prices and environmental pollution. Photovoltaic power generation accounts for a lot of renewable energy. There are many factors such as environmental factors and managerial factors in photovoltaic power generation, but management of photovoltaic power generation system is important. In particular, as installation locations are diversified, management problems are occurring.

17 companies in Europe invested 400 billion euros (approximately 620 trillion won) in the Sahara Desert by 2025 to build a 25 GW solar power plant and started the Desertec Project, which produces 15% of Europe's electricity demand. . Due to the problem of the Deserttech project, sand and dust in the Sahara Desert are seeking solutions to reduce efficiency. China's large market is also an area with heavy yellow dust, so solar module cleaning technology is essential.

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

In order to solve the problem of deterioration of efficiency due to pollution of solar cell module, some solar power plants are equipped with fixed sprinkler to spray water or mobile sprinkler installed on solar cell fixed frame to remove dust and yellow dust, etc. There is a situation. This method uses water, so water must always be secured. The method of using water can manage the modules on the ground, but it is difficult and difficult to apply to the solar cell modules on the building roof or the outer wall of the building. In order to solve these disadvantages, a robot cleaner is needed, and in particular, the development of a solar cell module cleaning robot using an adsorption technology with an adsorption device that can be used for a solar cell module is necessary.

Currently, small-scale solar cell systems do not have any special cleaning and are cleaned naturally by rainwater, and some of large-scale solar systems are cleaned using sprinklers. Therefore, most general solar systems are not cleaned properly. Currently, solar cell module efficiency is reduced by 10% due to various pollutants such as dust, yellow dust, and pollen.

The present invention solves the problem that the conventional internal mechanism is complicated and the cleaner is not easy to install, yet it is unlikely to be put to practical use, and the installation of the cleaning function equipment is easy due to the relatively simple structure, although the existing technology and components and operation methods are different. To provide an adsorption mobile cleaning robot for a solar cell module.

Adsorption mobile cleaning robot for solar cell module according to the present invention,

An upper body portion 10 of the robot;

A lower body portion 20 of the robot rotatably coupled to the lower portion of the upper body portion 10;

Coupled to the upper body portion 10 so as to move forward and backward, the first lifting bar 31 is provided perpendicular to both sides, each of the first vacuum suction plate (32) at the lower end of the first lifting bar (31) The first upper suction rod 30 is provided;

Coupled to the lower body portion 20 so as to move forward and backward, the second lifting bar 41 is provided perpendicular to both sides, the second vacuum suction plate 42 at the lower end of the second lifting bar 41, respectively It is provided with a second lower adsorption rod (40);

The first upper suction rod 30 is coupled to the first upper suction rod 30 and the upper body portion 10 to move the first upper suction rod 30 in a state where the upper body portion 10 is stopped, or the first upper suction rod 30. A first forward means part 50 for advancing the upper body part 10 in the stopped state;

Coupled to the second lower suction rod 40 and the lower body portion 20 to advance the second lower suction rod 40 or the second lower suction rod 40 in a state where the lower body portion 20 is stopped. A second forward means part 60 for advancing the lower body part 20 in this stopped state;

The lower body portion 20 is coupled to the upper body portion 10 of the robot and the lower body portion 20 of the robot to rotate the lower body portion 20 while the upper body portion 10 is stopped. Rotating means 70 for rotating the upper body portion 10 in the stopped state;

Adsorption of the first vacuum suction plate 32 and the second vacuum suction plate 42 by opening and closing the pneumatic path from the vacuum pump 90 to the first vacuum suction plate 32 and the second vacuum suction plate 42. A control valve 80 for controlling detachment;

A vacuum pump (90) for providing a vacuum state to the first vacuum suction plate (32) or the second vacuum suction plate (42) when the control valve unit (80) is opened;

And a controller 95 for controlling the opening and closing of the control valve 80.

In accordance with the present invention, the conventional internal mechanism is complicated and the cleaner is not easy to install, which solves the problem of the possibility of practical application. An adsorption mobile cleaning robot for an easy solar cell module is provided.

1 is a side view of an adsorption mobile cleaning robot for a solar cell module according to a first embodiment of the present invention.
2 is a conceptual diagram of an adsorption mobile cleaning robot for a solar cell module according to a second embodiment.
3 is a configuration of the adsorption plate control of the adsorption mobile cleaning robot for a solar cell module according to the embodiment.
Figure 4 is a flow chart of the adsorption mobile cleaning robot for a solar cell module according to a first embodiment of the present invention.
5 is a connection diagram of the control unit and the suction plate.

Hereinafter, an adsorption mobile cleaning robot for a solar cell module according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings. FIG. 1 is an adsorption mobile cleaning for a solar cell module according to a first embodiment of the present invention. Figure 2 is a robot side view, Figure 2 is a conceptual diagram of the adsorption mobile cleaning robot for solar cell module according to the second embodiment, Figure 3 is a configuration of the adsorption plate control of the adsorption mobile cleaning robot for solar cell module according to an embodiment, Figure 4 is a first embodiment of the present invention 1 is a flowchart illustrating a method of moving an adsorption mobile cleaning robot for a solar cell module according to an embodiment, and FIG. 5 is a connection diagram of a control unit and an adsorption plate.

As shown in Figure 1, 2, 3, the adsorption mobile cleaning robot for solar cell module according to an embodiment of the present invention is the upper body portion 10 and the lower body portion 20 and the robot of the robot 1 the upper suction rod 30, the second lower suction rod 40, the first forward means 50, the second forward means 60, the rotation means 70, the control valve 80 and the vacuum pump It comprises a 90 and the control valve 80.

1 to 5, the robot is composed of the upper body portion 10 of the robot, and the lower body portion 20 of the robot rotatably coupled to the lower portion of the upper body portion 10.

As shown in Figures 1 to 5, the first upper suction rod 30 is coupled to the upper body portion 10 so as to be moved forward and backward, the first lifting bar 31 is provided on both sides vertically, First vacuum suction plates 32 are provided at lower ends of the first lifting rods 31, respectively. The second lower adsorption rod 40 is coupled to the lower body portion 20 in a forward and backward direction, and is provided with second lifting rods 41 perpendicular to both sides, respectively, at the lower ends of the second lifting rods 41. The second vacuum suction plate 42 is provided.

1 to 5, the first upper suction rod 30 is coupled to the first upper suction rod 30 and the upper body portion 10 to move the first upper suction rod 30 in a state where the upper body portion 10 is stopped. Or to advance the upper body portion 10 in a state in which the first upper suction rod 30 is stopped. The second advancing means 60 is coupled to the second lower adsorption rod 40 and the lower body portion 20 to advance the second lower adsorption rod 40 while the lower body portion 20 is stopped. The lower body 20 is advanced while the second lower suction bar 40 is stopped.

Rotating means 70 is coupled to the upper body portion 10 of the robot and the lower body portion 20 of the robot to rotate the lower body portion 20 in the state in which the upper body portion 10 is stopped or lower The upper body portion 10 is rotated while the body portion 20 is stopped.

The control valve 80 opens and closes the pneumatic path from the vacuum pump 90 to the first vacuum suction plate 32 and the second vacuum suction plate 42 to open the first vacuum suction plate 32 and the second vacuum suction plate. Adsorption and desorption of 42 are controlled. The vacuum pump 90 provides a vacuum state to the first vacuum suction plate 32 or the second vacuum suction plate 42 when the control valve unit 80 is opened.

The controller 95 controls the opening and closing of the control valve 80. In addition, the control unit controls the entire expansion of the first forward means 50, the second forward means 60, the rotation means 70 and the control valve 80, the vacuum pump 90 and the lifting rod, etc. .

As shown in FIG. 2, the apparatus further includes a third upper suction rod 130, a fourth lower suction rod 140, a third advance means 150, and a fourth advance means 160. desirable. At this time, the first upper adsorption rod 30 and the third upper adsorption rod 130 are horizontally spaced apart from each other and simultaneously operate the same, the second lower absorption rod 40 and the fourth lower absorption rod 140 Are preferably formed horizontally spaced apart from one another and operate at the same time.

As shown in FIG. 2, the third upper adsorption rod 130 is coupled to the upper body portion 10 in a forward and backward direction, and is provided with a third lifting rod 131 perpendicular to both sides, and the third lift. Third vacuum suction plates 132 are provided at lower ends of the steel rods 131, respectively.

The fourth lower adsorption rod 140 is coupled to the lower body portion 20 in a forward and backward direction, and is provided with fourth lifting rods 141 perpendicular to both sides, respectively, at the lower ends of the fourth lifting rods 141. The fourth vacuum suction plate 142 is provided. The third advancing means 150 is coupled to the third upper suction rod 130 and the upper body portion 10 to move the third upper suction rod 130 in a state where the upper body portion 10 is stopped. The upper body portion 10 is advanced in the third upper suction bar 130 is stopped. The fourth forward means 160 is coupled to the fourth lower adsorption rod 140 and the lower body portion 20 to advance the fourth lower adsorption rod 140 while the lower body portion 20 is stopped. The lower body portion 20 is advanced in the fourth lower adsorption rod 140 is stopped.

As shown, the first forward means 50, the first pinion gear 51 is installed in the upper body portion 10 and rotated by the first drive means (M1), and the first upper suction rod The first rack gear 52 formed integrally with the 30 is formed in pairs with each other, and the second forward means part 60 is provided in the lower body part 10 and is rotated by the driving means. 61 and the second rack gear 62 formed integrally with the second upper suction rod 30 are preferably paired with each other.

In addition, the rotation means 70, the first bevel gear 71 and the upper body portion 10 or the lower body portion 20 provided in one of the upper body portion 10 or the lower body portion 20. A second bevel gear 72 installed in a place where the first bevel gear 71 is not installed and operating in pair with the first bevel gear 71; and the first bevel gear 71 or the second bevel gear 71; It is preferable to include a second drive means (M2) for rotating the bevel gear (72).

Hereinafter, a forward rotation method of an adsorption mobile cleaning robot for a solar cell module will be described.

Forward way

First, the first vacuum adsorption plate 32 in the state in which the first elevating rod 31 is lowered in step S10 is adsorbed on the solar panel. (Adsorption of the first upper adsorption rod 30)

In operation S20, the second pinion gear 61 of the second forward means 60 is reversely rotated while the second lifting bar 42 is lifted and the second vacuum suction plate 42 is detached. Advances 40 (the second lower adsorption rod 40 advances).

The lifting rods 31 and 41 are advanced by separate lifting means attached to each lifting rod. Lifting (expanding) techniques well known before the application of the present invention that can stretch the vertically elongated separated assembled objects are included in the scope of the present invention. For example, in the present invention, the lifting rod is composed of a cylinder (upper) and a piston (lower), and the lifting means is a pneumatic controller, and the expansion and contraction of the lifting rod can be made due to the expansion and contraction of the piston (lower lifting bar) by pneumatic pressure. .

In step S30, the second vacuum adsorption plate 42 is adsorbed on the solar panel after the second lifting bar 32 of the second lower adsorption rod 40 is lowered. Adsorption of the adsorption plates 32 and 42 is made by the control valve 80 and the vacuum pump 90 and controlled by the control unit 95 (suction of the second lower adsorption rod 40).

In operation S40, the first pinion gear 51 of the first forward means 50 is reversely rotated or the second pinion gear 61 of the second forward means 60 is rotated forward so that the robot body 10, 20 advances (the robot body 10, 20 advances).

In the present invention, it is preferable that the robot body portions 10 and 20 move forward in the state where both the first upper suction rod 30 and the second lower suction rod 40 are attached as described above. In the detached state, the robot body parts 10 and 20 may move forward or backward in the other adsorption fixed fixed adsorption bob.

In step S50, the first vacuum suction plate 32 of the first upper suction rod 30 behind is detached and the first lifting rod 31 is raised. In operation S50, the first pinion gear 51 of the first forward means 50 is rotated forward while the first lifting bar 32 is lifted up and the first vacuum suction plate 32 is detached. Advance 30.

Rotation way

When one of the first upper adsorption rods 30 or the second lower adsorption rods 40 is attached and the other one is detached, the rotating means unit 70 operates, and the adsorption rods in the detached state and the adsorption The robot body with the rod is rotated.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, but on the contrary, ≪ RTI ID = 0.0 > and / or < / RTI >

It is to be understood that the appended claims are intended to supplement the understanding of the invention and should not be construed as limiting the scope of the appended claims.

10: upper body portion 20: lower body portion
30: first upper adsorption rod 31: first lifting bar
32: first vacuum adsorption plate 40: second lower adsorption rod
41 second lifting bar 42: second vacuum suction plate
50: first forward means 51: first pinion gear
52: first rack gear 60: second forward means
61: first pinion gear 62: second rack gear
70: rotation means 71: first bevel gear
72: second bevel gear 80: control valve
90: vacuum pump 95: control unit
M1: first drive means M2: second drive means

Claims (5)

An upper body portion 10 of the robot;
A lower body portion 20 of the robot rotatably coupled to the lower portion of the upper body portion 10;
Coupled to the upper body portion 10 so as to move forward and backward, the first lifting bar 31 is provided perpendicular to both sides, each of the first vacuum suction plate (32) at the lower end of the first lifting bar (31) The first upper suction rod 30 is provided;
Coupled to the lower body portion 20 so as to move forward and backward, the second lifting bar 41 is provided perpendicular to both sides, the second vacuum suction plate 42 at the lower end of the second lifting bar 41, respectively It is provided with a second lower adsorption rod (40);
The first upper suction rod 30 is coupled to the first upper suction rod 30 and the upper body portion 10 to move the first upper suction rod 30 in a state where the upper body portion 10 is stopped, or the first upper suction rod 30. A first forward means part 50 for advancing the upper body part 10 in the stopped state;
Coupled to the second lower suction rod 40 and the lower body portion 20 to advance the second lower suction rod 40 or the second lower suction rod 40 in a state where the lower body portion 20 is stopped. A second forward means part 60 for advancing the lower body part 20 in this stopped state;
The lower body portion 20 is coupled to the upper body portion 10 of the robot and the lower body portion 20 of the robot to rotate the lower body portion 20 while the upper body portion 10 is stopped. Rotating means 70 for rotating the upper body portion 10 in the stopped state;
Adsorption of the first vacuum suction plate 32 and the second vacuum suction plate 42 by opening and closing the pneumatic path from the vacuum pump 90 to the first vacuum suction plate 32 and the second vacuum suction plate 42. A control valve 80 for controlling detachment;
A vacuum pump (90) for providing a vacuum state to the first vacuum suction plate (32) or the second vacuum suction plate (42) when the control valve unit (80) is opened;
And a control unit (95) for controlling the opening and closing of the control valve (80). The method of claim 1,
Coupled to the upper body portion 10 so as to be moved forward and backward, and are provided with a third elevating rod 131 perpendicular to both sides, the third vacuum suction plate 132 at the lower end of the third elevating rod 131, respectively It is provided with a third upper adsorption rod (130);
It is coupled to the lower body portion 20 forward and backward, and provided with a fourth lifting bar 141 perpendicular to both sides, each of the fourth vacuum suction plate 142 at the lower end of the fourth lifting bar 141 A fourth lower adsorption rod 140 provided therein;
Coupled to the third upper adsorption rod 130 and the upper body portion 10 to advance the third upper adsorption rod 130 in a state where the upper body portion 10 is stopped or the third upper adsorption rod 130 A third forward means part 150 for advancing the upper body part 10 in the stopped state;
The fourth lower suction bar 140 is coupled to the lower lower body part 20 and the lower lower body part 20 is stopped to move the fourth lower suction bar 140 or the fourth lower suction bar 140. The adsorption mobile cleaning robot for a solar cell module, characterized in that it further comprises; a fourth forward means 160 for advancing the lower body portion 20 in the stopped state. The method of claim 2,
The first upper adsorption rod 30 and the third upper adsorption rod 130 are horizontally spaced apart from each other and operate the same at the same time,
The second lower adsorption rod 40 and the fourth lower adsorption rod 140 are horizontally spaced apart from each other and are operated at the same time as the solar cell module adsorptive mobile cleaning robot. The method of claim 1,
The first forward means 50 is provided on the upper body portion 10 and the first pinion gear 51 rotated by the first driving means M1 and the first upper suction rod 30. The first rack gear 52 integrally formed in pairs with each other,

The second forward means 60 is a second pinion gear 61 installed in the lower body portion 10 and rotated by a driving means, and a second formed integrally with the second upper suction rod 30. Adsorption mobile cleaning robot for solar cell module, characterized in that the rack gear 62 is formed in pairs with each other. The method of claim 1,
The rotating means portion 70,
A first bevel gear 71 provided on one of the upper body portion 10 and the lower body portion 20;
The second bevel gear 72 is installed in the upper body portion 10 or the lower body portion 20 where the first bevel gear 71 is not installed and operates in pair with the first bevel gear 71. Wow,
And a second driving unit (M2) for rotating the first bevel gear (71) or the second bevel gear (72).

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