KR100925674B1 - Device for tracking sunlight - Google Patents

Abstract

PURPOSE: A solar tracking device is provided to fix a solar panel firmly by connecting a reinforcing bar to the back of the solar panel and supporting it on the bottom side of a post. CONSTITUTION: A solar tracking device comprises a post(10), a panel frame(20), a drive unit(30), a solar panel(40), a reinforcing-supporting unit(50), a reinforcing-connecting member(60), and a reinforcing bar(70). The panel frame is connected to rotate around a vertical rotation shaft supported in a shaft supporting part. The drive unit drives the panel frame around the rotation shaft to rotate reciprocally. The solar panel is installed on the top of the panel frame. The reinforcing-supporting unit is installed on the bottom part of the post. The reinforcing-connecting member is supported in the reinforcing-supporting unit around the same axis as the rotation shaft. One end of the reinforcing bar is connected to the reinforcing-connecting member while the other is connected to the panel frame.

Description

Solar Tracking Device {DEVICE FOR TRACKING SUNLIGHT}

The present invention relates to a solar tracking device, and more particularly, a reinforcing bar connected to a rear of a solar collector panel rotatably supported by a vertical axis of rotation at an upper end of a pillar is supported at a lower end of the pillar to shake the solar collector panel. It relates to a solar tracking device that can prevent the thing.

The solar tracking device is a device for measuring the sun's altitude or orientation, or allowing the solar collector or the solar collector panel of the solar power generator to track the sun according to a pre-programmed method in time. Here, the solar collector panel is a concept including both a panel panel for absorbing sunlight, such as a solar heat collecting panel that obtains heat energy from sunlight and a solar power panel that obtains electrical energy from sunlight.

The solar collector panel rotated to track the sun by the solar tracking device as described above is widened in order to increase the concentration or the concentration of the solar collector panel, and thus the solar collector panel is subjected to a large wind pressure by wind. . Therefore, the solar tracking device supporting and rotating the solar collection panel should be designed to have a structure that does not overturn or collapse even when a large wind pressure is applied to the solar collection panel.

In particular, since the wind speed or direction of wind changes frequently, a variable load is applied to the solar collector panel, and a vibration load is applied to the rotating shaft on which the solar collector panel is supported by vibration, which is very likely to cause fatigue failure. The greater the amplitude of vibration, the greater the risk of rollover.

The present invention was conceived by recognizing the above point is an object of the present invention is a reinforcing bar connected to the rear of the solar collector panel rotatably supported by a vertical axis of rotation on the top of the pillar is supported on the lower end of the solar collector It is to provide a solar tracking device that can prevent the panel shake.

The solar tracking device according to the present invention includes a vertically mounted pillar, a panel frame rotatably connected to a vertical axis of rotation supported by a shaft support provided at an upper end of the pillar, and the panel frame about the axis of rotation. A driving means for reciprocating rotation, a solar collector panel attached to an upper surface of the panel frame, a reinforcement support provided at a lower end of the column, and a reinforcement support supported rotatably about an axis concentric with the rotation axis. The reinforcement connecting portion, one end is connected to the reinforcing connection portion and the other end is characterized in that it comprises a plurality of reinforcing bars connected to the panel frame.

In addition, the solar tracking device according to the present invention, the reinforcing support portion is formed so that the outer edge has a circumference around the axis concentric with the rotation axis, the first ball seating groove is formed at the end of the outer edge, The reinforcing connection portion is formed such that an inner edge thereof has a circumference facing the outer edge of the reinforcing support portion, and a second ball seating groove is formed at a position corresponding to the first ball seating groove at an end portion of the inner edge thereof. The rolling ball is inserted and seated in the first ball seating groove and the second ball seating groove, characterized in that supported by the reinforcement support part.

In addition, the solar tracking device according to the present invention, the reinforcing support portion is formed so that the outer edge has a circumference around the axis concentric with the rotation axis, the reinforcement connection portion is provided with a roller rotatably the outer side of the reinforcement support It is supported by the reinforcing support while rotating in contact with the rolling clouds.

In addition, the solar tracking device according to the present invention is characterized in that the roller is formed with a groove for seating the outer edge end of the reinforcing support portion is inserted.

In addition, the solar tracking device according to the present invention, the reinforcement connecting portion is formed in an annular, characterized in that divided into a plurality of connected by a connecting bracket.

The solar tracking device according to the present invention by the configuration as described above is connected to the rear of the solar collector panel rotatably supported by a vertical axis of rotation on the top of the pillar is supported on the lower end of the pillar shaking the solar collector panel It has the advantage of preventing it.

Hereinafter, with reference to the embodiment shown in the drawings will be described in more detail the solar tracking device according to the present invention.

1 is a rear view showing a solar tracking device according to a first embodiment of the present invention, Figure 2 is a side view showing a solar tracking device according to a first embodiment of the present invention, Figure 3 is a present invention 4 is a cross-sectional view illustrating a structure of an axis support part and a rotating shaft part of the solar tracking device according to the first embodiment of the present invention, and FIGS. 4A and 4B show reinforcement support parts and reinforcement connecting parts of the solar tracking device according to the first embodiment of the present invention. Sectional drawing and top view which show the structure of a part.

Referring to the drawings, the solar tracking device according to the first embodiment of the present invention is a pillar 10, a panel frame 20, a drive means 30, a solar collector panel 40, a reinforcement support 50, reinforcement It is configured to include a connecting portion 60, the reinforcement bar (70).

The pillar 10 is a structure for vertically standing on the ground (S) to support the solar collector panel 40 is rotated. Referring to the drawings, the column 10 is vertically fixed with the lower end fixed to the foundation (B) embedded in the ground (S). The upper end of the pillar 10 is provided with a shaft support 11 for rotating the panel frame 20, the solar collector panel 40 is installed. The shaft support portion 11 is configured to support the shaft 21 provided in the central portion on the rear surface of the panel frame 20, and is provided with a bearing support end 11a thereon. The bearing support end 11a is coupled to an outer ring of a bearing in which the rotating shaft 21 is coupled to an inner ring.

The panel frame 20 is rotatably supported by the shaft support part 11 and is a frame structure for laying the solar collector panel 40 on an upper surface thereof. That is, the panel frame 20 is connected to the pillar 10 so as to be rotatable about a vertical rotation shaft 21 supported by the shaft support portion 11 provided at the upper end of the pillar 10.

Referring to the drawings, the panel frame 20 is coupled to an inner ring of a bearing having an outer ring coupled to a bearing support end 11a of the shaft support part 11 such that the shaft support part 11 is rotated about a vertical axis. The rotating shaft 21 is supported on, the shaft bracket 22 formed integrally with the rotating shaft 21 at the upper end of the rotating shaft 21, and connected to the shaft bracket 22 to connect the beam in the shape of a frame structure It is composed of a frame portion 24 formed. The frame portion 24 has a base beam 24a coupled to the shaft bracket 22 and a lower end of the frame beam 24 to form an inclination for inclining the solar collector panel 20 toward south. An inclined beam 24b connected to the base beam, a connecting beam 24c mounted on the base beam 24a lower than an upper end of the inclined beam 24b and coupled to the base beam 24a, and the inclined beam 24b; The main beam 24d supported and inclined to the connecting beam 24c, and the transverse beam 24d coupled to the main beam 24d in the transverse direction to the main beam 24d and the transverse beam 24d in the longitudinal direction. The support beam 24f coupled to the transverse ice 24d is configured to be a frame structure. The solar collector panel 40 is mounted on the support beam 24f and coupled thereto.

On the other hand, since the panel frame 20 has a structure supported on the upper end of the column 10 by the rotating shaft 21, the load of the panel frame 20 itself and the solar collector panel 40 installed on the upper portion thereof. The force exerted by the load and the external force (mainly the external force due to the wind pressure by the wind) is concentrated on the rotating shaft 21 and is caught. Accordingly, referring to the drawings, the panel frame 20 surrounds the outside of the shaft support part 11 of the pillar 10 and installs a reinforcement case 23 supported by the shaft support part 11, and the reinforcement case thereof. By connecting the 23 to the shaft bracket 22 with the connecting bolt 23a, the load applied to the rotating shaft 21 is distributed to the reinforcing case 23.

In addition, the present invention allows the panel frame 20 to be supported on the lower end of the column 10 by the reinforcing bar 70 as described below, so that the load applied to the rotating shaft 21 can be dispersed, and in particular, The panel frame 20 is prevented from vibrating by the variable wind pressure applied to the light collecting panel 40.

The drive means 30 is a configuration for reciprocating rotation drive the panel frame 20, the photovoltaic collecting panel 40 is installed on the rotation axis 21 on the upper surface. The solar collector panel 40 is installed in the upper portion of the panel frame 20 to be inclined southward in consideration of the altitude of the sun and is rotated reciprocally around the rotation shaft 21 in the east in accordance with the circumference of the sun. The driving means 30 is configured to rotate the panel frame 20 and to control the driving thereof. Referring to the drawings, the driving means 30 includes a drive motor 31 fixed to the shaft bracket 22 of the panel frame 20, and a worm gear 32 connected to the rotation shaft of the drive motor 31. And a worm wheel 33 formed to be engaged with the worm gear 32 on the upper circumference of the shaft support part 11 and a controller (not shown in the drawing) for controlling the driving of the driving motor 31. do.

The solar collector panel 40 is configured to absorb solar energy while being mounted on the panel frame 20 and rotated to follow each other in the copper by driving the driving means 30. The solar collector panel 40 converts the solar energy into energy that can absorb and use solar energy, such as a solar heat collecting panel that obtains heat energy from sunlight or a solar power generating panel that obtains electrical energy from sunlight.

On the other hand, in the present invention as described above, because the solar collector panel 40 is a plate-like structure, a lot of wind pressure due to wind is applied. Therefore, the wind pressure applied to the solar collector panel 40 causes a large load on the rotary shaft 21, leading to breakage of the rotary shaft 21, or the entire apparatus is overturned. Particularly, the structure of the panel frame 20 and the solar collector panel 40 supported on the upper end of the column 10 is shaken due to the variable load applied to the solar collector panel 40 due to the variation of the wind pressure rather than the static load. When the vibration is lowered, the vibration acts as a large load on the rotating shaft 21. When the amplitude increases due to the influence of dynamic load or resonance, the possibility of the device overturning becomes very large. Therefore, the present invention is characterized in that the panel frame 20 is supported on the lower end of the column 10 through the support bar 70 to prevent the vibration caused by the fluctuation of the wind pressure. To this end, the present invention is provided with a reinforcement support part 50 at the lower end of the column 10, connected to the panel frame 20 that is rotated about the rotary shaft 21 is rotated integrally with the panel frame 20 The support bar 70 is rotated around the pillar 10 while being connected to the reinforcement support part 50 and the upper end connected to the panel frame 20 and the lower end of the reinforcement connection part. It is configured to include a reinforcing bar 70 connected to (60). Hereinafter, the reinforcement support part 50, the reinforcement connection part 60, and the reinforcement bar 70 will be described in more detail.

The reinforcement support part 50 is provided at the lower end of the column 10 in such a manner that the reinforcement connection part 60 is rotatably supported about the column 10. Referring to the drawings, the reinforcement support 50 is a support bracket 51 coupled to stand on the lower end of the column 10, and the support bracket 51 is formed in an annular shape around the lower end of the column 10. It consists of an annular support ring 52 coupled to the upper portion of.

The reinforcing connection part 60 is configured to be rotatably supported by the support ring 52 of the reinforcing support part 50 by connecting the lower end of the reinforcing bar 70. That is, the reinforcing connection part 60 is rotatably supported by the reinforcement support part 50 about an axis concentric with the rotation shaft 21. Referring to the drawings, the reinforcing connection part 60 is formed in an annular ring shape so that its inner edge faces the outer edge of the support ring 52 and is supported on the outer edge thereof. A connector 62 for connecting the reinforcement bar 70 to the upper portion of the reinforcement connector 60 is formed. In order to facilitate the installation of the reinforcing connector 60 formed in an annular shape as described above, the reinforcing connector 60 is divided into several pieces 60a, 60b, 60c, and 60d and connected to each other to have an annular structure. That is, the reinforcing connection part 60 is formed in an annular shape as a whole, and is divided into four pieces 60a, 60b, 60c, and 60d so that both ends of the pieces are annular by the connecting bracket 61 in a state where they are opposed to each other. Connected.

On the other hand, the reinforcement connecting portion 60 is in contact with the reinforcing ring 52 of the reinforcing support portion 50 can be supported by sliding as well as the outer edge of the reinforcing support portion 50 facing each other as shown in the figure It is preferable that the rolling ball 64 is interposed between the end face and the inner edge end face of the reinforcing connection part 60 to reduce the friction. Referring to the drawings, the reinforcing ring 52 of the reinforcing support part 50 is formed so that the outer edge has a circumference about an axis concentric with the rotation axis, and the first ball seating groove 52a at the end of the outer edge thereof. Is formed. In addition, the reinforcing connector 60 is formed such that the inner edge has a circumference facing the outer edge of the reinforcing ring 52 of the reinforcing support part 50, and the first ball seating groove 52a at the end of the inner edge thereof. The second ball seating groove 63 is formed at a position corresponding to The rolling ball 64 is inserted and seated so as not to fall into the first ball seating groove 52a and the second ball seating groove 63, and the reinforcement connecting part 60 is the reinforcing support part by the rolling ball 64. It is rotatably supported by the reinforcing ring 52 of the (50).

The reinforcement bar 70 is for supporting the panel frame 20 so as not to shake. The lower end is connected to the reinforcement connection part 60 and the other end is connected to the panel frame 20. The position where the reinforcing bar 70 is connected to the panel frame 20 has a great moment supporting force as far as possible from the rotating shaft 21. In the drawing, four reinforcement bars 70 are provided, and an example is shown in which the reinforcement bars 70 are connected near each corner of the panel frame 20 having a rectangular shape, respectively. As described above, the reinforcing bar 70 is integrally rotated with the panel frame 20 which is rotated to follow the sun, the lower end of which is connected to the reinforcing connection part 60 rotatably supported by the reinforcing support part 50. Since the panel frame 20 is connected so as to be supported at the lower end of the column 10, the rotation is not constrained.

As described above, the present invention is provided with a reinforcement support part 50 at the lower end of the column 10, the lower end of the reinforcement bar 70 connected to the upper end of the panel frame 20 is connected to the reinforcement connection part 60, The reinforcing connection part 60 is configured to be rotatably supported by the reinforcing support part 50, so that the panel frame 20 is supported so as not to be shaken. The structure of the reinforcement support part and the reinforcement connection part as described above may be variously configured, and FIGS. 5A and 5B illustrate a reinforcing support part and the reinforcement connection part having a different structure from the first embodiment shown in FIGS. 1 to 4B. 2 is a view showing a part of the solar tracking device according to the embodiment.

Hereinafter, the reinforcing connector 50 'and the reinforcing connector 60' of the solar tracking device according to the second embodiment of the present invention will be described in detail with reference to FIGS. 5A and 5B.

5A and 5B, the reinforcing support part 50 'of the second embodiment is formed in an annular shape so that the outer edge 52a' has a circumference about an axis concentric with the rotational axis, and thus the lower end of the column 10. It is provided. That is, the reinforcement support part 50 'of the second embodiment is a support bracket 51' coupled to stand on the lower end of the column 10, and is formed in an annular shape to support the circumference around the lower end of the column 10. It consists of an annular support ring 52 'coupled to the upper portion of the bracket 51'.

The reinforcing connection part 60 'of the second embodiment is formed in an annular shape, and several rollers 61' are installed in the circumferential direction. Referring to the drawings, the reinforcing connection portion 60 'is provided with several roller shafts 60a', and the roller 61 'is rotatably supported by the roller shaft 60a'. ) Rotates in contact with the outer edge 50a 'of the reinforcing ring 52' of the reinforcing support 50 '. The reinforcing connection part 60 'is supported by the reinforcing ring 52' of the reinforcing support part 50 'by the roller 61'.

Meanwhile, the reinforcing ring 52 'and the roller 61' are coupled so as not to be separated. Referring to the drawings, the groove 61a 'is formed in the roller 61', and the groove 61a 'is formed in the groove 61a'. The outer edge 52a 'end of the reinforcing ring 52' is inserted and seated and engaged.

The solar tracking device described above and shown in the drawings is only one embodiment for carrying out the present invention, and should not be construed as limiting the technical idea of the present invention. The scope of protection of the present invention is defined only by the matters set forth in the claims below, and the embodiments which have been improved and changed without departing from the gist of the present invention will be apparent to those skilled in the art. It will be said to belong to the protection scope of the present invention.

1 is a rear view showing a solar tracking device according to a first embodiment of the present invention

2 is a side view showing a solar tracking device according to a first embodiment of the present invention

3 is a cross-sectional view showing the structure of the shaft support portion and the rotating shaft portion of the solar tracking device according to the first embodiment of the present invention

4A and 4B are cross-sectional views and plan views showing the structure of the reinforcement support part and the reinforcement connection part of the solar tracking device according to the first embodiment of the present invention.

5a and 5b is a cross-sectional view and a plan view showing the structure of the reinforcing support portion and the reinforcing connection portion of the solar tracking device according to a second embodiment of the present invention

<Short description of the major reference symbols>

10 pillars

     11 shaft support

20 panel frames

     21 axis of rotation

     22 shaft bracket

     23 reinforcement case

     24 frame parts

30 Driving means

     31 drive motor

     32 Worm Gear

     33 Worm Wheel

40 Solar Collecting Panel

50 Reinforcement Support

60 Reinforcement connection

70 reinforcement bar

Claims (5)

Vertical pillars, A panel frame rotatably connected about a vertical axis of rotation supported by a shaft support provided at an upper end of the column; Drive means for reciprocating rotation of the panel frame about an axis of rotation; A solar collector panel attached to an upper surface of the panel frame; A reinforcement support part provided at the lower end of the pillar, A reinforcement connecting part rotatably supported about the axis of concentricity with the rotation shaft, and the reinforcement support part; One end is connected to the reinforcement connecting portion and the other end is a solar tracking device comprising a plurality of reinforcing bars connected to the panel frame. The method of claim 1, The reinforcing support portion is formed such that the outer edge has a circumference about an axis concentric with the rotation axis, and an end of the outer edge is formed with a first ball seating groove, The reinforcing connection portion is formed such that the inner edge thereof has a circumference facing the outer edge of the reinforcing support portion, and an end of the inner edge thereof has a second ball seating groove formed at a position corresponding to the first ball seating groove, The reinforcing connection unit is a solar tracking device, characterized in that the rolling ball is seated in the first ball seating groove and the second ball seating groove is supported by the reinforcement support. The method of claim 1, The reinforcing support portion is formed such that the outer edge has a circumference around an axis concentric with the rotation axis, The reinforcing connector is rotatably provided with a roller is supported on the reinforcement support while being rotated in contact with the outer edge of the reinforcement support portion. The method of claim 3, The roller is a solar tracking device, characterized in that the groove is formed to be seated is inserted into the outer edge end of the reinforcement support. The method according to any one of claims 1 to 4, Reinforcing connector portion is formed in an annular, divided into a plurality of solar tracking device characterized in that connected by the connecting bracket.

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