KR20100094606A - Simulation apparatus for sun location tracking type solar generation - Google Patents

Abstract

PURPOSE: A simulation apparatus for tracking solar light is provided to perform a solar tracking experiment at night by including a replica sun and a solar panel which generates power by tracking light radiated from the replica sun. CONSTITUTION: An arch shaped rail(120) is installed on a base(110). A replica sun(130) moves along the arch shaped rail and emits light toward the upper side of the base. A solar panel(140) receives the light at the lower side of the arch shaped rail and generates power. A driving unit(150) supports the solar panel at the lower side of the arch shaped rail and rotates the solar panel based on the X-axis and the Y-axis.

Description

Simulation apparatus for sun location tracking type solar generation}

The present invention relates to a solar tracking power generation simulation device, and more specifically, to simulate the sun moving along the arched rail and a solar panel for tracking the light emitted from the simulation sun to produce power, even at night or indoors The present invention relates to a solar tracking power generation simulation apparatus that can test solar tracking power generation.

Photovoltaic power generation is a power generation technology using a solar panel that receives electricity to generate electricity by the photoelectric effect, and is a power generation technology that converts sunlight into electrical energy.

In addition, solar power generation uses the unlimited energy source of the sun and has no advantage of emitting pollutants, and according to the demand of environmental protection, technological development is rapidly progressing along with clean energy generation such as solar power generation and wind power generation. It is the power generation technology being done.

However, photovoltaic power generation requires a large solar panel due to a large dependence on the amount of insolation in the power generation and a low energy density, and thus has limited installation places and a large initial investment cost.

In recent years, solar tracking power generation technology has been developed that can improve the efficiency of photovoltaic power generation by generating power by tracking the incident direction of photovoltaic solar panels. The power generation efficiency is improved by about 15% over photovoltaic power generation.

In addition to the development of the solar tracking power generation technology, the solar tracking power generation technology can be simulated to test the power generation efficiency of the solar tracking power generation and the accuracy of the solar tracking of the solar panel, thereby improving the solar tracking power generation technology. There has been a need for a power generation simulator.

In order to improve the power generation efficiency of the solar tracking power generation, the present inventors have conducted research on a simulation apparatus that can test the power generation efficiency of the solar tracking power generation and the accuracy of the solar tracking. The present invention has been completed by developing a technical configuration capable of experimenting with solar tracking power generation indoors.

Accordingly, it is an object of the present invention to provide a solar tracking power generation simulation apparatus that can test solar tracking power generation.

In addition, another object of the present invention is to provide a solar tracking power generation simulation apparatus that can test the solar tracking power generation irrespective of whether the sunlight is incident, the amount of incident, the experimental place.

The objects of the present invention are not limited to the above-mentioned objects, and other objects that are not mentioned will be clearly understood by those skilled in the art from the following description.

In order to achieve the above object, the present invention provides a base, an arched rail installed on the base, a simulated sun moving along the arched rail and emitting light toward an upper portion of the base, and the light at the bottom of the arched rail. Is attached on the solar panel and the base to receive power, and supports the solar panel on the lower portion of the arched rail, and rotates the solar panel about the y-axis or the x-axis, so that the solar panel is It provides a solar tracking power generation simulation apparatus including a drive member for tracking the light emission direction of the light to produce power.

In a preferred embodiment, the drive member is connected to the y-axis drive unit including a first drive motor having a rotation axis is provided on the y axis and the rotation axis of the first drive motor, rotates about the y axis, the rotation axis And an x-axis driving unit including a second driving motor provided on the x-axis, wherein the solar panel is coupled to a rotation axis of the second driving motor to rotate about the x-axis or the y-axis.

In a preferred embodiment, both ends of the arcuate rail are pin-coupled respectively to a predetermined portion of the base, each pin-coupling about an imaginary linear axis of rotation parallel to the base, and the simulated aspect by the rotation of the arcuate rail The altitude, which is the angle of the base, is adjusted.

In a preferred embodiment, it further comprises a third drive motor provided on the base or the arcuate rail with a rotation axis on the virtual linear axis of rotation, and to rotate the arcuate rail about the virtual linear axis of rotation.

In the preferred embodiment, the arcuate rail is provided at one end of the arcuate rail, the first belt pulley to rotate about a first axis of rotation perpendicular to the virtual linear axis of rotation, parallel to the base of the arcuate rail It is provided at the other end and is connected to the second belt pulley and the belt pulleys that are perpendicular to the virtual straight axis of rotation and rotate about a second axis of rotation parallel to the base, and move along the arcuate rail in left and right directions. And a conveyor belt, wherein the simulation aspect is fixed to a portion of the conveyor belt and moves along the arced rail by the movement of the conveyor belt to emit light.

In a preferred embodiment, the arc rail further comprises a fourth drive motor for rotating the first belt pulley or the second belt pulley to move the conveyor belt.

In a preferred embodiment, the simulated embodiment is provided with a halogen lamp.

In a preferred embodiment, it further comprises an optical sensor module provided on the solar panel, detecting the light emission direction of the light, the drive member is driven.

The present invention has the following excellent effects.

First, according to the solar tracking power generation simulation apparatus of the present invention, it is possible to show the development process of the actual solar tracking power generation by having a simulated sun and a solar panel tracking the simulated sun moving similarly to the movement trajectory of the sun. Since the power generation efficiency of the light tracking power generation can be tested, there is an effect to improve the solar tracking power generation technology.

In addition, according to the solar tracking power generation simulation apparatus of the present invention, since the simulated sun uses a halogen lamp that moves similarly to the sun's movement trajectory, the solar tracking power generation is performed regardless of whether or not the actual sunlight is incident. There is a testable effect.

The terms used in the present invention were selected as general terms as widely used as possible, but in some cases, the terms arbitrarily selected by the applicant are included. In this case, the meanings described or used in the detailed description of the present invention are considered, rather than simply the names of the terms. The meaning should be grasped.

Hereinafter, the technical structure of the present invention will be described in detail with reference to preferred embodiments shown in the accompanying drawings.

However, the present invention is not limited to the embodiments described herein but may be embodied in other forms. Like reference numerals designate like elements throughout the specification.

1 is a view showing a solar tracking power generation simulation apparatus according to an embodiment of the present invention, Figure 2 is an enlarged view of the simulation sun of a solar tracking power generation simulation apparatus according to an embodiment of the present invention, 3 is a view for explaining the driving of the simulation sun of the solar tracking power generation simulation apparatus according to an embodiment of the present invention.

Referring to the drawings, the solar tracking power generation simulation apparatus 100 according to an embodiment of the present invention is the base 110, the arch rail 120, the simulated sun 130, the solar panel 140 and the driving member 150 )

The base 110 defines the bottom of the solar tracking power generation simulation apparatus 100 according to an embodiment of the present invention, the arched rail 120, the simulation sun 130, the solar panel 140 And the driving member 150.

The arc rail 120 is installed on the base 110, and becomes a movement path of the simulated sun 130 to be described below, and corresponds to the ecliptic trajectory of the actual sun.

In addition, both ends of the arched rail 120 is coupled to a predetermined portion of the base 110.

In more detail, both ends of the arcuate rail 120 are respectively pin-coupled to two opposite edges of the base 110 about an imaginary linear rotation axis (a) parallel to the upper surface of the base 110, the virtual It rotates about the linear axis of rotation (a).

In addition, at both edges of the base 110 to which the arcuate rail 120 pins, pin coupling portions 111 and 111a are formed, each of which pin holes are perforated along the virtual linear rotation axis a. Both ends of the arcuate rail 120 are pin-coupled to the pin coupling portions 111 and 111a, respectively.

However, both ends of the arcuate rail 120 may be coupled to the base 110 by any coupling method if the arcuate rail 120 can rotate about the virtual straight axis of rotation (a).

That is, the arc rail 120 is rotated about the virtual straight axis of rotation (a) to adjust the angle (d) with the base 110, the angle (d) with the base 110 is the actual sun Corresponds to altitude.

In addition, a third driving motor for rotating the arcuate rail 120 is provided in the pin coupling portion (111a) of the pin coupling portion (111, 111a) is provided on the virtual linear rotation axis (a) 160 is provided.

Therefore, the experimenter can automatically rotate the arcuate rail 120 by using the third drive motor 160.

However, the third driving motor 160 may be provided on the arcuate rail 120 to rotate the arcuate rail 120.

That is, if the third drive motor 160 can rotate the arcuate rail 120 with the rotation axis on the virtual straight axis of rotation (a), either the base 110 or the arcuate rail 120 It may also be provided.

In addition, the arcuate rail 120 is provided at one end of the arcuate rail 120 and is perpendicular to the virtual straight axis of rotation a, and centers around a first axis of rotation b that is parallel to the top surface of the base 110. A second rotation shaft c provided at the other end of the first belt pulley 121 and the arcuate rail 120 that rotates in a direction perpendicular to the virtual linear rotation axis a and parallel to the upper surface of the base 110. It has a second belt pulley 122 that rotates about.

In addition, the arched rail 120 is connected to the belt pulleys (121, 122) is connected, and further comprises a conveyor belt 123 moving along the arched rail (120).

In more detail, the conveyor belt 123 moves in the left and right direction inside the arched rail 120, and is connected to the simulated sun 130 to be described below to connect the simulated sun 130 to the arched rail 120. Move along).

The arcuate rail 120 further includes a fourth drive motor 124 rotating the first belt pulley 121 to move the conveyor belt 123 with the rotation shaft on the first rotation shaft b. Equipped.

However, the fourth driving motor 124 may move the conveyor belt 123 by rotating the second belt pulley 122 with the rotation shaft on the second rotation shaft c.

The simulated sun 130 moves along the arched rail 120 and emits light toward the top of the base 110.

In addition, the simulated sun 130 supports a halogen lamp 131 that emits light and the halogen lamp 131 on the arched rail 120, and a slider 133 sliding along the arced rail 120. And a belt fixing member 132 that fixes the slider 133 to the conveyor belt 123.

That is, the simulated sun 130 moves along the arched rail 120 in the same manner as the movement of the actual sun and emits light.

The solar panel 140 receives power emitted from the simulated sun 130 to produce power.

In addition, the solar panel 140 tracks the simulated sun 130 by moving the upper surface toward the light emitting direction of the light by the driving member 150 to be described below.

In addition, the upper surface of the solar panel 140 is provided with an optical sensor module 141 for detecting the light emitting direction of the light, the optical sensor module 141 is the solar panel 140 is the light emission of the light The driving member 150 is driven to face the direction.

The driving member 150 is attached to the center of the upper surface of the base 110 to support the solar panel 140, and to cause the solar panel 140 to rotate around the x-axis or y-axis.

In addition, the driving member 150 rotates about the x-axis or the y-axis so that the top surface of the solar panel 140 faces the light emission direction of the light detected by the optical sensor module 141.

In other words, the driving member 150 serves to enable the solar panel 140 to produce power by tracking the movement of the simulated sun 130.

In addition, the driving member 150 includes a y-axis driver 151 for rotating the solar panel 140 about the y-axis and an x-axis driver 152 for rotating the solar panel 140 about the x-axis. It includes.

In addition, the y-axis drive unit 151 includes a first drive motor 151a that rotates on the y-axis with a rotation axis, and the x-axis drive unit 152 is provided with a rotation axis of the first drive motor 151a. A second drive motor 152a is coupled to rotate about the x axis and rotate about the rotation axis on the y axis.

In addition, the solar panel 140 is coupled to the rotation shaft of the second driving motor 152a.

That is, the solar panel 140 rotates on the y-axis and the x-axis by the first driving motor 151a and the second driving motor 152a, respectively, and tracks the simulated sun 130 to produce power. do.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is clearly understood that the same is by way of illustration and example only and is not to be taken by way of limitation, Various changes and modifications will be possible.

1 is a view showing a solar tracking power generation simulation apparatus according to an embodiment of the present invention,

Figure 2 is an enlarged view of the simulation sun of the solar tracking power generation simulation apparatus according to an embodiment of the present invention,

3 is a view for explaining the driving of the simulation sun of the solar tracking power generation simulation apparatus according to an embodiment of the present invention.

In the drawings according to the present invention, the same reference numerals are used for components having substantially the same configuration and function.

<Description of the symbols for the main parts of the drawings>

100: solar tracking simulation device 110: base

111, 111a: Pin coupling portion 120: Arched rail

121: first belt pulley 122: second belt pulley

123: conveyor belt 124: fourth drive motor

130: simulated sun 131: halogen lamp

132: belt fixing member 133: slider

140: solar panel 141: light sensor module

150: drive member 151: y-axis drive portion

151a: first drive motor 152: x-axis drive unit

152a: second drive motor 160: third drive motor

Claims (8)

Base; An arched rail installed on the base; A simulated sun moving along the arched rail and emitting light towards the top of the base; A solar panel receiving power from the lower part of the arched rail to produce electric power; And Attached to the base, supporting the solar panel at the bottom of the arched rail, and rotating the solar panel about the y-axis or the x-axis, the solar panel tracks the light emission direction and produces power Solar tracking power generation simulation device comprising; The method of claim 1, The drive member: A y axis driver including a first drive motor having a rotation axis provided on the y axis; And And an x-axis driver connected to a rotation axis of the first drive motor, rotating about the y axis, and including a second drive motor provided on the x axis. The solar panel is a solar tracking power generation simulation device, characterized in that coupled to the rotation axis of the second drive motor. The method according to claim 1 or 2, Both ends of the arcuate rail are pin-coupled to a predetermined portion of the base, respectively, the pins are coupled around an imaginary linear rotation axis parallel to the base, and the angle formed by the simulation sun and the base by the rotation of the arcuate rail. Solar tracking power generation simulation device, characterized in that the altitude is controlled. The method of claim 3, wherein And a third driving motor provided on the base or the arcuate rail with a rotation axis on the imaginary linear axis of rotation, and configured to rotate the arcuate rail about the imaginary linear axis of rotation. Power generation simulator. The method of claim 4, wherein The arched rail: silver A first belt pulley provided at one end of the arcuate rail and rotating about a first rotation axis parallel to the base and perpendicular to the virtual straight axis of rotation; A second belt pulley provided at the other end of the arched rail and rotating about a second rotational axis perpendicular to the virtual linear rotational axis and parallel to the base; And A belt connected to the belt pulleys, the conveyor belt moving in a lateral direction along the arch rail, The simulation sun is fixed to a portion of the conveyor belt is a solar tracking power generation simulation device, characterized in that moving along the arched rail by the movement of the conveyor belt. The method of claim 5, The arc-shaped rail further includes a fourth driving motor for rotating the first belt pulley or the second belt pulley to move the conveyor belt. The method of claim 3, wherein The solar tracking power generation simulation device, characterized in that the simulated sun is provided with a halogen lamp. The method of claim 3, wherein The solar tracking power generation simulation apparatus provided on the solar panel, further comprising an optical sensor module for detecting the light emitting direction of the light, the drive member is driven.

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