KR20210117855A - Photovoltaic apparatus with adjustable angle - Google Patents

Abstract

The present invention relates to a variable solar module support and, more specifically, to a variable solar module support which can change an angle of the solar module support to allow a solar module to be perpendicular to the sun. According to the present invention, a tilt-variable solar power generating device varies a tilt of a module holding unit to allow the solar module to be perpendicular to the sun according to an altitude of the sun which changes according to a season by using a rotation link rotatably installed in a second pillar, thereby increasing efficiency of a solar power generating device.

Description

Tilt variable solar power generator {Photovoltaic apparatus with adjustable angle}

The present invention relates to a variable inclination photovoltaic device, and more particularly, to a tiltable photovoltaic device capable of changing the angle of a photovoltaic module support so that the photovoltaic module is perpendicular to the sun.

In the conventional solar concentrator, cells and solar panels connected in series/parallel as needed are fixedly installed at an angle of about 30 to 40° toward the south. This is to produce maximum power by making the incident angle of sunlight and the solar panel at right angles in a fixed state. However, if we look at the altitude of the sun by season in Korea, the latitude is approximately 35°, so during the spring/autumn equinox the sun is at about 35°, during the winter solstice it is at about 12°, and at the summer solstice it changes at about 58°. do.

Therefore, the conventional solar panel is fixedly installed at an inclination of about 35° toward the south, so there is a problem in that the efficiency is low compared to the investment cost because the power production is low except for the spring/autumn equinox.

The support structure of the inclination variable photovoltaic device disclosed in Republic of Korea Patent Registration No. 10-1681308 is installed between a module frame to which a photovoltaic module is coupled and a support pillar installed vertically on the ground to adjust the inclination angle of the module frame and then the module In the support structure of the inclined mask type photovoltaic device for fixing and supporting the frame, three support columns are installed, and one support column installed in the center of the support columns has both sides directly and indirectly connected to the module frame and the support column, respectively. An angle adjusting member for adjusting the inclination angle of the module frame through length adjustment is installed.

In addition, the solar light collecting panel inclination angle adjusting device disclosed in Korean Patent Registration No. 10-1847293 includes a support installed vertically, a sub frame on which a solar light collecting panel is installed and rotatably fixed to the support by a hinge, and a sub frame A plurality of first fixing holes drilled at appropriate intervals on a circumference centered on a hinge rotatably fixed to a semi-circular fixing base fixed to the sub-frame and a fixing hole formed in the fixing table are formed around the hinge. A second fixing hole is formed in the support to form the same axis as the first fixing hole in the columnar track, and any one of the second fixing hole formed in the support and the plurality of first fixing holes formed in the fixing is fixed with a fastener to attach the fixing to the support. A fixing means for fixing is provided.

However, in the prior art as described above, since the solar module is supported by one support on both sides, the support is tilted or There is a problem of damage such as bending.

Accordingly, a structure capable of stably supporting the photovoltaic module against an external force and facilitating tilt adjustment is required.

Republic of Korea Patent No. 10-1681308 Republic of Korea Patent No. 10-1847293 Republic of Korea Patent No. 10-1438927

The present invention is to solve the conventional problems as described above, and to provide a tilt-variable solar power generator that improves the power generation efficiency of the photovoltaic device by adjusting the angle of the photovoltaic module according to the altitude of the sun that changes by season. There is a purpose.

In addition, another object of the present invention is to provide a tilt-variable photovoltaic power generation device in which a photovoltaic module can be stably supported even under adverse conditions such as typhoons and has improved durability against external force.

In order to achieve the above object, a tilt-variable solar power generation device according to the present invention comprises: a module holder on which a solar module is installed; A first post positioned below the module holder and rotatably connected to one side of the module holder, and the module holder rotated to be spaced apart from the first post from the lower side of the module holder in a vertical direction to support the a module holder supporting unit having a second post that is stretchable and stretchable in length; The other side of the module holder is pushed up or pulled downward to support the other side of the module holder so that the module holder can be rotated with respect to the first post, and is rotatably installed on the second post in the vertical direction. and an angle adjustment unit including a pivot link.

In addition, the first holding is a first fixing part fixed to the ground or the floor of the building, and the separation distance to the ground or the floor of the building is changed according to the position coupled to the first fixing part, and one side of the module holder is A second fixing part having a first height adjustment part for rotatably supporting it, and the second holding part being fixed to the ground or the floor surface of a building to be spaced apart in a direction in which the module holder is inclined, and a second fixing part to which the rotation link is rotatably coupled; , The support position of the module holder rotated by the rotation link is changed, and the separation distance to the ground or the floor surface of the building is variable according to the position coupled to the second fixing part, so that it is adjacent to the first height adjustment part and a second height adjustment unit for adjusting the height of the module holder so as to be positioned on the same line as the solar modules to be installed.

In addition, the angle adjustment unit is installed in the lower part of the other side of the module holder, and supports one end of the rotation link whose support position of the module holder is changed while rotating to push up or pull the module holder and support the end of the module holder. It may further include a movement limiting unit for limiting the movement range of the rotational link, and a link operation unit connected to the other end of the rotational link to rotate the rotational link up and down.

In addition, the link moving unit includes a screw fixing head rotatably installed on the rotatable link, a screw having one end rotatably installed on the screw fixing head in a longitudinal direction as an axis and having a thread formed on the outside, and the screw passes through A screw thread is formed therein to be coupled, and a screw inlet member is rotatably mounted up and down with respect to the second post to support the screw so that the screw moves linearly when the screw rotates in the longitudinal direction.

In addition, the first and second height adjustment units are separated from the ground or the floor surface of the building according to the height fixed at the upper portion of the first fixing unit or the second fixing unit, and the load supporting unit supporting the module holder A body, a height adjustment unit for fixing the position of the load support body coupled to the first fixing part or the second fixing part, and a fastening unit for rotatably fastening the module holder to the load support body are provided, respectively. do.

In addition, the load support body is equal to or larger than the width of the first or second fixing part facing each other and spaced apart from each other, and a pair of vertical plates positioned between the first or second fixing parts, and the vertical plate interconnecting the It is composed of a connecting plate, and a plurality of fixing holes penetrated to be spaced apart from each other in the vertical direction are respectively formed in a pair of vertical plates, and a fastening hole for fastening with the module holder is formed above the plurality of fixing holes, respectively. The height adjustment unit may be installed through the fixing hole and the first or second fixing part to fix the load supporting body to the first fixing part or the second fixing part.

The variable inclination photovoltaic device of the present invention supports the photovoltaic module, but the durability can be improved as resistance to external force is dispersed by the first post and the second post that are spaced apart from each other in the direction in which the photovoltaic module is inclined. .

In addition, in the tilt-variable solar power generation device of the present invention, the other side of the photovoltaic module is lifted upward or downward while the rotation link installed on the second post is rotated so that the photovoltaic module is rotated about the upper end of the first post as an axis. The inclination of the solar module can be varied as it is pulled, so there is an advantage in that it is easy to manipulate the inclination of the solar module.

1 is a partial exploded perspective view of a tilt-variable solar power generation device according to a first embodiment of the present invention;
Figure 2 is an enlarged perspective view showing an enlarged part of the tilt-variable solar power generation device of Figure 1,
3 is an exploded perspective view of the first or second height adjustment unit of the tilt-variable solar power generation device of FIG. 1;
Figure 4 is a partial exploded perspective view of the angle adjustment unit of Figure 1,
5 is a side cross-sectional view showing the operating state of the inclination variable solar power generation device of FIG. 1,
6 is a partial exploded perspective view showing the side of the second height adjustment unit supporting the module holder of the inclination variable solar power generation device according to the second embodiment of the present invention,
7 is a partial exploded perspective view showing the side of the second height adjustment unit supporting the module holder of the inclination variable solar power generation device according to the third embodiment of the present invention,
8 is a partial exploded perspective view showing the side of the second height adjustment unit supporting the module holder of the inclination variable solar power generation device according to the fourth embodiment of the present invention,
9 is a partial exploded perspective view of a tilt-variable solar power generation device according to a fifth embodiment of the present invention;
10 is a side view showing an operating state of the tilt-variable solar power generator of FIG. 9;
11 is a partial exploded perspective view showing the side of the second height adjustment unit supporting the module holder of the inclination variable solar power generation device according to the sixth embodiment of the present invention;
12 is a partial cross-sectional view showing the second height adjustment unit side of the tilt-variable solar power generation device according to the seventh embodiment of the present invention.

Hereinafter, with reference to the accompanying drawings, it will be described in detail with respect to a tilt-variable solar power generation device according to a preferred embodiment of the present invention.

1 to 5 show a tilt-variable solar power generator 1 according to a first embodiment of the present invention.

The inclination variable photovoltaic power generation device 1 according to the first embodiment of the present invention includes a module holder 3 on which a photovoltaic module 2 is installed, and a module holder located below the module holder 3 . One side of (3) can support the first post 40 rotatably connected, and the module holder 3 that is spaced apart from the first post 40 below the module holder 3 and rotated to be inclined. It includes a module holder support unit 4 having a second post 50 that can be stretched and contracted in length in the vertical direction so that it can be rotated and an angle adjustment unit 6 for adjusting the angle by rotating the module holder 3 .

The module holder 3 supports the solar module 2 . The module holder 3 includes a plurality of first mounting frames 31 spaced apart from each other and a plurality of second mounting frames 32 extending to interconnect the spaced apart first mounting frames 31 . .

The first mounting frame 31 is formed to extend in the front-back direction, which is the direction in which the first post 40 and the second post 50 are spaced apart from each other, and is formed in a rectangular tube shape with an empty interior. On both sides of the first mounting frame 31 in a direction perpendicular to the front-rear direction, a plurality of adjustment holes 31a are formed to be spaced apart from each other and penetrate in the longitudinal direction of the first mounting frame 31 .

The second mounting frame 32 is formed to extend in the left-right direction, which is a direction orthogonal to the front-rear direction.

The module holder support unit 4 is positioned below the module holder 3 to support the module holder 3 . The module holder support unit 4 is rotatable and supports the module holder 3 at an angle. When the sun and the photovoltaic module 2 are perpendicular to each other, the power generation efficiency of the photovoltaic module 2 is maximized. By supporting it differently, the angle can be adjusted so that the solar module 2 is perpendicular to the sun.

The module holder support unit (4) is located below the module holder (3), and one side of the module holder (3) is rotatably connected to the first post (40) and the module holder (3) from below. It is provided with a second post 50 that can be extended and contracted in length in the vertical direction so as to support the module holder 3 that is spaced apart from the first post 40 in the front-rear direction and rotated obliquely.

The first post 40 is installed on the ground or the floor surface of the building so that the upper end is located below the upper end of the second post 50, the front end of the module holder 3 is located below the rear end of the module holder Support the front end of (3). The first post 40 is hinge-coupled with the module holder 3, so that the module holder 3 can rotate up and down about the upper end of the first post 40 as an axis. The first post 40 supports the front end sides of the plurality of first mounting frames 31 , respectively.

The second post 50 is installed on the ground or the bottom so that the upper end is positioned above the upper end of the first post 40 , and supports the rear end of the module holder 3 . The second post 50 is vertically extendable in length so as to support the module holder 3 that is spaced apart from the first post 40 and rotated to be inclined. The second post 50 supports the rear end side of the plurality of first mounting frames 31 , respectively.

The first post 40 has a first fixing part 41 fixed to the ground or the building floor surface, and the separation distance with respect to the ground or the building floor surface is changed according to the position coupled to the first fixing part 41, and the module A first height adjustment part 42 for rotatably supporting one side of the mounting part 3 is provided.

The first fixing part 41 is mounted to protrude upward from the ground or the floor surface of the building, and the first height adjusting part 42 is installed on the upper part of the first fixing part 41 . The first fixing part 41 has a rectangular tube shape, and may be fixed to the ground or the floor surface of a building by various methods, such as embedding, concrete pouring, and bolt construction.

The module holder 3 has a front end hinged to the first height adjustment part 42 so that it can be rotated up and down.

In the photovoltaic device according to the first embodiment of the present invention, when the top heights between the first fixing parts 41 adjacent in the left and right directions are not the same, the first height adjustment coupled to the first fixing part 41 is adjusted. By adjusting the coupling position of the part 42, the front end side of the module holder 3 by adjusting the height of each upper end of the plurality of first posts 40 to be positioned on the same line to the left and right is a plurality of first height adjustment parts (42) can be supported so as to be horizontal in the left and right direction.

The second post 50 has a second fixing part 51 fixed to the ground or the floor of the building, and the separation distance with respect to the ground or the floor of the building is changed according to the position coupled to the second fixing part 51, and the module A second height adjustment unit 52 for rotatably supporting one side of the mounting unit 3 is provided.

The second fixing part 51 is mounted to protrude upward from the ground or the floor surface of the building, and the second height adjusting part 52 is installed on the upper part. The second fixing part 51 has a rectangular tube shape, and may be fixed to the ground or the floor surface of a building by various methods such as embedding, concrete pouring, and bolt construction.

The module holder 3 has a rear end, that is, the other side is hinged to the second height adjustment unit 52 so that it can be rotated up and down around the second height adjustment unit 52 .

By adjusting the coupling position of the second height adjusting unit 52 coupled to the second fixing unit 51 , the second height adjusting unit 52 is connected to the module holder 3 .

In the photovoltaic device according to the first embodiment of the present invention, when the top heights between the second fixing parts 51 adjacent in the left and right directions are not the same, the second height is coupled to each of the second fixing parts 51 . By adjusting the coupling position of the adjusting unit 52, the rear end side of the module holder 3 is adjusted to a plurality of second heights by adjusting the height of each upper end of the plurality of second posts 50 to be located on the same line from side to side. The part 52 may be supported so as to be horizontal in the left and right directions.

The first and second height adjustment units 42 and 52 vary the separation distance from the ground or the floor of the building according to the height fixed at the top of the first or second fixing units 41 and 51, and are mounted on the module. The load support body 45 and 55 for supporting the part 3, the height adjustment unit 46 and 56 for fixing the position of the load support body 45 and 55, and the load support body 45 ( 55) is provided with fastening units 47 and 57 for rotatably fastening the module holder 3 to each other.

The load support body 45, 55 has a rectangular tube shape surrounding the first or second fixing parts 41 and 51 so as to be movable in the vertical and vertical directions, and upwardly so as to be parallel to the upper ends of both sides facing in the left and right directions. A pair of fastening pieces that protrude are formed.

For convenience of explanation, both sides of a pair of fastening pieces and a pair of fastening pieces connected to extend are called vertical plates 45a and 55a, and both sides of the square tube connecting the vertical plates 45a and 55a. And the upper surface of the square tube is referred to as the connecting plate (45b, 55b).

The load supporting body 45, 55 is a pair of vertical plates 45a and 55a facing each other and spaced apart from each other equal to or larger than the width of the first or second fixing parts 41 and 51, and the vertical plate ( 45a and 55a are composed of connecting plates 45b and 55b interconnecting each other.

The first or second fixing parts 41 and 51 are positioned between a pair of vertical plates 45a and 55a perpendicular to the ground or floor, and a pair of vertical plates 45a and 55a are The vertical plates 45a and 55a are spaced apart from each other by connecting plates 45b and 55b that interconnect each other.

A plurality of fixing holes 45c and 55c penetrated to be spaced apart from each other in the vertical direction for fixing with the fixing parts 41 and 51 are formed in the pair of vertical plates 45a and 55a, respectively, and a plurality of fixing holes 45c and 55c are respectively formed. Fastening holes 45d and 55d for fastening with the module holder 3 are formed through the upper portions of the balls 45c and 55c, respectively.

The connecting plates 45b and 55b are first connecting plates 45x and 55x connecting a pair of vertical plates 45a and 55a from the side surfaces of the first or second fixing parts 41 and 51 and , The second connecting plate 45y extending horizontally from the upper part of the first or second fixing part 41, 51 to the ground or the floor surface of the building to connect the pair of vertical plates 45a and 55a ( 55y) is provided.

The height adjustment units 46 and 56 are fixed bolts 46a and 56a passing through the first or second fixing parts 41 and 51 and the fixing holes 45c and 55c, and the fixing bolts 46a. Fixing nuts 46b and 56b for constraining the 56a are provided. The fixing bolts 46a and 56a are installed through the first or second fixing parts 41 and 51 and the fixing holes 45c and 55c to support the load supporting body 45 and 55 with the first or second fixing bolts. 2 It is fixed to the fixing part (41) (51).

Referring to FIG. 3 , the first fixing part 41 is formed so that the fixing bolts 46a of the first height adjustment part 42 can pass through both sides of the first fixing part 41 in the left and right directions, and spaced apart from each other at regular intervals in the vertical direction. A plurality of first bolt through-holes 41a are formed, respectively. In addition, the second fixing part 51 is formed so that the fixing bolts 56a of the second height adjustment part 52 can pass through both sides of the second fixing part 51 in the left and right directions, and a plurality of first fixing parts spaced apart from each other at regular intervals in the vertical direction are formed. Two bolt through-holes (51a) are respectively formed.

On the other hand, when the module holder 3 is rotated in the vertical direction, the height adjustment unit 56 of the second height adjustment unit 52 is the second fixing unit by the distance vertically moved while the module holder 3 is rotated. By fixing the load support body 55 of the second height adjustment part 52 moved vertically in (51), the module holder 3 is supported even in the rotated position.

The fastening units 47 and 57 are fastening bolts 47a and 57a and fastening bolts 47a and 57a passing through the fastening holes 45d and 55d and the adjusting hole 31a of the module holder 3 . A fastening nut (47b) (57b) for restraining is provided. The fastening units 47 and 57 are installed through the fastening holes 45d and 55d and the module holder 3, and the module holder 3 is installed in the vertical direction with respect to the load support body 45 and 55. It is rotatably fastened to support.

On the other hand, the fastening unit 57 of the second height adjustment unit 52 is located on a vertical line with the second post 50 among the plurality of adjustment holes 31a according to the angle of the module holder 3 , the adjustment hole 31a ) and the adjustment hole 31a and is fastened through the fastening hole 55d.

The first and second height adjustment units 42 and 52 are installed adjacent to each other so that the photovoltaic modules 2 of the photovoltaic device 1 according to the present invention are positioned on the same line as the module holder 3 adjust the height of

The angle adjustment unit 6 elevates or lowers the other side of the module holder 3 so that the module holder 3 rotates with respect to the first post 40 to adjust the inclination of the solar module 2 . .

The angle adjustment unit 6 pushes up the other side of the module holder 3 upward or pulls it downward so that the module holder 3 can be rotated with respect to the first post 40, the module holder 3 support the other side of The angle adjusting unit 6 is installed in the lower part of the other side of the rotation link 60 and the module holder 3 to be rotatably installed in the vertical direction on the second post 50, one end of the rotation link 60 A movement limiting unit 70 that supports and limits the range of movement of the rotation link 60 with respect to the module holder 3, and a link connected to the other end of the rotation link 60 to rotate the rotation link 60 up and down A movable unit (80) is provided.

One side of the rotation link 60 is connected to the movement limiting unit 70 , and the other side is provided with a link operation unit 80 . The rotation link 60 is installed rotatably up and down on the second fixing part 51 . The rotation link 60 and the movement limiting unit 70 are respectively installed on the plurality of first mounting frames 31 . The pivoting links 60 are interconnected by a connecting bar 62 extending in the left and right direction. Therefore, when one rotational link 60 is rotated by the link operation unit 80, the module holder 3 is rotated while the other rotational links 60 are also operated in the same manner.

The rotation link 60 is formed with a protruding bar (not shown) protruding apart from each other in the left and right directions from both sides in the left and right directions of one end, and the protruding bar (not shown) is connected to the movement limiting unit 70 .

The protrusion bar (not shown) has a follow wheel 61 rotatably mounted thereon as shown in FIG. 4 , thereby reducing friction when the rotation link 60 moves along the movement limiting unit 70 .

The movement limiting unit 70 penetrates the pair of guide frames 71 into which the follow wheel 61 is introduced, and the pair of guide frames 71 so that the follow wheel 61 does not deviate from the guide frame 71 . It is provided with a limiting bolt 72, and a limiting nut (73) coupled to the limiting bolt (72).

A pair of guide frames 71 form a space in which the follow wheel 61 can be moved in, preferably a pair of C-shaped steels are applied. The pair of guide frames 71 are installed in a direction in which the introduced portions face each other. The follow wheel 61 is moved to the retracted portion of the pair of guide frames 71 . The movable range of the module holder 3 varies according to the length of the guide frame 71 , and the length of the guide frame 71 may vary depending on the environment.

The limit bolt 72 and the limit nut 73 are installed at both ends of the pair of guide frames 71 to prevent the follow wheel 61 from being separated from the guide frame 71 .

The link movable unit 80 includes a screw fixing head 81 rotatably installed at the other end of the rotation link 60 , and one end of the screw fixing head 81 , rotatably installed in the longitudinal direction as an axis, and has a thread on the outside. The formed screw 82 and the screw 82 have a thread formed therein so that the screw 82 is through-coupled to support the screw 82 so that the screw 82 moves linearly when the screw 82 rotates in the longitudinal direction as an axis. 2 A screw-in member 83 that is mounted rotatably up and down with respect to the second post 50, and a fixing body 84 and a screw 82 for rotatably fixing the screw-in member 83 to the second post 50 ) is provided with a handle 85 for rotating.

The link operation unit 80 is any one of the second posts located on the inside of the plurality of second posts 50 spaced apart from each other in the left and right direction to be located in the center of the module holder 3 of the rear end of the module holder 3 (50) is installed in the second fixing portion 51 to rotate the rotation link 60 in the vertical vertical direction. The rotation link 60 rotated by the link operation unit 80 applies rotational force to the second post 50 located at both ends in the left and right directions of the module holder 3 through the connection bar 62, respectively. 60) to the

The screw fixing head 81 is installed rotatably up and down at the other end of the rotation link 60 so that the rotation link 60 is rotated around a part connected to the second post 50 when rotating. No restrictions on movement

The screw 82 is threaded on the outside, and one side of the screw 82 is rotatably installed in the screw fixing head 81 in the longitudinal direction of the screw 82, so that the screw 82 is rotated in a clockwise or counterclockwise direction. Rotation is not restricted. A handle 85 for rotating the screw 82 may be provided on the other side of the screw 82 .

The screw 82 is through-coupled to the screw-in member 83 , and a screw thread is formed inside the screw-in member 83 , so that the screw 82 is rotated while the screw 82 is coupled to the screw-in member 83 . ) is linearly moved in the axial direction of the screw 83 by the screw inlet member 83 .

The screw 82 makes a linear motion and rotates the rotation link 60 , and as the rotation link 60 rotates, the module holder 3 rotates up and down to change the inclination of the solar module 2 .

The link operation unit 80 may be provided with a fixing body 84 that allows the screw-in member 83 to perform vertical vertical rotation while fixing the screw-in member 83 to the second post 50 at the same time.

The variable inclination type photovoltaic power generation device 1 having the configuration as described above above supports the photovoltaic module 2, but the first post 40 and the second spaced apart from each other in the direction in which the photovoltaic module 2 is inclined. As the resistance to the external force is distributed by the post 50 , the durability may be improved.

In addition, the tilt-variable solar power generation device 1 according to the first embodiment of the present invention is installed on the second post 50 so that the solar module 2 is rotated about the upper end of the first post 40 as an axis. As the rotation link 60 is rotated, as the other side of the solar module 2 is lifted upward or pulled downward, the inclination of the solar module 2 can be changed, so that the inclination operation of the solar module 2 is difficult. It has the advantage of being easy.

Meanwhile, FIG. 6 shows a tilt-variable solar power generation device according to a second embodiment of the present invention. Components having the same functions as in the drawings shown above are denoted by the same reference numerals, and detailed descriptions thereof will be omitted.

Referring to FIG. 6 , the tilt-variable solar power generation device according to the second embodiment of the present invention has the same structure as the tilt-variable solar power generation device according to the first exemplary embodiment of the present invention except for the module holder 203 . have

The module holder 203 supports the solar module. The module holder 203 is the same as the structure of the module holder 3 according to the first embodiment of the present invention, except for the adjustment hole 231a of the first mounting frame 231 .

The adjustment hole 231a is formed through a long hole extending along the longitudinal direction of the first mounting frame 231 on both sides of the first mounting frame 231 in a direction orthogonal to the front-rear direction. The adjustment holes 231a are respectively drawn upwards at the top and are arranged in the longitudinal direction so that they can be mounted on the second post 50 according to the inclination angle of the module holder 203. A plurality of holding grooves 231b. this is formed

The adjustment hole (231a) is located at the vertical upper end of the second post (50). The holding groove 231b formed in the adjustment hole 231a is seated on the second post 50 so that the second post 50 supports the load of the module holder 203 .

A plurality of holding grooves 231b are formed in the adjusting hole 231a, so that the second post 50 among the plurality of holding grooves 231b of the adjusting hole 231a according to the inclination changed while the module holder 203 is rotated. ), the fastening bolt 57a of the second post 50 enters the holder groove 231b positioned vertically above, and the inclination of the module holder 203 is maintained.

In the tilt-variable solar power generation device according to the second embodiment of the present invention, a plurality of mounting grooves 231b can be moved in a state in which the fastening unit 57 of the second post 50 penetrates the adjustment hole 231a. Thus, it is possible to adjust the inclination of the solar module without disassembling the fastening unit 57 from the solar module.

Meanwhile, FIG. 7 shows a tilt-variable solar power generation device according to a third embodiment of the present invention. Components having the same functions as in the drawings shown above are denoted by the same reference numerals, and detailed descriptions thereof will be omitted.

Referring to FIG. 7 , the tilt-variable solar power generation device according to the third embodiment of the present invention is a tilt-variable solar power generation device according to the first embodiment of the present invention except for the first post 340 and the second post 350 . It has the same structure as the photoestrus device (1).

The first post 340 includes a first fixing part 341 and a first height adjusting part 342 , and the second post 350 has a second fixing part 351 and a second height adjusting part ( 352) is provided.

The first fixing part 341 and the second fixing part 351 according to the third embodiment of the present invention do not have the first and second bolt through holes 41a and 51a of the first embodiment of the present invention. Except that, the first fixing part 41 and the second fixing part 51 are the same.

The first and second height adjustment units 342 and 352 have the same configuration.

The first and second height adjustment units 342 and 352 vary the separation distance from the ground or the building floor according to the height fixed at the top of the first or second fixing units 341 and 351, and the module is mounted The position of the load support body 345, 355 for supporting the part 3 (see FIG. 1), and the load support body 345, 355 coupled to the first or second fixing parts 341 and 351 A height adjustment unit for fixing the 346 and 356, and fastening units 347 and 357 for rotatably fastening the module holder 3 to the load support body 345 and 355 are provided, respectively.

The load support body 345, 355 of the first or second height adjustment part 342, 352 is a circular frame (345a) surrounding the first or second fixing part 341, 351 in a square tube shape. 355a), and the circumferential frame (345a) (355a) and the circumferential frame (345a) (355a) and the spaced apart vertical plate member (345b) (355b) so that the module holder 3 can be disposed between the spaced apart and, A fixing hole (not shown) that connects the circumferential frame (345a) (355a) and the vertical plate (345b) (355b) and is formed to pass through to fix the relative position with the first fixing part 341 or the second fixing part 351 (not shown). ) is provided with a horizontal plate member (345c) (355c) formed, and an extension frame (355d) (355d) extending vertically downward from the lower end of the circumferential frame (345a) (355a), respectively.

The circumferential frame (345a) of the first height adjustment part 342 is moved in the vertical direction along the first fixing part 341 penetrated into the interior. The circumferential frame (355a) of the second height adjustment part 352 is moved in the vertical direction along the second fixing part 351 penetrating into the interior.

The vertical plates 345b and 355b of the first and second height adjustment parts 342 and 352 have fastening holes 345e and 355e formed to pass through for fastening with the module holder 3, respectively. . So that the module holder 3 can be installed on the vertical plates 345b and 355b by the fastening units 347 and 357 to be described later, the vertical plates 345b and 355b are circumferential frames (345a) (355a). It is spaced apart from the doedoe wider than the width of the module holder (3).

Fixing holes (not shown) through which the height adjustment units 346 and 356 pass are respectively formed in the horizontal plates 345c and 355c of the first and second height adjustment units 342 and 352 .

The module holder 3 is supported by the fastening units 347 and 357, or a part of the module holder 3 is in contact with the horizontal plates 345c and 355c, so that the load of the module holder 3 is applied to the fastening unit. (347) (357) and the horizontal plate members (345c, 355c) can be distributed and supported.

The first and second height adjustment units 342 and 352 of the height adjustment units 346 and 356 are horizontal plates 345c and 355c in the upper portion of the first or second fixing portions 341 and 351 . Support frames 346a and 356a protruding to be positioned vertically downward, and height adjustment bolts 356b penetrating vertically through support frames 346a and 356a and horizontal plates 345c and 355c, and horizontal The position of the body fixing nuts 346c and 356c for fixing the height adjustment bolts 346b and 356b in the lower part of the plate 355b, and the height adjustment bolts 346b and 356b on the support frames 346a and 356a. A plurality of frame fixing nuts (346d) ( 356d) respectively.

The support frames 346a and 356a of the first and second height adjustment units 342 and 352 have a plate shape in which the upper portion is bent and bent vertically, respectively. One side of the support frames 346a and 356a protrudes in a lateral direction perpendicular to the longitudinal direction of the first fixing part 341 or the second fixing part 351, and the other side of the first fixing part 341 or the second fixing part 341 2 It is fixed in close contact with the fixing part (351).

The height adjustment bolts 346b and 356b of the first and second height adjustment units 342 and 352 are horizontal plates 345c and 355c, and the first fixing portions 341 of the support frames 346a and 356a. ) vertically penetrates one side protruding from the second fixing part 351 .

The height adjustment bolts 346b and 356b of the first and second height adjustment parts 342 and 352 are the body fixing nut 346c) ( 356c) by means of a plurality of frame fixing nuts 346d and 356d that are fixed to the horizontal plate members 345c and 355c, and the lower portions are screwed in close contact with the upper and lower surfaces of the support frames 346a and 356a. It is fixed at (346a) (356a).

When adjusting the height of the load support body 345 and 355 of the first and second height adjustment units 342 and 352, the height adjustment units 346 and 356 are removed from the load support body 345 and 355. Without the need to disassemble, it is possible to adjust the height of the load support body (345, 355) by rotating the frame fixing nuts (346d) (356d) to change the position of the height adjustment bolts (346b, 356b).

The fastening units 347 and 357 of the first and second height adjustment units 342 and 352 have fastening holes 345f and 355f formed on the upper ends of the vertical plates 345b and 355b, and the first mounting frame. (31) and the fastening bolts (347a) (357a) passing through; It is provided with fastening nuts (347b) (357b) which are screwed to the ends of the fastening bolts (347a) (357a) protruding through the first mounting frame (31) to constrain the fastening bolts (347a) (357a).

Meanwhile, FIG. 8 shows a tilt-variable solar power generation device according to a fourth embodiment of the present invention.

Referring to FIG. 8 , the tilt-variable solar power generation device according to the fourth embodiment of the present invention is a tilt-variable type according to the first embodiment of the present invention except for the first and second height adjustment units 442 and 452 . It has the same structure as the photovoltaic device (1).

The first and second height adjustment units 442 and 452 are separated from the ground or the building floor according to the height fixed at the upper portion of the first or second fixing units 41 and 51, and are mounted on the module. Height adjustment for fixing the position of the load support body (445, 455) for supporting the part (3) and the load support body (445, 455) coupled to the first or second fixing part (441, 451) It includes units 446 and 456 and fastening units 447 and 457 for rotatably fastening the module holder 3 to the load supporting body 445 and 455 .

The load support body 445, 455 of the first and second height adjustment parts 442 and 452 is a circumferential frame (445a) surrounding the first or second fixing part 41, 51 in a square tube shape. 455a) and the round frame (445a) (455a) and the vertical plates (445b) (455b) spaced apart from each other, and the round frame (445a) (455a) and the vertical plate (445b) (455b) are connected to be spaced apart from each other. Plates 445c and 455c are provided.

The circumferential frame (445a) of the first height adjustment part 442 is moved in the vertical direction along the first fixing part 41 penetrated inside. The circumferential frame (455a) of the second height adjustment part 452 is moved in the vertical direction along the second fixing part 51 penetrated inside.

The circumferential frame (445a) (455a) of the first and second height adjustment parts (442, 452) is bolted to the first or second fixing part (41) (51) to fix the position, in the vertical direction. It has a plurality of body fixing holes (445e, 455e) penetrated in the right teeth spaced apart from each other.

Between the circumferential frame (445a) (455a) and the vertical plate member (445b) (455b), the first mounting frame 31 (see FIG. 1) can be disposed, the vertical plate member (445b) (455b) is the first mounting It is spaced apart from the circumferential frame (445a) (455a) by the width of the frame (31).

The fastening units 447 and 457 are first fastening holes 445f and 455f formed on the upper end of the vertical plate 455b, the first mounting frame 31, and the first fastening holes 445f and 455f. Fastening bolts (447a) (457a) penetrating through the second fastening holes (445g) (455g) formed through the circumferential frame (445a) (455a) of the corresponding position; It is screwed to the ends of the fastening bolts (447a) (457a) protruding from the circumferential frame (445a) (455a) and includes a fastening nut (447b) (457b) for constraining the fastening bolts (447a) (457a).

The module holder 3 is supported by the fastening units 447 and 457, or a part of the module holder 3 is in contact with the connecting plates 445c and 455c so that the load of the module holder 3 is applied to the fastening unit. (447) (457) and the connecting plate (445c, 455c) can be dispersed and supported.

Meanwhile, FIGS. 9 and 10 show a tilt-variable solar power generation device according to a fifth embodiment of the present invention.

The tilt-variable solar power generation device according to the fifth embodiment of the present invention is a tilt-variable solar power generator according to the first embodiment of the present invention except for the module holder 503 and the second height adjustment unit 550 ( It has the same structure as 1).

The module holder 503 supports the solar module 2 . The module holder 503 includes a plurality of first mounting frames 531 spaced apart from each other and a plurality of second mounting frames 32 extending to interconnect the spaced apart first mounting frames 531 to each other. .

The first mounting frame 531 is formed to extend in the front-rear direction, and unlike the first embodiment of the present invention, one adjustment hole (not shown) is formed in the first mounting frame 531 .

The second height adjustment unit 552 is a load supporting body 555 that supports the module holder 503 and the separation distance to the ground or the building floor is changed according to the height fixed at the top of the second fixing unit 51 . ), a height adjustment unit (56) for fixing the position of the load support body (555) coupled to the second fixing part (51), and the module holder (503) to the load support body (555) is rotatably fastened It is provided with a fastening unit (557).

The load support body 555 has a rectangular tube shape in which the lower part surrounds the second fixing part 51, and on the outside of the load support body 555 in the left and right direction of the module holder 503, it protrudes upward from the upper end. A piece 555b is formed.

For convenience of explanation, one side on which the fastening piece 555b is formed on the upper end of the left and right side surfaces of the load supporting body 555 is called a first vertical plate 555a, and the other side is called a second vertical plate (not shown). , The front and rear both sides of the load support body 555 connecting the first vertical plate 555a and the second vertical plate (not shown) are referred to as the connecting plate 555c.

The load support body 555 includes a first vertical plate 555a and a second vertical plate (not shown) facing each other that are equal to or larger than the width of the second fixing part 51, and a first vertical plate 555a. and a connecting plate 555c that interconnects the second vertical plate (not shown), and the inclined plate 555d that is installed on the first vertical plate 555a and protrudes obliquely with respect to the first vertical plate 555a. be prepared

The first vertical plate 555a and the second vertical plate (not shown) are spaced apart from each other by the connecting plate 555c, and between the first vertical plate 555a and the second vertical plate (not shown), a second high Government 51 is located.

9, the first vertical plate 555a fastened to the left end of the module holder 503 and the first vertical plate 555a fastened to the right end of the module holder 503 are each 2 is formed to protrude vertically upward than the vertical plate member (555b).

A plurality of fixing holes 555e penetrated to be spaced apart from each other in the vertical direction for fixing with the second fixing part 51 are respectively formed in the first vertical plate 555a and the second vertical plate (not shown).

The inclined plate member (555d) is provided with a plurality of fastening holes (555f) formed to be spaced apart from each other along the rotational trajectory of the first mounting frame (531). The inclined plate member 555d is installed on the first vertical plate member 555a. The inclined plate 555d is fastened to one of the plurality of fixing holes 555e, so that the vertical height with respect to the ground or the floor of the building may be adjusted.

The first vertical plate 555a protrudes from the first vertical plate 555a in order to fix the inclination of the inclined plate 555d to form an inclined support protrusion 555g for supporting the inclined plate 555d. The inclined support lead-in groove 555h formed to be drawn in from the inclined plate member 555d may be provided in the 555d to avoid interference with the inclined support protrusion piece 555g.

The fastening unit 557 includes a fastening bolt 557a for fastening the inclined plate member 555d and the first mounting frame 531 and a fastening nut 557b for constraining the fastening bolt 557a.

The fastening unit 557 penetrates the fastening hole 555f and the first mounting frame 531 at positions corresponding to the rotated first mounting frame 531 among the plurality of fastening holes 555f formed in the inclined plate 555d. It is installed to support the module holder (503).

Unlike the fifth embodiment, the above-described inclined plate material may be applied to the load supporting body of the second height adjustment unit applied to the third and fourth embodiments.

11 shows a tilt-variable solar power generation device according to a sixth embodiment of the present invention.

In the tilt-variable solar power generation device according to the sixth embodiment of the present invention, a pair of inclined plate members 655c are provided on the second height adjustment unit 652 , and the first mounting frame 631 of the module holder 603 is provided. ) has the same structure as the inclination variable photovoltaic device 501 according to the fifth embodiment of the present invention, except that the photovoltaic module 2 is installed to be spaced apart.

The inclined plate members 655c are respectively installed on the first and second vertical plates 555a and 555b, and protrude obliquely with respect to the first or second vertical plates 555a and 555b. The inclined plate member 655c strongly supports the module holder 603 by protruding from the first and second vertical plate members 555a and 555b, respectively.

The first mounting frames 631 located at both ends in the left and right directions of the module holder 603 are spaced apart from each other in the left and right directions with respect to the adjacent solar module 2 , and the inclined plate 655c interferes with the solar module 2 . It can be fastened to the module holder 603 without generating a .

12 shows a tilt-variable solar power generation device according to a seventh embodiment of the present invention.

The tilt-variable solar power generation device according to the seventh embodiment of the present invention is a tilt-variable solar power generation device according to the first embodiment of the present invention, except for the second fixing part 751 and the second height adjusting part 752 . It has the same configuration as (1).

The second fixing part 751 has a lower part fixed to the ground or a building floor surface, and an upper part is sealed.

The second height adjustment unit 752 includes a load support body 55, a height adjustment unit 56 for fixing the position of the load support body 55, a fastening unit 57, and a main body transfer spring (756d) and , and a spring guide 756c.

The main body transfer spring 756d is in the form of a coil spring, and one end is in contact with the lower surface of the second connecting plate 55y and the other end is in contact with the upper surface of the second fixing unit 751, and the module holder 3 rotates and rises by the elastic force. When the module holder 3 is raised, the load supporting body 55 is raised by the vertical height.

The spring guide (756c) protrudes downward from the lower surface of the second connecting plate member (55y) and penetrates the upper surface of the main body feed spring (756d) and the second fixing part (751) to determine the lengthwise expansion and contraction direction of the main body feed spring (756d). Guide in the vertical up-down direction.

The spring guide 756c protrudes vertically downward from the second connecting plate 55y and penetrates the upper surface of the second fixing part 751 and is introduced into the inner space of the second fixing part 751 . The length of the spring guide (756c) is extended to maintain a state penetrating the upper surface of the second fixing part (751) within the rotation angle range of the module holder (3).

The body feed spring 756d is formed to surround the spring guide 756c, and elevates the load support body 55 by elastic force so that the load support body 55 comes into contact with the module holder 3 without separate manipulation. do.

In the tilt-variable solar power generation device according to the seventh embodiment of the present invention, when the module holder 3 is rotated, the load support body 55 is maintained in contact with the module holder 3, so the tilt control operation efficiency is improved. do.

Although the tilt-variable solar power generation device according to the present invention described above has been described with reference to the accompanying drawings, this is only exemplary, and those of ordinary skill in the art may make various modifications and equivalent other embodiments therefrom. You will understand that it is possible.

Accordingly, the scope of true technical protection of the present invention should be defined only by the technical spirit of the appended claims.

1: Tilt variable solar power generation device 2: Solar module
3: module holder 4: module holder support unit
6: Angle adjustment part

Claims (7)

a module holder on which a solar module is installed;
A first post positioned below the module holder and rotatably connected to one side of the module holder, and the module holder rotated to be spaced apart from the first post from the lower side of the module holder in a vertical direction to support the a module holder supporting unit having a second post that is stretchable and stretchable in length;
The other side of the module holder is pushed up or pulled downward to support the other side of the module holder so that the module holder can be rotated with respect to the first post, and is rotatably installed on the second post in the vertical direction. and an angle adjustment unit including a pivot link;
The first holding is
A first fixing part fixed to the ground or the floor surface of the building, and the separation distance with respect to the ground or the building floor varies according to a position coupled to the first fixing part, and a first for rotatably supporting one side of the module holder Equipped with a height adjustment unit,
The second holding is
A second fixing part fixed to the ground or the floor surface of the building so that the module holder is spaced apart from each other in an inclined direction and the rotation link is rotatably coupled, and the support position of the module holder rotated by the rotation link is changed, and the The height of the module holder so that the separation distance with respect to the ground or the floor surface of the building is variable according to the position coupled to the second fixing unit to be located on the same line with the solar modules installed adjacently together with the first height adjustment unit A tilt-variable solar power generation device, characterized in that it comprises a second height adjustment unit for adjusting the. According to claim 1, wherein the angle adjustment unit
It is installed in the lower part of the other side of the module holder, and supports one end of the rotation link in which the support position of the module holder is changed while rotating to push up or pull the module holder, and the range of movement of the rotation link with respect to the module holder A movement limiting unit that limits
Further comprising a link movable unit connected to the other end of the rotary link to rotate the rotary link up and down,
The link operation unit is
A screw fixing head rotatably installed on the rotation link, a screw having one end rotatably installed on the screw fixing head in the longitudinal direction as an axis and having a thread on the outside, and a thread on the inside so that the screw is through-coupled Tilt variable solar power generation, characterized in that it includes a screw inlet member that is rotatably mounted with respect to the second post so as to support the screw so that the screw moves linearly when the screw rotates in the longitudinal direction as an axis. Device. The method of claim 1, wherein the first and second height adjustment parts
The separation distance from the ground or the building floor varies according to the height fixed from the upper part of the first fixing part or the second fixing part, and the load supporting body supporting the module holder, the first fixing part or the first fixing part 2 A height adjustment unit for fixing the position of the load support body coupled to the fixing unit, and a fastening unit for rotatably fastening the module holder to the load support body,
The load-bearing body is
It consists of a pair of vertical plates facing the same as or largely spaced apart from the width of the first or second fixing parts and positioned between the first or second fixing parts, and a connecting plate for interconnecting the vertical plates,
A plurality of fixing holes penetrated to be spaced apart from each other in the vertical direction are respectively formed in the pair of vertical plates, and a plurality of fixing holes for fastening with the module holder are respectively formed through the upper portions of the plurality of fixing holes,
The height adjustment unit is installed through the fixing hole and the first or second fixing part to fix the load supporting body to the first fixing part or the second fixing part. Device. The method of claim 1, wherein the first and second height adjustment parts
The separation distance from the ground or the building floor varies according to the height fixed from the upper part of the first fixing part or the second fixing part, and the load supporting body supporting the module holder, the first fixing part or the first fixing part 2 A height adjustment unit for fixing the position of the load support body coupled to the fixing unit, and a fastening unit for rotatably fastening the module holder to the load support body,
In the module holder,
A plurality of control holes are formed that are spaced apart from each other in the direction in which the first post and the second post are spaced apart,
The fastening unit is
According to the angle of the module holder among the plurality of adjustment holes, an adjustment hole positioned on a vertical line with the second post is fastened to the adjustment hole and the fastening hole of the second post positioned on a vertical line with the second post. A tilt-variable solar power generation device, characterized in that it is fastened. The method of claim 1, wherein the first and second height adjustment parts
The separation distance from the ground or the building floor varies according to the height fixed from the upper part of the first fixing part or the second fixing part, and the load supporting body supporting the module holder, the first fixing part or the first fixing part 2 A height adjustment unit for fixing the position of the load support body coupled to the fixing unit, and a fastening unit for rotatably fastening the module holder to the load support body,
The module holder
The first post and the second post are penetratingly formed in the form of a long hole extending in a direction to be spaced apart from each other, respectively, are drawn upwardly at the upper end and arranged in the longitudinal direction to be mounted on the fastening unit according to the inclination angle of the module holder. A tilt-variable solar power generation device, characterized in that the adjustment hole is formed with a plurality of mounting grooves positioned so as to be able to be formed. According to claim 3, wherein the load-bearing body
Incline-variable solar power generation device, characterized in that it further comprises a plurality of inclined plate members protruding obliquely from the vertical plate with respect to the vertical plate, the fastening holes are spaced apart from each other along the rotational trajectory of the module holder. The method according to claim 3, wherein the first or second fixing part has an upper surface sealed,
The first and second height adjustment parts
When one end is in contact with the connecting plate and the other end is in contact with the upper surface of the first or second fixing part and the module holder rotates and rises by an elastic force, a main body transfer spring for raising and lowering the load supporting body by the vertical height to which the module holder is raised; , It protrudes vertically downward from the connecting plate, passes through the center of the main body transfer spring, passes through the upper surface of the first or second fixing part, and the main body transfer spring extends only in the vertical vertical direction without departure in the other direction or Incline-variable solar power generation device, characterized in that it further comprises a spring guide for guiding the main body transfer spring so as to be contracted.

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