KR102151999B1 - Supporting structure for solar module - Google Patents

Abstract

A support structure for a solar module according to an embodiment of the present invention includes a plurality of support portions each formed in a column shape and positioned in a vertical direction, spaced apart from each other around the solar module; And a driving unit hinged to the edge of the photovoltaic module and installed on the supporting unit, and moving in a vertical direction along the supporting unit while supporting the photovoltaic module, wherein the driving unit moves vertically along the support unit, and the solar module The slope of may be characterized in that it is changed.

Description

Support structure for solar module{SUPPORTING STRUCTURE FOR SOLAR MODULE}

The present invention relates to a support structure for a photovoltaic module, and more particularly, a support for a photovoltaic module capable of positioning the photovoltaic module at various angles and withstanding the wind and preventing the separation of the photovoltaic module by the wind. It is about the structure.

In general, a photovoltaic module is a device that converts solar energy into electrical energy, and can provide no pollution, no noise, and infinite energy supply. Such a solar module converts solar energy into electrical energy by a solar cell array formed by arranging a plurality of solar cells in series and parallel through a conductive ribbon and bus bar. Here, solar energy is transmitted through the low iron tempered glass seated on the top of the solar cell array and converted into electrical energy.

The solar module as described above is positioned on the support structure so that direct sunlight from the sun is vertically incident on the front surface of the solar module in order to improve the efficiency of power generation. Here, the supporting structure is coupled to the solar module using bolts and nuts including C-shaped steel.

On the other hand, when the photovoltaic module is exposed to weak wind, the wind passes through the hole between the photovoltaic modules, whereas when the photovoltaic module is exposed to strong wind, the bolt and nut connecting the photovoltaic module and the supporting structure The solar module is released from the supporting structure because it cannot withstand the wind. Even if the bolts and nuts are not loosened, the wind can damage the solar module and dislodge the supporting structure.

A technical problem to be achieved by the support structure for a solar module according to the technical idea of the present invention is to provide a support structure for a solar module that allows the inclination of the solar module to be changed according to changes in external environment.

In addition, the technical problem to be achieved by the support structure for a solar module according to the technical idea of the present invention is to provide a support structure for a solar module that prevents the solar module from being damaged or separated while withstanding a varying external pressure.

The technical problem to be achieved by the support structure for a photovoltaic module according to the technical idea of the present invention is not limited to the above mentioned problem, and another problem not mentioned can be clearly understood by a person skilled in the art from the following description. will be.

A support structure for a solar module according to an embodiment of the inventive concept includes a plurality of support portions each formed in a column shape and positioned in a vertical direction, spaced apart from each other around the solar module; And a driving unit hinged to the edge of the photovoltaic module and installed on the supporting unit, and moving in a vertical direction along the supporting unit while supporting the photovoltaic module, wherein the driving unit moves vertically along the support unit, and the solar module The slope of may be characterized in that it is changed.

In addition, a guide space is formed concave along the longitudinal direction of the support part on one surface of the support part, and a guide gear made of a plurality of teeth is formed along the longitudinal direction of the support part to correspond to the other surface of the support part on the inner surface of the guide space. Guide openings are formed along the longitudinal direction of the support portion on both side surfaces of the driving unit, the driving unit is inserted into the guide space and meshed with the guide gear, and a drive gear unit having a gear shaft inserted into the guide opening at the center of both longitudinal surfaces; The first end is hingedly connected to the edge surface of the solar module, the second end is hingedly connected to the first end of the gear shaft of the drive gear unit, the deformable drive connection; And a drive body part connected to the second end of the gear shaft of the drive gear part to rotate the gear shaft, wherein when the drive body part rotates the gear shaft to rotate the drive gear part with the gear shaft as an axis, the drive gear part The photovoltaic module can be rotated while being engaged and moving in the vertical direction along the support part, and the driving connection part is deformed.

In addition, the drive connection is made of a bar shape, the first end is hinge-connected to the edge of the solar module, is rotatable about an axis along the longitudinal direction, and the second end has an insertion opening along the length direction. A formed first connection body; And a second connection body formed in a bar shape, wherein the first end is hingedly connected to the gear shaft, and the second end is formed with an insertion protrusion corresponding to the insertion opening, wherein the insertion protrusion is inserted into the insertion opening, The 1 connection body and the second connection body are connected to each other, and when the drive body part moves the drive gear part along the support part, at least one of the first connection body and the second connection body may move or rotate around the insertion protrusion. have.

In addition, the drive unit is installed in the support unit so as to correspond to the guide opening into which the first end of the gear shaft is inserted, is in contact with the first end of the gear shaft, and further includes a blocking unit connected to the drive body, the drive body unit is operated In this case, the blocking portion may be spaced apart from the guide opening so that the driving gear portion can be moved along the guide opening.

In addition, the blocking portion is provided on the support portion so as to be adjacent to the guide opening into which the first end portion of the gear shaft is inserted, and the blocking base portion parallel to the guide opening; A plurality of blocking body parts that are connected to be perpendicular to the blocking base and are spaced apart from each other on the side of the support part to face the guide opening; And a blocking driving part connected to the blocking base part and the driving body part and moving the blocking base part with respect to the guide opening, wherein the blocking driving part positions the blocking body part to cross the guide opening by the blocking base part, and the gear shaft is cut off. It is inserted and supported between the body parts, and when the driving body part is operated, the blocking driving part can move the blocking base part on the support part to separate the blocking body part from the guide opening.

In addition, the drive unit is located on the outer circumferential surface of the second end of the gear shaft, is located between the support and the drive body, is connected to the blocking drive and the drive body, and measures the acceleration of the drive gear when the drive body is operating. Further comprising an acceleration detection unit, wherein when the acceleration detection unit measures the acceleration of the drive gear unit above the limit value, the blocking drive unit moves the blocking base unit to cross the blocking body part with the guide opening, so that the first end of the gear shaft is between blocking body parts. Can be placed in

In addition, the support structure is located on the solar module, the sensing unit for sensing the pressure by the wind applied to the solar module; And a control unit for connecting the sensing unit and the driving unit, and moving the driving unit in a vertical direction along the support unit according to the pressure sensed by the sensing unit, wherein when the sensing unit detects a pressure applied to the solar module above a set value, the control unit is By operating the driving unit, the tilt of the solar module can be adjusted.

In addition, the support portion is positioned to correspond to each of the edge faces of the solar module at least one, and the driving portion may be movable along the support portion to change the inclination of the solar module in a direction corresponding to each of the edge faces of the solar module. .

The support structure for a solar module according to embodiments according to the technical idea of the present invention has the following effects.

(1) The inclination of the solar module may be changed according to changes in the external environment (eg, wind strength).

(2) Make sure that the solar module can withstand external pressure and is not damaged or separated.

However, the effects that can be achieved by the support structure for a photovoltaic module according to an embodiment of the present invention are not limited to those mentioned above, and other effects not mentioned are clearly to those skilled in the art from the following description. It will be understandable.

In order to more fully understand the drawings cited in the present specification, a brief description of each drawing is provided.
1 is a perspective view showing a supporting structure for a solar module according to a first embodiment of the present invention.
2 is a photograph showing a state in which the main connection part is fixed to the solar module in the support structure for a solar module according to the first embodiment of the present invention.
3 is a perspective view showing a supporting structure for a solar module according to a second embodiment of the present invention.
4 is a perspective view showing a part of a support structure for a solar module according to a second embodiment of the present invention.
5 is an exploded perspective view showing a support part and a driving part of a support structure for a solar module according to a second embodiment of the present invention.
6 is a perspective view showing an operation of a blocking unit in a driving unit of a support structure for a solar module according to a second embodiment of the present invention.

In the present invention, various modifications may be made and various embodiments may be provided, and specific embodiments are illustrated in the drawings and will be described in detail through detailed description. However, this is not intended to limit the present invention to specific embodiments, and the present invention should be understood to include all changes, equivalents, and substitutes included in the spirit and scope of the present invention.

In describing the present invention, when it is determined that a detailed description of a related known technology may unnecessarily obscure the subject matter of the present invention, a detailed description thereof will be omitted. In addition, numbers (eg, first, second, etc.) used in the description of the present specification are merely identification symbols for distinguishing one component from another component.

In addition, in the present specification, when one component is referred to as "connected" or "connected" to another component, the one component may be directly connected or directly connected to the other component, but specially It should be understood that as long as there is no opposing substrate, it may be connected or may be connected via another component in the middle.

In addition, as for the constituent elements represented by'~ unit' in the present specification, two or more constituent elements may be combined into one constituent element, or one constituent element may be divided into two or more for each more subdivided function. In addition, each of the components to be described below may additionally perform some or all of the functions that other components are responsible for in addition to its own main function, and some of the main functions that each component is responsible for are different. It goes without saying that it may be performed exclusively by components.

Hereinafter, embodiments according to the technical idea of the present invention will be sequentially described in detail.

1 is a perspective view showing a support structure 1 for a photovoltaic module according to a first embodiment of the present invention, and FIG. 2 is a main structure in the support structure 1 for a photovoltaic module according to the first embodiment of the present invention. These are photos showing a state in which the connection part 1a is fixed to the solar module 10.

1 and 2, the support structure 1 for a solar module according to the first embodiment includes a main connection 1a, a sub connection 1b, and a pillar 1c, It is used to control the slope of the module 10. Here, the solar module 10 is formed in a plate shape, and collects sunlight by being exposed to sunlight, and converts energy according to sunlight into electrical energy and outputs it. In addition, the photovoltaic module 10 is made of a plurality of unit cells, and outputs power of different output values according to the number of unit cells and is connected to a connection panel to transmit power.

The main connecting portions 1a are formed in plural, each positioned on the lower surface of the solar module 10 and spaced apart at regular intervals so as to be parallel to each other. The main connection portions 1a of the present embodiment are located along the width direction of the solar module 10 from the lower surface of the solar module 10 and are spaced apart from each other in parallel along the length direction of the solar module 10.

Here, the main connecting portions 1a are each made of C-shaped steel. The upper flange of the main connection part 1a may be fixed to the frame forming the edge of the solar module 10 using bolts and nuts.

A plurality of sub-connections 1b are formed, each of which is positioned orthogonal to the main connection 1a, and is spaced apart at regular intervals so as to be parallel to each other. Here, the sub connection part 1b connects the main connection part 1a to each other. The sub-connectors 1b of this embodiment are positioned along the length direction of the solar module 10 and are spaced apart from each other in parallel along the width direction of the solar module 10.

In addition, the sub connection portion 1b is formed in a bar shape, and may be fixed to the lower flange of the main connection portion 1a of C-shaped steel using bolts and nuts.

A plurality of pillar portions 1c are formed, each of which has a pillar shape, and is positioned in a vertical direction on the ground. In the present embodiment, the pillar portion 1c is shown in the shape of a square pillar, but is not limited thereto, and may be formed in various shapes of pillars.

With the top surface of the column part 1c facing the bottom surface of the sub connection part 1b, the column part 1c is connected to the sub connection part 1b. Here, the sub connection part 1b may be rotatable through vertical movement or length change of the column part 1c. Due to this, the inclination of the solar module 10 may be changed.

In addition, a plurality of pillar portions 1c may be connected to one sub connection portion 1b, respectively. Accordingly, the sub connection portion 1b may be stably positioned while being supported by the column portion 1c. The pillars 1c are connected to the sub-connections 1b and are positioned to be spaced apart from each other. Here, the pillar portions 1c may be connected to each other, so that the solar module 10 may be supported more stably in combination with the main connecting portion 1a and the sub connecting portion 1b.

In addition, the pillar portion 1c may be hingedly connected to the sub-connection portion 1b corresponding between the pillar portions 1c by using a connection member, so that the sub-connection portion 1b can be supported more stably.

The solar module support structure 1 of the present embodiment as described above uses the main connection part 1a, the sub connection part 1b, and the pillar part 1c to firmly support the solar module 10 to protect the external environment. It can be maintained in a stable state. In particular, the pillar portion 1c can be moved up and down or the length can be changed, so that the inclination of the solar module 10 can be changed. Due to this, the solar module 10 is reached by the support structure 1 for the solar module without being damaged or detached, and can even be positioned in the horizontal direction under the column portion 1c. Accordingly, the support structure 1 for the solar module may be such that the solar module 10 is not damaged or separated even when a strong wind is applied.

3 is a perspective view showing a support structure 100 for a solar module according to a second embodiment of the present invention, and FIG. 4 is a part of the support structure 100 for a solar module according to a second embodiment of the present invention. 5 is a perspective view showing an exploded view of the support part 101 and the driving part 102 of the support structure 100 for a solar module according to the second embodiment of the present invention, and FIG. 6 is the present invention It is a perspective view showing the operation of the blocking portion 127 in the driving portion 102 of the solar module support structure 100 according to the second embodiment of the.

3 to 6, the support structure 100 for a photovoltaic module according to the second embodiment of the present invention includes a support 101, a driving unit 102, a sensing unit 103, and a control unit 104. Including, it is used to control the inclination of the solar module 10 according to the wind strength applied to the solar module 10. Here, the solar module 10 is formed in a plate shape, and collects sunlight by being exposed to sunlight, and converts energy according to sunlight into electrical energy and outputs it. In addition, the photovoltaic module 10 is made of a plurality of unit cells, and outputs power of different output values according to the number of unit cells and is connected to a connection panel to transmit power.

The support portion 101 is made of a plurality, each formed in a columnar shape, each positioned in a vertical direction on the ground. In the present embodiment, the support part 101 is shown in the shape of a square pillar, but is not limited thereto, and may be formed in various shapes of pillars.

The plurality of support portions 101 are positioned around the solar module 10 and may be spaced apart at regular intervals between the top and bottom. In addition, the support 101 is positioned to correspond to the edge surface of the solar module 10. In particular, when the solar module 10 is formed in a planar plate shape, the support unit 101 may be positioned to correspond at least one to each of the edge surfaces of the solar module 10 consisting of four, and will be described later. When considering the configuration of the driving unit 102 to be preferably two or more may be positioned to correspond to each other.

In addition, a guide space 111, a guide gear 113, and a guide opening 115 are formed in the support part 101.

The guide space 111 is concavely formed on one surface of the support part 101, and is formed in a vertical direction along the length direction of the support part 101.

The guide gear 113 is formed along the longitudinal direction of the guide space 111 on the inner surface of the guide space 111 so as to correspond to the other surface of the support part 101 and is made of a plurality of teeth. That is, the guide gear 113 is formed in the form of a rack gear on the inner surface of the guide space 111.

The guide opening 115 is formed on both side surfaces of the support portion 101 in a vertical direction along the longitudinal direction of the support portion 101, respectively. Here, the guide opening 115 opens the guide space 111 through both side surfaces of the support part 101.

The driving unit 102 is made of a plurality, and connects the solar module 10 and the support unit 101. Here, the driving unit 102 is positioned to correspond to each of the support units 101, is hinged to the edge of the solar module 10, and is installed on the support unit 101. In addition, the driving unit 102 may move vertically along the support unit 101 while supporting the solar module 10 to adjust the inclination of the solar module 10. The inclination of the solar module 10 may be maintained by the driving unit 102.

The photovoltaic module 10 of the present embodiment has four edge surfaces. Here, the driving unit 102 may tilt the photovoltaic module 10 in four directions by positioning the edge surfaces of the photovoltaic module 10 downward, respectively. That is, the driving unit 102 of the present embodiment may tilt the solar module 10 in various directions.

Further, the driving unit 102 may include a driving gear unit 121, a driving connection unit 123, and a driving body unit 125.

The drive gear unit 121 is inserted into the guide space 111 and meshes with the guide gear 113. Here, the drive gear unit 121 is formed in a cylindrical shape and has a plurality of teeth formed along the outer circumferential surface. In addition, a gear shaft 121a is formed in the drive gear part 121 to pass through the centers of both end faces of the drive gear part 121. The drive gear unit 121 as described above may be formed in the form of a pinion gear in consideration of the guide gear 113 formed in the form of a rack gear.

When the driving gear part 121 is inserted into the guide space 111 and meshed with the guide gear 113, both ends of the gear shaft 121a are inserted into the guide opening 115, respectively, through the guide opening 115. It protrudes to the outside of the guide space 111. As the gear shaft 121a is inserted into the guide opening 115, the driving gear unit 121 may be maintained in a state inserted into the guide space 111. In addition, the driving gear unit 121 may be rotated around the gear shaft 121a while being engaged with the guide gear 113. Here, the gear shaft 121a moves in a vertical direction along the guide opening 115 while rotating together with the driving gear part 121. That is, the drive gear unit 121 is rotated to move in the vertical direction.

On the other hand, while the driving gear unit 121 is inserted into the guide space 111, one surface of the open support unit 101 may be closed by the support cover 110. In addition, the support cover 110 is detachable with respect to one surface of the support portion 101.

The drive connection part 123 has a bar shape and connects the edge surface of the solar module 10 and the drive gear part 121. Here, the first end of the drive connection 123 is hinged to the edge of the photovoltaic module 10, and the second end of the drive connection 123 is the second end of the gear shaft 121a of the drive gear part 121. 1 is hinged to the end. In addition, the drive connection part 123 extends from the edge surface of the solar module 10 and is orthogonal to the gear shaft 121a.

When the drive gear part 121 is inserted into the guide space 111 and rotates to move along the guide space 111, the drive connection part 123 is deformed while being moved by the drive gear part 121. Here, the drive connection part 123 may be bent, or may be lengthened or shortened. For this reason, the solar module 10 can be rotated and adjusted to various inclinations.

In addition, the driving connection part 123 may include a first connection body 123a and a second connection body 123b.

The first connection body 123a has a bar shape. In the first connection body 123a, the first end is hinged to the edge of the photovoltaic module 10, and the second end has an insertion opening 123a' along the length direction of the first connection body 123a. Is formed. In addition, the first connection body portion 123a is rotatable about an axis along the longitudinal direction of the first connection body 123a on the edge surface of the solar module 10.

The second connection body 123b has a bar shape. The first end of the second connection body 123b is hinged to the first end of the gear shaft 121a of the drive gear unit 121, and the second connection body 123b is positioned so as to be orthogonal to the gear shaft 121a. do.

In addition, an insertion protrusion 123b' is formed at the end of the second connection body 123b so as to correspond to the insertion opening 123a'. The insertion protrusion 123b' is inserted into the insertion opening 123a', so that the first connection body 123a and the second connection body 123b are connected to each other. In addition, the first connection body (123a) and the second connection body (123b) may be formed of a driving connection portion 123 that is deformed to form a variety of lengths and angles.

When the driving gear unit 121 rotates and moves, the second connection body 123b may be moved by the driving gear unit 121. Here, since the insertion protrusion 123b' is in the state of being inserted into the insertion opening 123a', at least one of the first connection body 123a and the second connection body 123b moves or the insertion protrusion 123b' It can be rotated as an axis. In addition, the solar module 10 may be connected to the first connection body 123a and rotate while moving to adjust the inclination.

The drive body part 125 is connected to the second end of the gear shaft 121a of the drive gear part 121 to rotate the gear shaft 121a. When the gear shaft (121a) is rotated by the drive body (125), the drive gear (121) is rotated in a state engaged with the guide gear (113) and moves in the vertical direction along the guide gear (113). For example, when the drive body 125 rotates the gear shaft 121a counterclockwise, the drive gear unit 121 rotates and moves upward, while the drive body 125 is a gear shaft ( When rotating 121a) clockwise, the driving gear unit 121 rotates and moves downward. On the other hand, the drive body portion 125, when the drive body portion 125 rotates the gear shaft 121a clockwise, the drive gear portion 121 can be rotated and moved upward, and the drive body portion 125 When the gear shaft 121a rotates counterclockwise, the driving gear unit 121 may rotate and move downward. Further, the driving body 125 may maintain the driving gear unit 121 in a moved state.

In addition, the drive body 125 may be formed in the form of a motor, and may be connected to the second end of the gear shaft 121a to be kept spaced apart from the support part 101.

As the driving gear unit 121 is rotated and moved by the driving body unit 125 as described above, the solar module 10 may be rotated by the driving connection unit 123 to be positioned at various inclinations.

Meanwhile, the driving unit 102 according to the present embodiment may further include a blocking unit 127 and an acceleration detecting unit 129.

The blocking part 127 is installed on the support part 101 to correspond to the guide opening 115 into which the first end part of the gear shaft 121a is inserted, and contacts the first end part of the gear shaft 121a. In addition, the blocking part 127 is connected to the driving body part 125.

When the drive body part 125 is not operated and the drive gear part 121 is not moved, the blocking part 127 may be maintained in contact with the first end part of the gear shaft 121a ( 6(b)). Due to this, the driving gear unit 121 can be maintained in a stably moved state. On the other hand, when the drive body 125 is operated, the blocking portion 127 moves and is spaced apart from the guide opening 115, and is also spaced apart from the first end of the gear shaft 121a (Fig. 6(a)). Reference). Here, the drive gear part 121 may be moved in the vertical direction along the support part 101 by the drive body part 125. When the drive body 125 is not operated again, the blocking portion 127 is moved to correspond to the guide opening 115 so as to contact the first end portion of the gear shaft 121a.

In addition, the blocking part 127 may include a blocking base part 127a, a blocking body part 127b, and a blocking driving part 127c.

The blocking base portion 127a is installed on the support portion 101 so as to be adjacent to the guide opening 115 into which the first end portion of the gear shaft 121a is inserted, and is positioned parallel to the guide opening 115.

The blocking body portion 127b is formed in a plurality, and is connected to be perpendicular to the blocking base portion 127a and is positioned on the side of the support portion 101 to correspond to the guide opening 115. Here, the blocking base portion 127a may move the blocking body portion 127b with respect to the guide opening 115, and the blocking body portion 127b may be positioned to cross the guide opening 115. The blocking body portion 127b crosses the guide opening 115 and contacts the first end portion of the gear shaft 121a to limit the movement of the driving gear portion 121. In addition, it may be desirable that the blocking body portions 127b are spaced apart from each other at regular intervals.

Meanwhile, the blocking body portion 127b may be formed in a comb shape in combination with the blocking base portion 127a.

The blocking driving part 127c is connected to the blocking base part 129a and the driving body part 125. Here, the blocking driving part 127c separates the blocking body part 127b from the guide opening 115. Accordingly, the first end portion of the gear shaft 121a is spaced apart from the blocking body portion 127b, and the driving gear portion 121 is movable along the guide opening 115.

The acceleration detection unit 129 is located on the outer circumferential surface of the second end portion of the gear shaft 121a, is positioned between the driving body 125 and the support unit 101, and the blocking driving unit 127c and the driving body 125 ) Can be connected. Here, the acceleration sensing unit 129 measures the acceleration of the driving gear unit 121 when the driving body unit 125 operates.

When the acceleration sensing unit 129 measures the acceleration of the driving gear unit 121 over the limit value, the blocking driving unit 127c moves the blocking base unit 127a to move the blocking body unit 127b to the guide opening 115 Cross with (see Fig. 6(b)). In addition, the first end portion of the gear shaft 121a is positioned between the blocking body portions 127b, and the gear shaft 121a is in contact with the blocking body portion 127b. Here, the limit value of the acceleration of the driving gear unit 121 refers to the acceleration of the driving gear unit 121 when the driving gear unit 121 is moved that cannot be controlled by the driving body unit 125, for example , It may be an acceleration of the driving gear unit 121 when the driving gear unit 121 falls or rotates rapidly. Therefore, the acceleration detection unit 129 prevents the driving gear unit 121 from moving any more in combination with the blocking unit 127, so that the driving gear unit 121 due to unexpected movement of the driving gear unit 121 Collision of the support part 101 can be prevented.

The sensing unit 103 is located on the solar module 10 and senses a pressure applied to the solar module 10. In particular, pressure from the wind is applied to the solar module 10, and the sensing unit 103 detects the pressure due to the wind. Here, a set value for the pressure is set in the sensing unit 103, and the set value of the pressure means a pressure capable of causing damage and separation of the solar module 10 by wind.

The control unit 104 is connected to the sensing unit 103 and the driving unit 102. When the sensing unit 103 detects a pressure greater than or equal to the set value, the control unit 104 operates the driving unit 102 to adjust the inclination of the solar module 10. Here, the controller 104 operates the driving unit 102 until the sensing unit 103 detects a pressure applied to the solar module 10 lower than the set value.

In addition, looking at the operation of the drive unit 102, the drive body unit 125 rotates the drive gear unit 121 using the gear shaft 121a, and moves it in the vertical direction along the support unit 101. Here, the driving unit 102 may be operated to position the solar module 10 in a horizontal direction. Meanwhile, when the sensing unit 103 detects a pressure lower than the set value, the control unit 104 may stop the rotation and movement of the driving gear unit 121 using the driving body unit 125.

In addition, the sensing unit 103 may detect an incident amount of sunlight incident on the solar module 10. When the sensing unit 103 detects a pressure lower than the set value, the control unit 104 operates the driving unit 102 so that sunlight is incident on the solar module 10 above the set value, so that the inclination of the solar module 10 Adjust. Here, the tilt adjustment of the solar module 10 may be performed within a range in which the sensing unit 103 senses a pressure lower than a set value.

On the other hand, when the acceleration detection unit 129 of the driving unit 102 measures the acceleration of the driving gear unit 121 over the limit value, the control unit 104 generates a notification signal and transmits it to the manager of the solar module 10 Sometimes it does. In addition, even if the driving unit 102 is operated for a predetermined time, when the pressure change is not detected by the detection unit 103, the control unit 104 generates a notification signal and transmits it to the manager of the solar module 10. .

The solar module support structure 100 of the present embodiment as described above detects the pressure applied to the solar module 10 through the sensing unit 103 and operates the driving unit 102 using the control unit 104 I can make it. Here, the driving unit 102 is hinged to the edge surface of the solar module 10 and is installed on the support unit 101. In the drive unit 102, the drive body unit 125 moves the drive gear unit 121 along the support unit 101. Accordingly, the inclination of the solar module 10 is adjusted, and the pressure sensed by the sensing unit 103 may be changed. Accordingly, the solar module support structure 100 of the present embodiment may change the inclination of the solar module 10 according to the external environment, particularly, pressure applied to the solar module 10.

In addition, when the sensing unit 103 detects a pressure greater than or equal to the set value applied to the solar module 10 by wind, the support structure 100 for a solar module adjusts the inclination of the solar module 10. The inclination of the solar module 10 is adjusted until the sensing unit 103 senses a pressure higher than the set value applied to the solar module 10 by wind. Due to this, the solar module 10 is reached by the support structure 100 for the solar module in a state that is not damaged or separated, and is even positioned horizontally from the bottom of the support unit 101 by the driving unit 102. I can. For this reason, the solar module support structure 100 may be positioned so that the solar module 10 is not damaged or separated even when a strong wind is applied.

As described above, the technical idea of the present invention has been described in detail with reference to preferred embodiments, but the technical idea of the present invention is not limited to the above embodiments, and those skilled in the art within the scope of the technical idea of the present invention Various modifications and changes are possible by the user.

1, 100: support structure for solar modules
101: support
102: drive unit
121: drive gear unit
123: drive connection
125: drive body
127: blocking portion
129: acceleration detection unit
103: detection unit
104: control unit
10: solar module
1a: main connection
1b: sub connection
1c: pillar

Claims (8)

A plurality of support portions each formed in a columnar shape and positioned in a vertical direction, spaced apart from each other around the solar module; And
Each hinge-connected to the edge of the solar module and installed on the support, including a driving unit that moves in the vertical direction along the support while supporting the solar module,
As the driving unit moves up and down along the support, the inclination of the solar module is changed,
A guide space is formed concave along the longitudinal direction of the support on one side of the support, and a guide gear consisting of a plurality of teeth is formed along the longitudinal direction of the support so as to correspond to the other surface of the support on the inner side of the guide space, and both sides of the support Guide openings are formed along the longitudinal direction of each support,
The driving part,
A drive gear unit inserted into the guide space and engaged with the guide gear, and having a gear shaft inserted into the guide opening at the center of both end faces;
The first end is hingedly connected to the edge surface of the solar module, the second end is hingedly connected to the first end of the gear shaft of the drive gear unit, a deformable drive connection; And
It is connected to the second end of the gear shaft of the drive gear unit includes a drive body for rotating the gear shaft,
When the drive body rotates the gear shaft and rotates the drive gear part with the gear shaft as the axis, the drive gear part moves up and down along the support part while being engaged with the guide gear, and the drive connection part rotates the solar module while being deformed. ,
The driving part,
The first end portion of the gear shaft is installed on the support portion to correspond to the inserted guide opening, contacting the first end portion of the gear shaft, further comprising a blocking portion connected to the drive body,
When the drive body part is operated, the blocking part is spaced apart from the guide opening to make the drive gear part movable along the guide opening,
The blocking part,
A blocking base portion installed on the support portion so as to be adjacent to the guide opening into which the first end portion of the gear shaft is inserted, and parallel to the guide opening;
A plurality of blocking body parts that are connected to be perpendicular to the blocking base and are spaced apart from each other on the side of the support part so as to face the guide opening; And
It is connected to the blocking base portion and the driving body portion, and includes a blocking driving unit for moving the blocking base portion with respect to the guide opening,
The blocking drive part positions the blocking body part to cross the guide opening by the blocking base part, and the gear shaft is inserted and supported between the blocking body parts,
A support structure, characterized in that when the driving body is operated, the blocking driving unit moves the blocking base unit on the support so as to separate the blocking body from the guide opening.
delete The method of claim 1, wherein the drive connection unit,
A first connection body formed in a bar shape, wherein a first end is hinged to an edge surface of the solar module, is rotatable about an axis along a longitudinal direction, and an insertion opening is formed along a longitudinal direction at the second end; And
It is made in a bar shape, the first end is hinged to the gear shaft, and the second end includes a second connection body with an insertion protrusion formed to correspond to the insertion opening,
The insertion protrusion is inserted into the insertion opening, so that the first connection body and the second connection body are connected to each other,
When the drive body part moves the drive gear part along the support part, at least one of the first connection body and the second connection body moves or rotates about the insertion protrusion.
delete delete The method of claim 1, wherein the driving unit,
It is located on the outer circumferential surface of the second end of the gear shaft, is located between the support and the drive body, is connected to the blocking drive and the drive body, further includes an acceleration sensing unit that measures the acceleration of the drive gear when the drive body is operating But,
When the acceleration sensing unit measures the acceleration of the drive gear unit above the limit, the blocking drive unit moves the blocking base unit to cross the blocking body part with the guide opening, and positions the first end of the gear shaft between the blocking body parts. Supporting structures.
The method of claim 1, wherein the support structure,
A sensing unit positioned on the solar module to detect pressure caused by wind applied to the solar module; And
Further comprising a control unit for connecting the sensing unit and the driving unit, and moving the driving unit in the vertical direction along the support unit according to the pressure sensed in the sensing unit,
When the sensing unit senses the pressure applied to the solar module above the set value, the control unit operates the driving unit to adjust the inclination of the solar module.
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