KR101707584B1 - Solar structure having a recline function - Google Patents

Abstract

The present invention relates to a solar generation structure having an angle control function, which can easily control the vertical angle of a solar cell module according to solar altitude and position, and can support the solar cell module more safely. The present invention can reduce manufacturing costs by simplifying the structure.

Description

[0001] Solar structure having a reclining function [0002]

The present invention can more easily adjust the vertical angle of the solar cell module according to the sun altitude and position, and can more safely support the solar cell module in a structurally more secure manner. Further, And more particularly, to a solar power generating structure having an angle adjusting function that can be reduced.

Recently, due to the exhaustion of fossil energy and the burden of greenhouse gas reduction obligations under the Convention on Climate Change, the development of alternative energy is urgently needed.

In addition, it is required to construct own power generation facilities in remote islands such as islands where transmission and distribution facilities can not be installed, and accordingly, the renewable energy industry for producing electric energy from solar and wind power is required to have an annual average of 20% ~ 30% And is rapidly expanding into high-tech new industries in the 21st century along with IT and BT industries.

In accordance with this tendency, recently, a main body, in which a rear end of a center is hinged to a support rod rotatably installed on a pedestal, is adjusted in accordance with the reciprocal movement of the working rod, Patent No. 10-0798441.

However, in the case of the Korean Patent Registration No. 10-0798441 (solar power generation system using sunlight and heat), in order to smoothly reciprocate the working rod for adjusting the inclination angle of the main body, So that it is difficult to securely support the main body in a structurally safe manner, and the structure is complicated, thus requiring a lot of manufacturing cost.

Korean Patent Registration No. 10-0798441

The present invention has been made in order to solve the above problems, and it is an object of the present invention to provide a solar cell module which can more easily adjust the vertical angle of the solar cell module according to the sun altitude and position, And an object of the present invention is to provide a solar power generating structure having an angle adjusting function that can reduce the manufacturing cost by simple structure.

According to an aspect of the present invention, there is provided a solar cell module comprising: a stationary frame to which a solar cell module is fixed; A support having an upper portion axially coupled to the stationary frame to be provided below the stationary frame; A horizontal support fixed to the support to be provided in a lower direction of the fixed frame; A rotation guide part that is axially coupled to the front side of the horizontal support and guiding the upward and downward rotational movement of the solar cell module so that the solar cell module is rotated up and down to adjust the angle, A pair of second fixing holes provided on both sides of the rotary guide part at predetermined intervals in the vertical direction, the upper and lower movable parts being vertically movable in the vertical direction, the upper part being axially coupled to the fixed frame, Wow; A pinion gear axially coupled to the inside of the rotation guide portion in a state of engagement with the rack gear of the up-and-down moving portion; And a position fixing unit inserted and fixed in any one of the first fixing holes of the rotation guide unit and the plurality of second fixing holes of the up-and-down moving unit so that the up-down and down- And a solar cell structure having an angle adjusting function.

Here, it is preferable that a manual lever for rotating the pinion gear is provided.

Alternatively, it is preferable that a driving member for rotating the pinion gear is provided.

A rotation direction switching stopper for switching the rotation direction of the pinion gear is axially coupled to the inside of the rotation guide portion.

Here, the rear side of the rotation direction switching stopper is rotationally moved in the front-rear direction of the pinion gear while the front side of the rotation direction switching stopper is axially coupled to the inside of the rotation guide portion, An upper protruding member formed on an upper portion of the rear side of the rotation direction change stopper and inclined upward toward a rear upper side of the rotation direction change stopper from a lower portion toward an upper portion; And a lower protruding member formed at a rear lower portion of the rotation direction change stopper and inclined downward in the rear lower direction of the rotation direction change stopper from an upper portion to a lower portion.

Or the rear side of the rotation direction switching stopper is rotationally moved in the front and rear direction of the pinion gear in a state where the front side of the rotation direction switching stopper is axially coupled to the inside of the rotation guide portion, An upper inclined surface formed on an upper portion of the rear side of the rotation direction change stopper and inclined downward in a rear lower direction of the rotation direction stopper from an upper portion to a lower portion; And a lower inclined surface which is formed at a rear lower portion of the rotation direction change stopper and which is inclined upward toward the upper side of the rear portion of the rotation direction stopper from the lower portion toward the upper portion.

Furthermore, it is preferable that a arc-shaped guide slit is formed on the side surface of the horizontal support and the side surface of the rotation guide, respectively, and a position fixing member for fixing the rotation guide in a state of being accommodated in the guide slit.

Alternatively, an arc-shaped guide slit is formed on a side surface of the horizontal support, a shaft member accommodated in the guide slit is formed on a side surface of the rotation guide, and a nut member is screwed to the shaft member.

In accordance with the present invention, it is possible to more easily adjust the vertical angle of the solar cell module through the upper and lower portions of the solar cell module according to the sun altitude and position, which are changed by seasonal characteristics, The upper and lower tongues can securely support the solar cell module in a structurally more secure manner, and furthermore, the structure is simple, so that the manufacturing cost can be reduced .

1 is a perspective view schematically showing a solar power generating structure having an angle adjusting function, which is an embodiment of the present invention,
2 is a perspective view schematically showing a state in which the solar cell module is not fixed to the stationary frame,
Fig. 3 is a side view of Fig. 1,
4 is a side view schematically showing a state in which the solar cell module is rotated up and down to adjust its angle,
5 is a partially enlarged perspective view showing an enlarged view of the horizontal support and the rotation guide,
Fig. 6 is a partially enlarged incision oblique view of Fig. 5,
Figs. 7 and 8 are partial enlarged plan views schematically showing a manual lever for rotating the pinion gear,
9 is a partially enlarged plan view schematically showing a driving member for rotating the pinion gear,
10 and 11 are enlarged partial side views schematically showing a state in which an example rotation direction switching stopper is rotated,
Figs. 12 and 13 are partially enlarged side views schematically showing a state in which the rotation direction change-over stopper of another example is rotationally moved,
14 is a partially enlarged side view schematically showing a state in which the position fixing member is accommodated in the guide slit formed on the side surface of the horizontal support and the side surface of the rotation guide,
15 is a partially enlarged plan view schematically showing the position fixing member,
16 is a partially enlarged plan view schematically showing a state in which a nut member is screwed to a shaft member formed on a side surface of the rotation guide portion,
17 is a perspective view schematically showing a solar power generating structure having an angle adjusting function, which is another embodiment of the present invention,
FIG. 18 is a perspective view schematically showing a state where the fixing frame and the solar cell module are not provided on the upper part of the support,
19 is a side view of Fig.

Hereinafter, preferred embodiments of the present invention will be described in more detail with reference to the accompanying drawings. It is to be understood that the scope of the present invention is not limited to the following embodiments, and various modifications may be made by those skilled in the art without departing from the technical scope of the present invention.

FIG. 1 is a perspective view schematically showing a solar power generating structure having an angle adjusting function, which is an embodiment of the present invention, FIG. 2 is a perspective view schematically showing a state in which a solar cell module is not fixed to a stationary frame, And FIG. 4 is a side view schematically showing a state in which the solar cell module is rotated up and down to adjust its angle.

1 to 4, a solar power generating structure having an angle adjusting function according to an embodiment of the present invention includes a fixed frame 10, a support 20, a horizontal support 30, a rotation guide 40, A pinion gear (60 in Fig. 6), and a position fixing portion (70 in Fig. 5).

First, the solar cell module 11 is seated and fixed on the fixed frame 10 in various ways such as bolt fixing.

The support 20 is vertically provided on the lower portion of the fixed frame 10 and is coupled to the fixed frame 10 in a state where the upper portion is axially coupled to the lower side, An intermediate strut 220 and an other strut 230 disposed on the center line of the center strut 210 at left and right sides at regular intervals.

5 is a partially enlarged perspective view showing an enlarged view of a horizontal support and a rotation guide, and FIG. 6 is a partially enlarged incisional perspective view of FIG.

Next, the horizontal support 30 is fixed to the column 20 so as to be provided in a lower direction of the fixed frame 10.

As shown in FIGS. 5 and 6, in order to allow the horizontal support 30 to move in the vertical direction of the support 20 and be fixed to the support 20 in a position-adjusted state, (310) and a rear lateral support (320).

The front horizontal support 310 may be provided on the upper side of the column 20 so as to be disposed in a lower direction of the fixed frame 10.

The rear horizontal support 320 may be provided on the upper rear side of the column 20 so as to be provided in a lower direction of the fixed frame 10.

The front and rear lateral supports 310 and 320 may be coupled to each other by a predetermined distance between the front and rear lateral supports 310 and 320. [ One side of the front side and the other side of the other side can be detachably fixed by various methods such as bolt fixing.

One side rear side and the other side rear side of the rotation guide part 40 are respectively connected to the horizontal support part 310 of the horizontal support part 30, And is axially coupled to one side of the front side and the other side of the other side of the front side horizontal support 310 of the main body 30.

The front and rear sides of the solar cell module 11 are respectively rotated in the vertical direction of the solar cell module 11 so that the solar cell module 11 is rotated up and down So as to guide the upward and downward movement of the solar cell module 11 so as to adjust the angle.

As shown in FIG. 5, a first fixing hole 410 is formed on one side of the rotation guide part 40.

Next, the up / down moving part 50 is vertically provided on the inside of the rotation guide part 40 so as to be vertically movable.

The upper part of the up / down moving part 50 is fixed to the lower part of the fixed frame 10 so that the upper and lower moving parts 50 face one side support 210, middle support 220 and the other support 230 of the support 20. [ And are axially coupled to the front side at regular intervals.

A rack gear 510 is provided on the front side or all sides of any one of the one support pillars 210, the middle support pillars 220 and the plurality of the upward / downward movable pillars 50 facing the other support pillars 230, .

A plurality of second fixing holes 511 are formed at regular intervals in the vertical direction of the up / down moving part 50 on both sides of the up / down moving part 50, that is, one side surface and the other side surface of the up / down moving part 50.

The pinion gear 60 is rotatably supported by one of the plurality of rotation guide portions 40 located in the forward direction of the support pillars 210, middle support pillars 220 and the other support pillars 230 of the pillars 20, And can be engaged with the rack gear 510 of the up / down moving part 50 in a state of being axially coupled to one inner front side or all of the inner front sides.

4, each of the plurality of upward and downward moving parts 50 facing the one supporting part 210, the intermediate supporting part 220 and the other supporting part 230 is vertically The first fixing holes 410 of the rotation guide portion 40 and the plurality of second fixing holes 511 of the up and down moving portion 50 are positioned and fixed as shown in FIG. And a fixed shaft which is inserted and fixed in any one of them.

A nut member may be screwed to one side of the fixed shaft so as to prevent the detachment of the fixed shaft which can form the position fixing portion 70. [

7 and 8 are partial enlarged plan views schematically showing a manual lever for rotating the pinion gear, respectively.

Next, in order to rotate the pinion gear 60 manually or more easily without power consumption, as shown in FIG. 7, the pinion gear 60 is formed of a crankshaft or the like at one side or the other side of the shaft 601 of the pinion gear 60 One side of the manual lever 80 can be detachably or integrally coupled.

When one side of the manual lever 80 is detachably coupled to one side or the other side of the shaft 601 of the pinion gear 60 in order to rotate the shaft 601 of the pinion gear 60 smoothly and smoothly, The cross section of one side or the other side of the shaft 601 of the pinion gear 60 may be a straight line or a polygonal shape such as a triangle, a quadrangle, a pentagon, a hexagon, or the like, One or both sides of the shaft 601 of the pinion gear 60 are formed in a shape corresponding to the sectional shape so that one side or the other side of the shaft 601 of the pinion gear 60 is inserted Grooves can be formed.

8, the rear side rotational force transmission gear 801 may be coupled to one side or the other side of the shaft 601 of the pinion gear 60, and the front side of the rear side rotational force transmission gear 801 may be connected to the rear side The front side rotational force transmission gear 802 engaged with the rear side rotational force transmission gear 801 can be axially coupled to the front side or the other side of the other side of the rotation guide part 40. [

One side of the manual lever 80, which may be a crankshaft or the like, may be detachably or integrally connected to the shaft 802a of the front side rotational force transmission gear 802.

9 is a partially enlarged plan view schematically showing a driving member for rotating the pinion gear.

9, on the front side or the front side of the other side of the rotation guide portion 40, the shaft portion of the pinion gear 60 is rotatably supported by the pinion gear 60, Such as a driving motor coupled to one side or the other side of the motor 601, may be fixed in various ways, such as by bolting.

The upward and downward angles of the solar cell module 11 can be adjusted by rotating the pinion gear 60 in the forward and reverse directions, .

10 and 11 are partially enlarged side views schematically showing a state in which an example rotation direction changeover stopper is rotated.

10 and 11, a rotation direction switching stopper 100 for switching the normal and reverse directions of rotation of the pinion gear 60 may be axially coupled to the inner upper portion of the rotation guide portion 40. As shown in FIGS.

The rear side of the rotation direction changeover stopper 100 is moved by the operator in the front and rear direction of the pinion gear 60 in the state where the front side of the rotation direction changeover stopper 100 is axially coupled to the inside upper side of the rotation guide portion 40 As shown in FIG.

7 to 9, the rear side of the rotation direction switching stopper 100 is provided on one side or the other side of the shaft 101 coupled to the front side of the rotation direction switching stopper 100, The front side of the lever member 102 can be connected integrally.

For example, a protruding member 110 contacting the teeth of the pinion gear 60 may be formed on the rear side of the rotation direction switching stopper 100.

The protruding member 110 may include an upper protruding member 111 and a lower protruding member 112.

The upper protruding member 111 may protrude upward in the backward direction of the rotation direction switching stopper 100.

The upper protruding member 111 is inclined upward toward the upper side of the rear direction of the rotation direction change stopper 100 from the lower portion of the upper protruding member 111 to the upper direction of the upper protruding member 111 have.

The lower protruding member 112 may protrude downward in the rear direction of the rotation direction change stopper 100. [

The lower protruding member 112 is inclined downward in the rear lower direction of the rotation direction switching stopper 100 from the upper portion of the lower protruding member 112 toward the lower direction of the lower protruding member 112 have.

12 and 13 are partially enlarged side views schematically showing the state in which the rotation direction changeover stopper of another example is rotated.

Next, as shown in FIG. 12 and FIG. 13, a slope 120 contacting the teeth of the pinion gear 60 may be formed on the rear side of the rotation direction changeover stopper 100.

The inclined surface 120 may include an upper inclined surface 121 and a lower inclined surface 122.

The upper inclined surface 121 may be formed on an upper rear side of the rotation direction change stopper 100.

The upper inclined surface 121 may be inclined downward in the rearward direction of the rotation direction stopper 100 from the upper portion of the upper inclined surface 121 toward the lower portion of the upper inclined surface 121.

The lower inclined surface 122 may be formed at a rear lower portion of the rotation direction change stopper 100.

The lower inclined surface 122 may be inclined upwards toward the upper side of the rear side of the rotation direction stopper 100 from the lower side of the lower inclined surface 122 toward the upper side of the lower inclined surface 122.

10 and 12, when the rear side of the rotation direction switching stopper 100 is rotated in the rearward direction of the pinion gear 60, the pinion gear 60 is rotated in the forward direction 10 and 12), the forward and reverse rotation of the pinion gear 60 causes the upstream and downstream shafts 50 to be gradually lowered (see arrows in solid arrows) .

11 and 13, in a state in which the rear side of the rotation direction stopper 100 is rotated in the forward direction of the pinion gear 60, the pinion gear 60 is rotated in a reverse direction 11 and 13), the upward and downward rotation of the pinion gear 60 causes the upward and downward rotation of the pinion gear 50 to be gradually raised (see arrows in FIG. 11 and FIG. 13) In particular, it is possible to effectively prevent the downward movement of the upper and lower shovel buckets 50 from being lowered.

FIG. 14 is a partially enlarged side view schematically showing a state in which a position fixing member is accommodated in a guide slit formed on the side surface of the horizontal support and the side surface of the rotation guide, and FIG. 15 is a partially enlarged plan view schematically showing the position fixing member.

As shown in FIG. 14, in the front side of the front side horizontal support 310 of the horizontal support 30 or on the front side of any one of the other side, Shaped guide slit 200 can be formed to extend vertically.

The guide slit 200 may be formed on the rear side or the back side of any one of the one side surface and the other side surface of the rotation guide portion 40.

The guide slit 200 may include a position fixing member 300 for fixing the rotation guide unit 40.

The position fixing member 300 includes a fixing bolt 301 horizontally received in the guide slit 200; And a nut 302 screwed on the opposite end of the fixing bolt 301 and fixed to the rear side of the other side of the rotation guide part 40.

16 is a partially enlarged plan view schematically showing a state in which a nut member is screwed to a shaft member formed on a side surface of the rotation guide portion;

16, a shaft member 400 (shown in FIG. 16) which is horizontally extended in the direction of the guide slit 400 and accommodated in the guide slit 400 is formed on one side surface of the rotation guide portion 40 and the other side of the other side surface Can be integrally formed.

A nut member 500 formed of a butterfly nut may be screwed to one side of the shaft member 400 and fixedly attached to one side of the front horizontal support member 310 of the horizontal support member 30.

FIG. 17 is a perspective view schematically showing a solar power generating structure having an angle adjusting function according to another embodiment of the present invention, FIG. 18 is a perspective view schematically showing a state where a fixing frame and a solar cell module are not provided on an upper part of a support, 19 is a side view of Fig.

17 to 19, the struts 20 are formed on the lower center line of the fixed frame 10, as shown in Figs. 17 to 19, And one side support 210 and the other side support 230 which are axially coupled to one side of the lower side of the fixed frame 10 and the other side of the lower side of the fixed frame 10, .

According to the present invention configured as described above, the up-and-down angle of the solar cell module 11 can be more easily adjusted through the up / down moving part 50 according to the sun height and position changed by the seasonality, (50) is located in the front direction of the strut (20) so as to be in line with the strut (20) while facing the strut (20) without being offset from the strut (20) 11) can be structurally supported more securely, and further, the structure is simple, and the manufacturing cost can be reduced.

10; Fixed frame, 20; landlord,
30; Horizontal support, 40; The rotation guide portion,
50; Shanghai East, 60; Pinion gear,
70; Position fixture.

Claims (8)

A fixed frame to which the solar cell module is fixed;
A support having an upper portion axially coupled to the stationary frame to be provided below the stationary frame;
A horizontal support fixed to the support to be provided in a lower direction of the fixed frame;
A rotation guide part that is axially coupled to the front side of the horizontal support and guiding the upward and downward rotational movement of the solar cell module so that the solar cell module is rotated up and down to adjust the angle,
A pair of second fixing holes provided on both sides of the rotary guide part at predetermined intervals in the vertical direction, the upper and lower movable parts being vertically movable in the vertical direction, the upper part being axially coupled to the fixed frame, Wow;
A pinion gear axially coupled to the inside of the rotation guide portion in a state of engagement with the rack gear of the up-and-down moving portion;
A position fixing unit inserted and fixed in any one of the first fixing holes of the rotation guide unit and the plurality of second fixing holes of the up-and-down moving unit such that the up-down and downward movement of the up-down and downward position-
Wherein a rear side of the pinion gear is rotatably moved in the forward and backward directions of the pinion gear in a state in which the front side is axially coupled to the inside of the rotation guide to switch the rotation direction of the pinion gear, The protruding member includes an upper protruding member formed in an upper portion of a rear side of the upper portion of the rear lower portion and a lower protruding member formed in an upper portion of the rear lower portion of the protruding member in a downward direction A direction changing stopper;
And a lever member connected to one side or the other side of the shaft coupled to the front side of the rotation direction changeover stopper to rotate the rear side of the rotation direction change stopper in the forward and backward directions of the pinion gear. Solar structure with function.
A fixed frame to which the solar cell module is fixed;
A support having an upper portion axially coupled to the stationary frame to be provided below the stationary frame;
A horizontal support fixed to the support to be provided in a lower direction of the fixed frame;
A rotation guide part that is axially coupled to the front side of the horizontal support and guiding the upward and downward rotational movement of the solar cell module so that the solar cell module is rotated up and down to adjust the angle,
A pair of second fixing holes provided on both sides of the rotary guide part at predetermined intervals in the vertical direction, the upper and lower movable parts being vertically movable in the vertical direction, the upper part being axially coupled to the fixed frame, Wow;
A pinion gear axially coupled to the inside of the rotation guide portion in a state of engagement with the rack gear of the up-and-down moving portion;
A position fixing unit inserted and fixed in any one of the first fixing holes of the rotation guide unit and the plurality of second fixing holes of the up-and-down moving unit such that the up-down and downward movement of the up-down and downward position-
Wherein a rear side of the pinion gear is rotationally moved in the forward and backward directions of the pinion gear in a state in which the front side is axially coupled to the inside of the rotation guide to switch the rotation direction of the pinion gear, Wherein the inclined surface includes an upper inclined surface formed at an upper portion of the rear side and inclined downward toward a lower portion of the rear side from an upper portion toward a lower portion and a lower inclined surface inclined upward upward from a lower portion toward an upper portion in a rear direction, Wow;
And a lever member connected to one side or the other side of the shaft coupled to the front side of the rotation direction changeover stopper to rotate the rear side of the rotation direction change stopper in the forward and backward directions of the pinion gear. Solar structure with function.
3. The method according to claim 1 or 2,
And a manual lever for rotating the pinion gear.
3. The method according to claim 1 or 2,
And a driving member for rotating the pinion gear.
3. The method according to claim 1 or 2,
Shaped guiding slits are formed on side surfaces of the horizontal support and side surfaces of the rotation guide,
And a position fixing member for fixing the rotation guide portion in a state of being accommodated in the guide slit.
3. The method according to claim 1 or 2,
An arc-shaped guide slit is formed on a side surface of the horizontal support,
Wherein a shaft member accommodated in the guide slit is formed on a side surface of the rotation guide portion, and a nut member is screwed to the shaft member. delete delete

Images