KR101766638B1 - Non-powered sunlight tracking device - Google Patents

Abstract

A housing through which light can pass, fixing means provided inside the housing, an axis passing through the housing along the extension direction of the housing, a shaft through which the heat mediating fluid can flow, A reflector that is connected to the first guide and is rotatable together with the first guide about the axis and reflects sunlight toward the axis; a reflector that is deformably fixed to the securing means and that has different heat transfer rates And a second guide for rotating the first guide according to a deformation amount of the bimetal.

Description

[0001] NON-POWERED SUNLIGHT TRACKING DEVICE [0002]

The present invention relates to a photovoltaic solar tracking device.

As fossil fuels become depleted and environmental pollution caused by fossil fuels becomes more and more serious, interest in environmentally friendly and semi-permanent renewable energy is increasing day by day. Solar power generation, wind power generation, and tidal power generation are examples of such eco-friendly energy. In particular, solar energy has a high thermal energy, so it is highly utilized.

Generally, solar energy is the energy that collects and uses sunlight by using lens or reflector. However, since the altitude angle and azimuth angle of the sun continuously change due to the rotation and rotation of the earth, it is necessary to continuously change the position of the concentrator that receives the sunlight according to the position of the sun. To this end, research is being conducted on a tracking device capable of tracking sunlight.

In order to improve the power generation efficiency, the tracking device is capable of adjusting the position of the reflector according to the movement of the sun. In the past, a device capable of adjusting the position of the reflector with electrical energy using a predetermined power transmission device has been used. A tracking device using bimetallic has been proposed.

Bimetallic refers to a thermal expansion coefficient, that is, a superposition of two kinds of thin metals with different degrees of expansion and contraction according to changes in temperature.

Patent Document 1 (Korean Patent No. 1412533) discloses a device capable of tracking sunlight using a bimetal. However, the apparatus disclosed in Patent Document 1 has a problem in that sunlight can not be continuously tracked due to the nature of the bimetal that returns to the original state if energy is not supplied. Specifically, the apparatus disclosed in Patent Document 1 traces sunlight and is deformed, then returns to the initial state, and after being deformed again, returns to the initial state.

Patent Document 1: Korean Patent No. 1412533 (registered on June 20, 2014)

Embodiments of the present invention have been proposed in order to solve the above-mentioned problems, and an object of the present invention is to provide a solar-powered solar tracking device capable of continuously tracking the sun using one axis.

Further, there is a need to provide a photovoltaic solar tracking device that can be installed and manufactured at low cost.

Further, there is a need to provide a non-power solar tracking device capable of enhancing operation reliability.

It is also intended to provide a non-powered solar tracking device that can be used extensively.

According to an embodiment of the present invention, there is provided a light emitting device comprising: a tubular housing through which light can pass; Fixing means provided inside the housing; An axis passing through the housing along an extension direction of the housing and provided with energy conversion means therein; A first guide rotatable about the axis; A reflector connected to the first guide and rotatable together with the first guide about the axis, the reflector reflecting sunlight toward the axis; A bimetal fixed to the fixing means so as to be deformable and formed of two metal plates having different heat transfer rates; And a second guide for rotating the first guide according to a deformation amount of the bimetal.

In addition, the bimetal extends in the axial extension direction, the center portion is fixed and the both ends are bent in the horizontal direction, and the second guide surrounds the bimetal, and the end of the bimetal is slidably movable inwardly And a head portion for applying an external force to the first guide in accordance with the movement of the hook portion.

The bimetal is fixed on the upper portion and the lower portion is bent in the horizontal direction. The second guide includes a rotating bar that is sandwiched between the pair of bimetals, and a head portion where both sides of the rotating bar are bent and formed downward A photovoltaic solar tracking device can be provided.

In addition, the first guide may include a wing portion to which a head portion of the second guide is connected and fixed.

The wing portion may have a concave shape toward the reflection portion, and the back surface of the wing portion may be formed as an auxiliary reflection surface that reflects the light reflected by the reflection portion.

Also, the bimetal is fixed on the upper part, the lower part is bent in the horizontal direction and is spaced apart and provided with a pair, the second guide is connected to the bimetal, moves according to the movement of the bimetal, It is possible to provide a photovoltaic solar tracking device in which the first guide rotates in accordance with the movement.

In addition, the first guide may be a pulley having a constant groove, and the second guide may be a ball chain having a ball having a size corresponding to the groove of the pulley.

Also, a pair of the bimetals is provided, and among the two metal plates constituting the bimetal, an inner metal plate of the bimetal closer to the axis provides a thermal expansion coefficient that is higher than that of the outer metal plate of the bimetal remote from the axis. can do.

In addition, the bimetal can provide a photovoltaic solar tracking device in which the outer surface far from the axis is a blackbody surface, and the inner surface near the axis is a total reflection surface.

In addition, the second guide may provide a non-power solar tracking device that converts a linear motion of the bimetal into a rotational motion and transmits the rotational motion to the first guide.

The reflective portion may further include a main reflecting surface reflecting sunlight and a supporting portion for fixing the curvature and shape of the main reflecting surface.

Further, the housing may be a vacuum tube and may provide a photovoltaic solar tracking device.

Further, it is possible to provide a non-power solar tracking device including a bearing provided in a form of wrapping the shaft.

Further, a non-powered solar tracking device may be provided between the shaft and the bearing, further comprising a thermal insulation bushing for blocking thermal interference of the shaft.

Further, it is possible to provide a photovoltaic solar tracking device mounted on the first guide.

In addition, the energy conversion means may provide a non-powered solar tracking device that is a heat-mediated fluid flowing inside the shaft.

In addition, the energy conversion means may provide a non-powered solar tracking device that is a thermoelectric element provided inside the shaft.

The non-power solar tracking apparatus according to the embodiments of the present invention does not include a separate power supply apparatus, and has an effect of being able to operate without power.

In addition, since one axis is provided, there is an effect that the sun can be continuously tracked.

Further, since the installation is simplified, there is an effect that installation and manufacture can be performed at low cost.

In addition, since the bimetal is provided inside the sealed housing, it is not influenced by the external environment, so that the operation reliability can be improved.

In addition, there is an effect that the light collection ratio can be changed and widely used in various fields.

FIG. 1 is a perspective view showing a non-power solar tracking apparatus according to an embodiment of the present invention.
2 is a side view of Fig.
3 is an exploded perspective view of part A of Fig.
FIG. 4 is a view showing a state in which the non-power solar tracking apparatus of FIG. 1 operates in response to the change of the sun azimuth angle.
5 is a perspective view showing a photovoltaic solar tracking apparatus according to another embodiment of the present invention.
Fig. 6 is a side view of Fig. 5. Fig.
7 is an exploded perspective view of part B of Fig.
FIG. 8 is a view showing the non-power solar tracking apparatus of FIG. 5 operating in response to the change of the sun azimuth angle.
FIG. 9 is a perspective view showing a photovoltaic solar tracking apparatus according to another embodiment of the present invention. FIG.
10 is a side cross-sectional view taken along the ball chain of FIG.
11 is a partially enlarged perspective view of the ball chain and pulley of Fig.
Fig. 12 is a side view of Fig. 11. Fig.
13 is a cross-sectional view showing the configuration of the pulley of Fig.
FIG. 14 is a view showing the non-power source solar tracking device of FIG. 9 operating in response to a change of the sun azimuth angle.
15 is a graph showing a comparison between a solar collector and a conventional solar collector according to an embodiment of the present invention.

Hereinafter, specific embodiments of the present invention will be described in detail with reference to the drawings.

In the following description of the present invention, detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear.

FIG. 1 is a perspective view showing a photovoltaic solar tracking apparatus according to an embodiment of the present invention, FIG. 2 is a side view of FIG. 1, and FIG. 3 is an exploded perspective view of a portion A of FIG.

1 to 3, a non-powered solar tracking apparatus 10 according to an embodiment of the present invention includes a tubular housing 100 through which light can pass, And a shaft 120 passing through the bottom surface of the housing 100 (in the x-axis direction in FIG. 1) and passing through the heat transfer fluid or thermoelectric elements, A reflection unit 140 connected to the first guide 130 and rotatable about the shaft 120 and a second guide 130 connected to the fixing unit 110. The first guide 130 is rotatable around the axis 120, And a second guide 160 for rotating the first guide 130 in accordance with the amount of deformation of the bimetal 150.

The housing 100 is formed of a transparent material through which light can pass and can provide a controlled environment. For example, the housing 100 may be a vacuum tube and may be cylindrical with two undersides. When the housing 100 is provided as a vacuum tube, the inside of the housing 100 may not be influenced by the external environment such as air temperature, air pressure, and humidity.

The fixing means 110 is provided inside the housing 100 to position the bimetal 150 at a predetermined position inside the housing 100. The fastening means 110 may comprise a frame 111 which may be secured to the inner surface of the housing 100 and at least one extension 112 extending from the frame 111 towards the shaft 120, And a fixing portion 113 provided at an end of the bimetal portion 112 and to which the bimetal 150 can be fixed. At this time, the fixing portion 113 may further include a fastening hole 114 for connection with the bimetal 150. [ Further, the fixing portion 113 may be shorter than the frame 111.

The frame 111 is connected to the rectilinear section 111 and is formed to correspond to the sectional shape of the housing 100 and is connected to the housing 100. The rectilinear section 111a extends in the extension direction of the housing 100, And a ring portion 111b which is in close contact with the inner surface of the base portion 100a.

The frame 111, the extension 112, and the fixing portion 114 may be integrally formed, and the shape of the fixing means 110 is not limited thereto. For example, the frame 111, the extension 112 and the fixing portion 114 may be separately provided and connected to each other, and the ring portion 111b may be omitted or the fixing portion 113 may be omitted, 112 may be connected to the bimetal 150 directly, or may have a structure other than the structure illustrated in this embodiment.

The shaft 120 may pass through the center of the bottom surface of the housing 100 in the X-axis direction, and may have a constant thickness. At this time, the shaft 120 may have a hollow inside to allow the flow of the heat mediating fluid, and may extend to the outside through the housing 110.

The heat-transfer fluid flows into the shaft 120 and can be heated by absorbing the sunlight. Alternatively, a thermoelectric element may be disposed inside the shaft 120, and a predetermined pipe for cooling the thermoelectric element may be additionally provided, so that the thermoelectric element may be heated by absorbing and heating the sun light. In this embodiment, the heat-mediating fluid flows inside the shaft 120 as an example.

Here, the heat transfer medium flowing inside the shaft 120 or the thermoelectric element provided inside the shaft 120 accumulates or generates predetermined energy by absorbing sunlight, and can be said to be an energy conversion means. That is, the energy conversion means is provided inside the shaft 120.

The first guide 130 may be provided to be rotatable around the axis 120 and transmits the movement of the bimetal 150 to the reflection unit 140 to rotate the reflection unit 140. Here, the bearing 170 may be formed under the first guide 130 for smooth rotation of the first guide 130. The bearing 170 may be formed to be fitted to the shaft 120 and a thermal insulation bushing 180 is provided between the shaft 120 and the bearing 170 to block thermal interference of the shaft 120 . The bearing 170 is connected to the reflecting portion 140 and the first guide 130 is connected to the reflecting portion 140. The bearing 170 is connected to the first guide 130, As shown in FIG. That is, the bearing 170 is provided so that the first guide 130 and the reflecting portion 140 can be smoothly rotated about the shaft 120.

The first guide 130 is disposed between the shaft 120 and the bimetal 150 and the second guide 160 and rotates around the axis 120 by an external force applied from the second guide 160. [ . The first guide 130 and the reflector 140 are directly or indirectly connected to each other. When the first guide 130 is rotated, the reflector 140 may be rotated together.

The first guide 130 may have a shape in which a head portion 162 of a second guide 160 to be described later can be fitted. Can be rotated. For example, the first guide 130 may include a pair of wings 131 extending in both directions from the shaft 120, and a valley 134 may be provided between the wings 131 have. That is, the first guide 130 may be formed in a shape similar to a '3' character.

The pair of wing portions 131 may have a curved shape concave toward the reflecting portion 140. The upper surface of the first guide 130 serves as a contact surface that interlocks with the second guide 160. The lower surface of the first guide 130 functions as an auxiliary reflecting surface for reflecting the light reflected from the reflecting portion 140 again. (132). In this case, the light condensing efficiency can be further increased through the concave auxiliary reflecting surface 132.

Here, the first guide 130 may be formed to have a relatively small size as compared with the reflector 140, so that the reflector 140 can be largely rotated even if the bimetal 150 is deformed to a small extent.

The first guide 130 may be provided with a weight 133 for weighting the first guide 130 with respect to the axis 120. Even if only a weak force is applied from the second guide 160 due to the provision of the weight 133, a large moment may be generated on the first guide 130 side, so that the reflector 140 can be easily rotated.

The reflector 140 may be connected to the first guide 130 to be rotatable about the axis 120. The reflecting portion 140 may include a main reflecting surface 141 that reflects sunlight toward the shaft 120 and a supporting portion 142 that supports the main reflecting surface 141. The main reflecting surface 141 may be concave toward the axis 120 and the supporting portion 142 may have a fan-shaped cross-section having a constant central angle so as to fix the curvature and shape of the reflecting portion 140 . At this time, the curvature of the main reflecting surface 141 can be changed according to the angle of the supporting portion 142. [

The bimetal 150 can be deformably fixed to the fixing means 110. In this case, the bimetal 150 is formed of two metal plates having different heat transfer rates. The bimetal 150 may have a rectangular cross-section, and may have a rectangular cross-section, for example, longer in the X-axis direction.

In the present embodiment, the pair of bimetals 150 are arranged so that the surfaces for absorbing the sunlight are directed to the outside, respectively. In this case, there is an advantage that the bimetal can react even if the sunlight is reflected from either side.

The pair of bimetals 150 may be fixed to the fixing means 110 by means of a fastening means 151 such as a bolt or may be connected to each other. And may include a further fastening hole 152. In the present embodiment, four bite holes 152 are formed in the bimetal 150, but the present invention is not limited thereto.

Specifically, the fastening holes 152 at both ends of the bimetal 150 can be used to couple the pair of bimetals 150 to one another. And the bimetal 150 may be used to couple the bimetal 150 to the fixing means 110. The fastening means 151 may be but is not limited to a washer, a sleeve, and a bolt and a nut.

Here, the bimetal 150 may be disposed such that the metal plate having a larger coefficient of thermal expansion faces the center side, that is, the side of the fixed portion 113. As a result, when the bimetal 150 absorbs and deforms thermal energy, it can be bent toward the direction in which sunlight is provided.

The surface facing the outside of the bimetal 150 may be a low reflective black body by a technique such as titanium vacuum deposition to absorb solar light well, and the rear surface may be a surface capable of total internal reflection, for example, a mirror. That is, when the bimetals 150 are provided as a pair, the facing inner surface of the bimetal 150 may be a total reflection surface. The total reflection surface can prevent mutual thermal interference due to radiation between the pair of bimetals 150. In the present embodiment, the inner surface of the bimetal 150 is formed as a total reflection surface, but the spirit of the present invention is not limited thereto. For example, a highly elastic heat insulator may be provided between the pair of bimetals 150 to block heat transfer.

The bimetal 150 is bent as it absorbs solar heat. Specifically, since the outer surface of the bimetal 150, that is, the surface subjected to the black body treatment, can absorb sunlight well, the amount of deformation of the bimetal 150 can be increased. As the sunlight is absorbed, the bimetal 150 is bent according to the difference in the thermal expansion coefficients of the two metals forming the bimetal 150. At this time, the bimetal 150 is bent toward the sunlight because the metal plate having a larger coefficient of thermal expansion is disposed toward the central side, that is, toward the fixing portion 113.

In this embodiment, the bimetals 150 are provided as a pair. When the sunlight is irradiated toward one of the pair of bimetals 150, the other bimetal 150b absorbs energy well It is not thermally expanded, or it is thermally expanded only by a relatively small amount. In this case, since the other bimetal 150b is connected to the bimetal 150a by the coupling means 151, the other bimetal 150b is deformed together with the deformation of the bimetal 150a.

In this embodiment, the bimetal 150 is provided in such a manner that the length in the same direction (X-axis direction) as the extending direction of the shaft 120 is longer than the length in the other direction (Z-axis direction). In addition, since the central portion of the bimetal 150 is fixed to the fixing portion 113, the bimetal 150 can be bent at both ends in the horizontal direction with respect to the central portion.

The second guide 160 can rotate the first guide 130 according to the deformation amount of the bimetal 150. The bimetal 150 is fixed to the fixing means 110 and bent. The second guide 160 may be configured to rotate together with the degree of bending of the bimetal 150. 2, the second guide 160 converts the linear motion of the bimetal 150 into rotational motion and transmits the linear motion to the first guide 130 It can be cam. At this time, the second guide 160 may be made of a Teflon material having a low thermal conductivity and high heat resistance, but is not limited thereto.

The second guide 160 is directly connected to the bimetal 130 so that the first guide 130 is rotated in accordance with the change of the bimetal 130. The second guide 160 is connected to the bimetal 130 and the first guide 130 Structure. Accordingly, the second guide 160 may be provided on the upper portion of the first guide 130 and interlocked with the bimetal 130.

The second guide 160 includes a ring portion 161 surrounding the bimetal 150 and a head portion 162 contacting the first guide 130 to rotate the first guide 130 can do. At this time, the head portion 162 may have a shape corresponding to the top surface shape of the first guide 130 so that the second guide 160 is interlocked with the first guide 130. In detail, the head portion 162 is connected to the first guide 130 and rotated together with the first guide 130. For example, when the first guide 130 has a pair of wing portions 131, the head portion 162 may be formed in a wedge shape to be fitted in the valley portion 134, The wing portion 131 can be adhered and fixed.

The annular portion 161 is rotated as the bimetal 150 is bent and the center of rotation can be a contact portion between the head portion 162 and the first guide 130. [ In detail, the annular portion 161 may be formed in an elliptic shape or a cam shape having a predetermined curvature and may be fitted in a form to surround the bimetal 150. When the bimetal 150 is bent, the corner portion of the bimetal 150 pushes the inner side surface of the ring portion 161, so that the tangential direction (the left-right direction in FIG. 2) An external force is applied. Since the head portion 162 is connected to the first guide 130, such an external force acts as a moment for rotating the entire first guide 130. The bimetal 150 is slid along the inner surface of the ring 161 when the bimetal 150 is bent and the first guide 130 is rotated about the contact portion between the head portion 162 and the first guide 130 as a whole do.

Although the method of fixing the head portion 162 to the valley portion 134 of the first guide 130 is described as an example in the present embodiment, the method of joining the second guide 160 and the first guide 130 But is not limited thereto. For example, the lower portion of the second guide 160 may be fitted and fixed to a part of the first guide 130.

FIG. 4 is a view showing a state in which the non-power solar tracking apparatus of FIG. 1 operates in response to the change of the sun azimuth angle.

Fig. 4 (a) is a side view of the solar tracking device, and Fig. 4 (b) is a plan view of the solar tracking device. Referring to FIG. 4, the shape of the bimetal 150 and the states of the first guide 130, the reflector 140, and the second guide 160 according to the change of the position of the sun can be confirmed.

Specifically, the solar tracking device 10 is arranged such that the sun is located at one side of the solar tracking device 10 in the morning and the sun is positioned at the other side of the solar tracking device 10 in the afternoon, . In the present embodiment, the sun is located on the left side of the solar tracking device 10 in the morning and the sun is located on the right side in the afternoon.

The bimetal 150 can be turned toward the direction of the sun. Specifically, as described above, the bimetals 150 can be provided in pairs, and the metal plates 150 having a large coefficient of thermal expansion can be disposed inside the bimetals 150. That is, And is therefore bent toward the sunlight.

In addition, when sunlight is irradiated toward one of the pair of bimetals 150, the other bimetal 150b does not absorb energy, and therefore, it is not thermally expanded or only a relatively small amount And is thermally expanded. In this case, since the other bimetal 150b is connected to the bimetal 150a by the coupling means 151, the other bimetal 150b is deformed together with the deformation of the bimetal 150a.

Before the sunrise, the bimetal 150 is not thermally expanded by the sunlight, so that the state as shown at noon in FIG. 4 is maintained.

Since the sun is located on the left side of the housing 100 in the morning, any one of the bimetals 150a can absorb the sunlight better, and the entire bimetal 150 is bent concavely in the leftward direction toward the sun .

The second guide 160 is connected to both ends of the bimetal 150 and the bimetal 150 pushes the ring 162 of the second guide 160 to rotate the second guide 160. As a result, The first guide 130 coupled to the second guide 160 and the first guide 130 coupled to the second guide 160 and the reflector 140 move along the axis 120, As shown in FIG. That is, when the bimetal 150 is bent to the left, the first guide 130, the second guide 160, and the reflecting portion 140 are rotated counterclockwise. Thereby, the main reflecting surface 141 of the reflecting portion 140 can be positioned toward the sun.

As the sun goes down at noon, the altitude of the sun gradually increases, and the angle of incidence of sunlight incident on any one of the bimetals 150a becomes smaller. That is, since the amount of heat transferred to one of the bimetals 150a is reduced, the thermal expansion of one of the bimetals 150a gradually decreases. Accordingly, the angle of rotation of the reflecting portion 140 is also reduced.

At noon, the sun supplies the same energy to both bimetals 150a and 150b, so that the bimetal 150 having the same thermal expansion amount of the bimetals 150a and 150b is not bent in any direction, The portion 140 can be directed upward.

In the afternoon, since the sun is located on the right side of the housing 100, any one of the bimetals 150b can absorb the sunlight better, so that the entire bimetal 150 is concave toward the sun in the right direction .

The second guide 160 is connected to both ends of the bimetal 150 and the bimetal 150 pushes the ring 162 of the second guide 160 to rotate the second guide 160. As a result, The first guide 130 coupled to the second guide 160 and the first guide 130 coupled to the second guide 160 and the reflector 140 move along the axis 120, As shown in FIG. That is, when the bimetal 150 is bent to the right, the first guide 130, the second guide 160, and the reflecting portion 140 are rotated clockwise. Thereby, the main reflecting surface 141 of the reflecting portion 140 can be positioned toward the sun.

The above description is ideally generated when the sensitivity of the bimetal 150 is extremely excellent. In fact, since it takes time for the bimetal 150 to absorb the energy transmitted from the sun and thermally expand, This may work in a somewhat late fashion. In this case, the reflector 140 may be rotated clockwise around the center of the first guide 130 and a virtual line passing through the center of the axis 120 to increase the light-condensing efficiency.

The photovoltaic solar tracking apparatus 10 according to the embodiment of the present invention does not include a separate power supply unit but includes a first guide 130 and a reflection unit 140 according to the bending direction of the bimetal 150, And the second guide 160 are rotated, so that there is an effect that operation can be performed with no force.

In addition, since the first guide 130, the second guide 160, and the reflector 140 are connected to the one shaft 120 and rotate, the sun can be continuously tracked.

In addition, since one shaft 120 is provided to simplify installation, it is possible to install and manufacture at low cost.

In addition, since the bimetal 150 is provided inside the sealed housing 100, it is not influenced by the external environment, and thus it is advantageous in that the operational reliability can be enhanced.

Further, there is an effect that the angle of the reflection part 140 is adjusted to change the light collection ratio and thus it can be widely used in various fields.

Hereinafter, a non-power solar tracking apparatus according to another embodiment of the present invention will be described with reference to FIGS. 5 to 8. FIG. However, the second embodiment differs from the first embodiment in terms of the connection between the bimetal and the second guide, so that differences will be mainly described. In the following description, the detailed description of the components is omitted for avoiding redundant description. If necessary, the reference numerals of the reference numerals are replaced with 2, 3, and 4, respectively. For example, the housing of the non-powered solar tracking device 20 corresponding to the housing 100 of the non-powered solar tracking device 10 may be represented by reference numeral 200. For example, the non-powered solar tracking device 20 includes a housing 200, a fixing means 210, a shaft 220, a first guide 230, a reflector 240, a bimetal 250, (260), a bearing (270), and a heat insulating bushing (280).

FIG. 5 is a perspective view illustrating a photovoltaic solar tracking apparatus according to another embodiment of the present invention, FIG. 6 is a side view of FIG. 5, and FIG. 7 is an exploded perspective view of a portion B of FIG.

5 to 7, a photovoltaic solar tracking apparatus 20 according to another embodiment of the present invention includes a tubular housing 200 through which light can pass, a fixing unit 200 provided inside the housing 200, A shaft 220 passing in a direction (x-axis direction in FIG. 5) passing through a bottom surface of the housing 200, A bimetal 250 fixed to the fixing unit 210 and a bimetal 250 fixed to the fixing unit 210. The bimetal 250 may include a first guide 230, And a second guide 260 for rotating the first guide 230 according to the amount of deformation of the second guide 250.

The bimetal 250 may be deformably fixed to the fixing means 210. In this case, the bimetal 250 is formed of two metal plates having different heat transfer ratios, and may have a rectangular cross-section, for example, a rectangular cross-section longer in the Z-axis direction.

In this embodiment, the pair of bimetals 250 are disposed so that the surface for absorbing sunlight is directed to the outside. In this case, there is an advantage that the bimetal can react even if the sunlight is reflected from either side.

The pair of bimetals 250 may be fixed to the fixing means 210 by a fastening means 251 such as a bolt or may be connected to each other. And may include a further fastening hole 252. In the present embodiment, four bite holes 252 are formed in the bimetal 250, but the present invention is not limited thereto.

Specifically, the fastening hole 252 on the upper side of the bimetal 250 is configured to correspond to the fastening hole 214 of the fastening means 210 and used to couple the bimetal 250 to the fastening means 210 . The fastening holes 252 on the lower side of the bimetal 250 may be used to couple the pair of bimetals 250 together. The fastening means 251 may be a washer, a sleeve, a bolt and a nut, but is not limited thereto.

Here, the bimetal 250 may be disposed such that the metal plate having a larger coefficient of thermal expansion faces the fixing portion 213 side. Thus, when the bimetal 250 absorbs and deforms the heat energy, the lower portion can be bent toward the direction in which sunlight is provided.

The bimetal 250 is bent as it absorbs solar heat. Specifically, the outer surface of the bimetal 250, that is, the surface subjected to the black body treatment, can absorb sunlight well, and therefore the amount of deformation of the bimetal 250 can be increased. As the sunlight is absorbed, the bimetal 250 is bent according to the difference in the thermal expansion coefficients of the two metals forming the bimetal 250. At this time, the bimetal 250 is bent toward the solar light because the metal plate having a larger coefficient of thermal expansion is disposed toward the fixing portion 213.

In this embodiment, since the upper portion of the bimetal 250 is fixed to the fixing portion 213, the lower portion of the bimetal 250 can be bent in the horizontal direction with respect to the upper portion.

The second guide 260 may include a turning bar 261 rotatably fitted between the pair of bimetals 250 and a head 262 provided at an end of the turning bar 261. At this time, both end portions of the pivot bar 261 may be bent and extended downward, and the pair of head portions 262 may be provided at the bent end portions.

The head portion 262 may have a shape corresponding to the top surface shape of the first guide 230 so that the second guide 260 is interlocked with the first guide 230. In detail, the head portion 262 is connected to the first guide 130 and rotated together with the first guide 230. For example, when the first guide 230 has a pair of wing portions 231, the head portion 262 may be formed in a wedge shape to be fitted in the valley portion 234, and the head portion 262 The wing portion 231 can be adhered and fixed.

The rotation bar 261 may be rotated as the bimetal 250 is bent and the rotation center may be a contact portion between the head portion 262 and the first guide 230. In detail, the pivot bar 261 may be provided in a space below the pair of bimetals 250.

When the bimetal 250 is bent, the bimetal 250 pushes the outer surface of the pivotal bar 261 that is fitted to the lower portion. Thus, the tilting direction (the left-right direction in FIG. 6) An external force is applied. Since the head portion 262 is connected to the first guide 230, this external force acts as a moment for rotating the entire first guide 230. When the bimetal 250 is bent, the pivotal bar 261 is drawn by the bimetal 250, and the first guide 230 generally contacts the contact portion between the head portion 262 and the first guide 230 .

Although the method of fixing the head portion 262 to the valley portion 234 of the first guide 230 is described as an example in the present embodiment, the method of joining the second guide 260 and the first guide 230 But is not limited thereto. For example, the lower portion of the second guide 260 may be fitted and fixed to a part of the first guide 230.

FIG. 8 is a view showing the non-power solar tracking apparatus of FIG. 5 operating in response to the change of the sun azimuth angle. Fig. 8 (a) is a side view of the solar tracking device, and Fig. 8 (b) is a plan view of the solar tracking device. Referring to FIG. 8, the shape of the bimetal 250 and the states of the first guide 230, the reflector 240, and the second guide 260 according to the position of the sun can be confirmed.

In the present embodiment, the sun is located on the left side of the solar ray tracking device 20 in the morning and the sun is located on the right side in the afternoon.

Before the sunrise, the bimetal 250 is not thermally expanded by the sunlight, so that the state as shown at noon in FIG. 8 is maintained.

Since the sun is located on the left side of the housing 200 in the morning, any one of the bimetals 250a can absorb the sunlight better, and the entire bimetal 250 is bent concavely in the leftward direction toward the sun .

The second guide 260 is connected to the lower part of the bimetal 250 and the rotation bar 261 is inserted between the lower part of the bimetal 250 as described above, The first guide 230 coupled to the second guide 260 and the reflector 240 rotate about the axis 220. The first guide 230 and the second guide 260 are rotated together with the bimetal 250 in the direction of bending. That is, when the bimetal 250 is bent to the left, the first guide 230, the second guide 260, and the reflecting portion 240 are rotated counterclockwise. Thereby, the main reflecting surface 241 of the reflecting portion 240 can be positioned toward the sun.

As the sun approaches to noon, the altitude of the sun gradually increases. At noon, the sun supplies the same energy to both bimetals 250a and 250b. The amount of thermal expansion of the bimetals 250a and 250b is the same The bimetal 250 is not bent in any direction, and the reflecting portion 240 can be directed upward.

In the afternoon, since the sun is located on the right side of the housing 200, any one of the bimetals 250b can absorb the sunlight better, so that the entire bimetal 250 is concave in the rightward direction toward the sun . The first guide 230 coupled to the second guide 260 and the first guide 230 coupled to the bimetal 250 move in the bending direction of the bimetal 250, The main reflecting surface 241 of the reflecting portion 240 can be positioned toward the sun.

Hereinafter, a non-power solar tracking apparatus according to another embodiment of the present invention will be described with reference to FIGS. 9 to 14. FIG. However, another embodiment differs from the first embodiment in that the second guide includes the ball chain and the belt pulley, so that the difference will be mainly described. In the following description, the detailed description of the components is omitted for avoiding redundant description. If necessary, the reference numerals of the reference numerals are replaced with 2, 3, and 4, respectively. For example, the housing of the non-powered solar tracking device 30 corresponding to the housing 100 of the non-powered solar tracking device 10 may be represented by reference numeral 300. For example, the photovoltaic solar tracking device 30 includes a housing 300, a fixing means 310, a shaft 230, a first guide 330, a reflector 340, a bimetal 350, (360), a bearing (370), and a heat insulating bushing (380).

Fig. 9 is a perspective view showing a non-power solar tracking apparatus according to another embodiment of the present invention, Fig. 10 is a side sectional view cut in the vicinity of the ball chain of Fig. 9, Fig. 11 is a cross- Fig. 12 is a side view of Fig. 11, and Fig. 13 is a cross-sectional view showing the structure of the pulley of Fig.

9 to 13, a non-powered solar tracking device 30 according to another embodiment of the present invention includes a tubular housing 300 through which light can pass, A shaft 320 passing through the bottom surface of the housing 300 (in the x-axis direction in FIG. 9) and through which the fluid flows, A reflector 340 connected to both sides of the first guide 330 and rotatable around the axis 320, a bimetal 350 fixed to the fixing means 310, And a second guide 360 for rotating the first guide 330 according to the amount of deformation of the bimetal 350.

The fixing means 310 may have two or more rectilinear portions 311a extending in the X axis within the housing 300. [ In this case, the rectilinear section 312 can be provided with the rectilinear section 312 for directly fixing the bimetal 350 to the rectilinear section 311a. Thus, the rectilinear section 312 can be provided with two or more rectilinear sections 311a .

The first guide 330 may be provided rotatably about a shaft 320 and may transmit the movement of the bimetal 350 to the reflector 340 to rotate the reflector 340. In this case, the first guide 330 may be a pulley having a plurality of grooves of the same size, or may have a structure in which a plurality of grooves are uniformly arranged.

Also, the first guide 330 may be provided to be fitted in the center of the shaft 320. Accordingly, the reflection portion 340 and the auxiliary reflection portion 390 may be provided on both sides of the first guide 330. [

The pair of bimetals 350 may be spaced apart from each other by a predetermined distance about the axis 320 and may be deformably fixed to the fixing means 310. In this case, the bimetal 350 is formed of two metal plates having different heat transfer rates. The bimetal 350 may have a rectangular cross-section, and may have a rectangular cross-section longer in the Z-axis direction, for example.

The pair of bimetals 350 may be fixed to the fixing means 310 by fastening means 351 such as bolts or may be connected to each other and may have one or more And may include a fastening hole 352. In the present embodiment, two bite holes 352 are formed in the bimetal 350. However, the present invention is not limited thereto.

The fastening hole 352 on the upper side of the bimetal 350 is configured to correspond to the fastening hole 314 of the fastening means 310 to be used to couple the bimetal 350 to the fastening means 310 . The fastening means 351 may be a washer, a sleeve, a bolt and a nut, but is not limited thereto.

Here, the bimetal 350 may be disposed such that a metal plate having a larger coefficient of thermal expansion is directed toward the inside of the housing 300. As a result, when the bimetal 350 absorbs and deforms the heat energy, the lower portion can be bent toward the direction in which sunlight is provided.

The bimetal 350 is bent as it absorbs solar heat. Specifically, the outer surface of the bimetal 350, that is, the surface subjected to the black body treatment, can absorb sunlight well, and therefore the deformation amount of the bimetal 350 can be increased. As the sunlight is absorbed, the bimetal 350 is bent according to the difference in the thermal expansion coefficients of the two metals forming the bimetal 350. At this time, the bimetal 350 is bent toward the sunlight because the metal plate having a larger coefficient of thermal expansion is disposed toward the inside of the housing 300.

In this embodiment, since the upper portion of the bimetal 350 is fixed to the fixing portion 312, the lower portion of the bimetal 350 can be bent in the horizontal direction with respect to the upper portion.

The second guide 360 may be directly connected to the bimetal 350 so that the first guide 330 may be rotated according to the amount of deformation of the bimetal 350. At this time, the second guide 360 may have a structure in which the first guide 330 is wrapped and both sides thereof are connected to the bimetal 350.

The second guide 360 may be a ball chain having a structure in which a plurality of balls are extended. At this time, the ball may be formed to have a size corresponding to the groove of the first guide 330, and the ball of the second guide 360 may be coupled to the groove of the first guide 330. Accordingly, when the bimetal 350 is bent, the second guide 360 moves along the bending direction of the bimetal 350, whereby the first guide 330 overlapped with the ball due to the ball of the second guide 360 The first guide 330 can be rotated.

The first guide 330 and the second guide 360 are illustrated as a pulley and the second guide 360 is a ball chain. However, the first guide 330 and the second guide 360 But is not limited thereto. In one example, a sprocket having a saw tooth structure and a corresponding chain can be provided.

FIG. 14 is a view showing the non-power source solar tracking device of FIG. 9 operating in response to a change of the sun azimuth angle.

Fig. 14 (a) is a side view of the solar tracking device, and Fig. 14 (b) is a plan view of the solar tracking device. Referring to FIG. 14, the shape of the bimetal 350 and the states of the first guide 330, the reflector 340, and the second guide 360 according to the position of the sun can be confirmed.

In this embodiment, the sun is located on the left side of the solar tracking device 30 in the morning and the sun is located on the right side in the afternoon.

Before the sunrise, the bimetal 350 is not thermally expanded by the sunlight, so the state as shown at noon in FIG. 14 is maintained.

The second guide 360 moves along with the bimetal 350 in the bending direction of the bimetal 350 and the second guide 360 moves along with the bimetal 350. As a result, The first guide 330 and the reflecting portion 340, which are coupled to each other, are rotated about the axis 320. That is, when the bimetal 350 is bent to the left, the first guide 330, the second guide 360, and the reflecting portion 340 are rotated counterclockwise. Thereby, the main reflecting surface 341 of the reflecting portion 340 can be positioned toward the sun.

At noon, the sun will be supplied with the same energy to both bimetals 350a and 350b, and the amount of thermal expansion of both bimetals 350a and 350b will be the same The bimetal 350 is not bent in any direction, and the reflecting portion 340 can be directed upward.

In the afternoon, since the sun is located on the right side of the housing 300, the entire bimetal 350 is concavely bent in the rightward direction toward the sun. Accordingly, the second guide 360 moves together with the bimetal 350 in the bending direction of the bimetal 350, thereby causing the first guide 330 to be engaged with the second guide 360, 340 are rotated clockwise about the axis 320, the main reflecting surface 341 of the reflecting portion 340 can be positioned toward the sun.

Hereinafter, a comparison graph of efficiency of the non-power solar tracking apparatus according to an embodiment of the present invention will be described with reference to FIG.

15 is a graph showing a comparison between a solar collector and a conventional solar collector according to an embodiment of the present invention.

Referring to FIG. 15, when the efficiency of a solar collector having a two-axis tracking device is taken as 100, the efficiency of the solar-powered solar tracking device 10, 20, 30 according to the present invention may vary with time.

For example, at 08 o'clock, the radiant black body emission of the bimetals 150, 250 and 350 is less than the radiant energy of the sun, ) At the time of 12 o'clock, and the radiant blackbody emission of the bimetal (150, 250, 350) at 12 o'clock is equal to the direct radiation of the sun Energy is smaller than energy, it can show the same efficiency as ⓒ.

Since the radiant black body emission of the bimetals 150, 250 and 350 is equal to the radiant energy of the sun at the time of 14 o'clock at 14 o'clock, the efficiency can be shown as d. At about 15 o'clock, the bimetals 150, 250 and 350 ) Since the blackbody emission is smaller than the solar energy of the sun, it can show the same efficiency as ⓔ.

As described above, the non-powered solar tracking device 10, 20, 30 according to the present invention can exhibit a specific curve shape according to the response time delay of the bimetals 150, 250, 350.

Although the solar tracking device according to the embodiment of the present invention has been described above as a specific embodiment, the present invention is not limited thereto, and the present invention is not limited thereto, and may be interpreted as having the widest range according to the basic idea disclosed in the present specification . Skilled artisans may implement the pattern of features that have not been explicitly described in combination, substitution of the disclosed embodiments, but which, too, do not depart from the scope of the present invention. It will be apparent to those skilled in the art that various changes and modifications may be readily made without departing from the spirit and scope of the invention as defined by the appended claims.

10, 20, 30: solar tracking device 100, 200, 300: housing
110, 210, 310: fixing means 120, 220, 320:
130, 230, 330: first guide 140, 240, 340:
150, 250, 350: bimetal 160, 260, 360: second guide
170, 270, 370: bearings 180, 280, 380: insulating bushings

Claims (17)

A tubular housing through which light can pass;
Fixing means provided inside the housing;
An axis passing through the housing along an extension direction of the housing and provided with energy conversion means therein;
A first guide rotatable about the axis;
A reflector connected to the first guide and rotatable together with the first guide about the axis, the reflector reflecting sunlight toward the axis;
A bimetal fixed to the fixing means so as to be deformable and formed of two metal plates having different heat transfer rates; And
And a second guide for rotating the first guide according to a deformation amount of the bimetal,
The housing is a vacuum tube
Photovoltaic solar tracking device. The method according to claim 1,
Wherein the bimetal extends in the axial extension direction and the center portion is fixed and both ends are bent in the horizontal direction, the second guide surrounds the bimetal, and the end of the bimetal is slidably movable inside, And a head portion that applies an external force to the first guide in accordance with the movement of the hook portion
Photovoltaic solar tracking device. The method according to claim 1,
Wherein the bimetal is provided in a pair, the bimetal is fixed to the upper portion and the lower portion is bent in the horizontal direction, the second guide includes a rotating bar that is sandwiched between the pair of bimetals, And a head portion
Photovoltaic solar tracking device. 4. The method according to any one of claims 1 to 3,
Wherein the first guide includes a wing portion to which a head portion of the second guide is connected and fixed
Photovoltaic solar tracking device. 5. The method of claim 4,
The wing portion has a concave shape toward the reflection portion, and the back surface of the wing portion is formed as an auxiliary reflection surface that reflects the light reflected by the reflection portion
Photovoltaic solar tracking device. The method according to claim 1,
The bimetal is fixed on the upper part, the lower part is bent in the horizontal direction,
The second guide is connected to the bimetal, moves according to the movement of the bimetal,
And the first guide rotates in accordance with the movement of the second guide
Photovoltaic solar tracking device. The method according to claim 6,
Wherein the first guide is a pulley having a constant groove and the second guide is formed of a ball chain having a ball having a size corresponding to the groove of the pulley
Photovoltaic solar tracking device. The method according to claim 1,
The bimetal is provided in a pair,
Wherein an inner metal plate of the bimetal closer to the axis among the two metal plates constituting the bimetal has a coefficient of thermal expansion greater than that of an outer metal plate of the bimetal far from the axis
Photovoltaic solar tracking device. 9. The method of claim 8,
Wherein the bimetal has an outer surface farther from the axis than a blackbody surface, and an inner surface near the axis is a total reflection surface
Photovoltaic solar tracking device. The method according to claim 1,
And the second guide converts the linear motion of the bimetal into a rotational motion and transmits the rotational motion to the first guide
Photovoltaic solar tracking device. The method according to claim 1,
Wherein the reflecting portion further comprises a main reflecting surface reflecting sunlight and a supporting portion for fixing the curvature and shape of the main reflecting surface
Photovoltaic solar tracking device. delete The method according to claim 1,
And a bearing provided in a form to wrap the shaft
Photovoltaic solar tracking device. 14. The method of claim 13,
Further comprising a thermal insulation bushing between the shaft and the bearing to block thermal interference of the shaft
Photovoltaic solar tracking device. The method according to claim 1,
The first guide is provided with a weight
Photovoltaic solar tracking device. The method according to claim 1,
Wherein the energy conversion means is a heat-mediating fluid flowing inside the shaft
Photovoltaic solar tracking device. The method according to claim 1,
Wherein the energy conversion means is a thermoelectric element provided inside the shaft
Photovoltaic solar tracking device.

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