KR20190143615A - Solar power generating system - Google Patents

Abstract

The present invention relates to a wind force reduction type solar power generation system. The wind force reduction type solar power generation system comprises: two vertical supporting shafts disposed adjacent to each other; supporting holders disposed on upper ends of the two vertical supporting shafts, respectively; a main supporting bar disposed between the two supporting holders; connection members coupled to both ends of the main supporting bar, respectively, and inserted into the supporting holders to be able to angularly rotate within a predetermined angular range, respectively; and a solar cell module coupled to the main supporting bar, disposed to be inclined, and configured to move within the predetermined angular range by the connection members according to applied wind force. Each of the supporting holders includes: a body part having the length in a horizontal direction; a shaft insertion hole which penetrates the body part in a longitudinal direction; and rotational angle limiting grooves disposed on both surfaces of the body part, respectively. Each of the connection members includes: a shaft part inserted into the shaft insertion hole of the supporting holder to be able to rotate; and a holding protrusion protruding from an outer peripheral surface of the shaft part and inserted into the rotational angle limiting grooves to be able to angularly rotate at a rotational angle limiting groove area of the supporting holder. According to the present invention, the solar cell module is able to effectively absorb the sunlight, and to minimize wind pressure applied to the solar cell module when a strong wind blows, thereby preventing damage to the solar cell module and other components.

Description

SOLAR POWER GENERATING SYSTEM

The present invention relates to a wind energy saving solar power system.

At present, the depletion of hydrocarbon-based fossil energy resources and the increase of greenhouse gases emitted by its use have increased the adverse effects on the global environment and threatened the survival of humankind. In addition, nuclear power generation, as well as the depletion of resources, as in the Chernobyl and Fukushima nuclear power plants, has a great impact on the global environment and the threat of human survival in the event of an accident.

For this reason, the use of renewable energy such as solar, wind, tidal power, etc., with no environmental pollution and infinite duration is increasing all over the world. Among renewable energy, solar energy is distributed evenly in the inhabited place of people around the world, and solar power generation is the most effective because it directly converts solar light energy into electrical energy.

In general, a photovoltaic power generation system using electricity to generate electricity includes a flat panel type solar module, a support frame for supporting the solar module, and a cable for storing and transmitting electricity generated from the solar module. It includes a system. In order to effectively absorb the solar module, the solar module is fixed to the support frame to be inclined, or the solar module is installed on the support frame to automatically adjust the inclination according to the position of the sun. If the solar module is installed on the support frame so that the tilt is automatically adjusted according to the position of the sun, the installation cost is very expensive. Therefore, in order to reduce the installation cost, the solar module is fixed to the support frame in an inclined state.

However, since the solar modules are inclined in order to absorb the solar light effectively, when a typhoon or strong wind occurs, the wind pressure of the typhoon or strong wind acts greatly on the solar module, causing the solar module to be damaged or There is a problem that occurs when the connection portion of the support frame is broken.

An object of the present invention is to reduce the wind pressure of the solar cell module to minimize the wind pressure acting on the solar cell module when the solar cell module effectively absorbs the sunlight, and to prevent damage to the solar cell module and other components. To provide.

In order to achieve the object of the present invention, two vertical support shafts adjacent to each other; A support holder provided at each upper end of the two vertical support shafts; A main support bar positioned between the two support holders; Connecting members respectively coupled to both ends of the main support bar, the connecting members being rotatably inserted in the angle ranges respectively set in the support holders; And a solar cell module coupled to the main support bar to be inclined and moving in an angular range set by the connection members according to the acting wind power. The support holder includes a body having a length in a horizontal direction, and the body. A shaft insertion hole formed in the longitudinal direction through the portion, and a rotation angle limiting groove provided on both side surfaces of the body portion, wherein the connecting member includes a shaft portion rotatably inserted into the shaft insertion hole of the support holder, and the shaft portion. It is projected on the outer circumferential surface of the support holder is provided a wind power reduction type solar power generation system including a locking projection which is inserted into the rotation angle limited groove to be angular rotation in the region of the rotation angle limited groove.

The rotation angle limiting groove of the support holder includes a first inner contact surface positioned in a horizontal direction and a second inner contact surface positioned in a vertical direction at an angle set with the first inner contact surface with respect to the shaft insertion hole. It is desirable to.

Preferably, the first and second inner contact surfaces of the rotation angle limiting groove are flat.

The engaging protrusion of the connection member includes both side surfaces, and the distance between the both side surfaces is smaller than the width of the rotation angle limiting groove of the support holder.

An anti-separation plate may be coupled to one side of the support holder to prevent separation of the locking protrusion.

It is preferable that elastic plates are provided on both side surfaces of the engaging protrusion of the connection member.

A coupling plate is coupled to both ends of the main support bar, and a flange is provided at one end surface of the connection member, so that the coupling plate and the flange are fastened by a fastening means.

An air damper for absorbing shock may be connected to the vertical support shaft and the solar cell module.

According to the present invention, when the strong wind does not occur, the solar cell module is inclined by its own weight, so that the solar cell module effectively absorbs the sunlight, and when the strong wind is generated, the wind pressure is caused by the strong wind acting on the solar cell module. When the solar cell module moves in a horizontal state so that the wind pressure acting on the solar cell module decreases and the strong wind becomes weak, the solar cell module moves to its original position and is inclined due to the weight of the solar cell module. If it is to prevent the solar cell module is damaged by the strong wind.

In addition, the present invention, because the elastic plate is provided on both sides of the engaging projection portion of the connecting member inserted into the support holder when the solar cell module moves in the horizontal state at the maximum inclined position or moves in the horizontal state at the maximum inclined position together the obstacle of the connecting member By absorbing the impact of the base and the support holder to minimize the impact on the solar cell module.

1 is a plan view showing one embodiment of a wind power reduction type solar power generation system according to the present invention,
Figure 2 is a side view showing an embodiment of a wind energy saving photovoltaic power generation system according to the present invention,
Figure 3 is an exploded perspective view showing a support holder and a connecting member constituting an embodiment of a wind power reduction type solar power generation system according to the present invention,
Figure 4 is a side view showing a support holder and a connecting member constituting an embodiment of a wind power reduction type solar power generation system according to the present invention,
Figure 5 is a front view showing a support holder and a connecting member constituting an embodiment of a wind power reduction type solar power generation system according to the present invention,
Figure 6 is a front view showing another embodiment of the connecting member constituting an embodiment of the wind power reduction type solar power generation system according to the present invention,
Figure 7 is a side view showing another embodiment of the connecting member constituting an embodiment of the wind power reduction type solar power generation system according to the present invention,
8 is a side view showing a state in which an air damper is provided in the wind energy saving photovoltaic power generation system according to the present invention;
Figure 9 is a side view showing the operating state of one embodiment of a wind energy saving photovoltaic power generation system according to the present invention.

Hereinafter, with reference to the accompanying drawings, an embodiment of a wind energy saving photovoltaic power generation system according to the present invention.

1 is a plan view showing an embodiment of a wind energy saving photovoltaic power generation system according to the present invention. Figure 2 is a side view showing an embodiment of a wind energy saving photovoltaic power generation system according to the present invention.

As shown in Figures 1 and 2, one embodiment of the wind power reduction type solar power generation system according to the present invention, the vertical support shafts 10, the support holder 20, the main support bar 30, the connection member 40, a solar cell module 50.

The vertical support shafts 10 are installed at the installation site in a row at intervals from each other. The vertical support shafts 10 are preferably installed at a predetermined interval from each other. The installation place is the place where the solar power plant is installed. The vertical support shaft 10 is preferably a square tube having a set length. The vertical support shaft 10 is installed in the vertical direction. Mounting cover 60 is preferably provided at the upper end of the vertical support shaft (10). The mounting cover 60 includes a rectangular cylinder portion 61 having a cross-sectional size larger than the cross-sectional size of the vertical support shaft 10, and a cover plate portion 62 coupled to the upper surface of the rectangular cylinder portion 61. The cover plate portion 62 is a square plate having a larger size than the cross section of the square cylinder portion 61. Square tube portion 61 of the mounting cover 60 and the upper end of the vertical support shaft 10 is fastened by the fastening means.

The support holder 20 is preferably installed at each upper end of the vertical support shaft (10). As an example of the support holder 20, as shown in FIGS. 3, 4, and 5, the support holder 20 has a body portion 21 having a length in the horizontal direction and a length portion in the body portion 21. It includes a shaft insertion hole 22 and a rotation angle limited groove (G) provided on both sides of the body portion 21 formed therethrough. The lower surface of the body portion 21 is preferably a square and the upper surface is a curved surface. Preferably, the flange portion 23 is provided on the lower surface of the body portion 21. The flange portion 23 is preferably formed in a square plate shape at the lower end of the body portion 21. The size of the flange portion 23 is preferably the same as the size of the cover plate portion 62 of the mounting cover 60. As an example of the rotation angle limitation groove G, the rotation angle limitation groove G has a depth set from one side of the body portion 21 and is formed in a fan shape in which one side is connected to the shaft insertion hole 22. That is, the rotation angle limiting groove G forms the first inner contact surface 1 positioned in the horizontal direction and the shaft insertion hole 22 at a predetermined angle with the first inner contact surface 1 with respect to the center line in the vertical direction. The inner side of the first inner contact surface 1 and the second inner contact surface 2, the curved surface 3 connecting the outer end of each of the first and second inner contact surfaces 1 and 2, and the first and second inner contact surfaces 1 and 2, respectively. An opening 4 between each end. It is preferable that the 1st, 2nd inner side contact surfaces 1 and 2 are respectively planar. Preferably, the first and second inner contact surfaces 1 and 2 are located on radial center lines passing through the center of the shaft insertion hole 22, respectively. The support holder 20 is vertically supported by the fastening means of the cover plate 62 of the detachable cover 60 provided at the upper end of the flange 23 and the vertical support shaft 10 of the support holder 20. Is coupled to the upper end of the shaft 10.

The main support bar 30 is located between two support holders 20 adjacent to each other. As an example of the main support bar 30, the main support bar 30 is preferably a square tube.

The connecting members 40 are respectively coupled to both ends of the main support bar 30, and are rotatably inserted in the angle ranges set in the support holders 20, respectively. That is, one end of the connection member 40 is coupled to the end of the main support bar 30 and the other end of the connection member 40 is inserted into the support holder 20, the angular rotation is inserted in the set angle range. . As an example of the connecting member 40, the connecting member 40 is supported by a shaft portion 41 rotatably inserted into the shaft insertion hole 22 of the support holder 20, and the outer peripheral surface of the shaft portion 41; It includes a locking projection 42 is inserted into the rotation angle limited groove (G) to be movable in the region of the rotation angle limited groove (G) of the holder (20). The engaging protrusion 42 of the connecting member 40 includes both side surfaces, and the distance between the two side surfaces is smaller than the width of the rotation angle limiting groove G of the support holder 20. As an example of the locking projection 42, the locking projection 42 is formed in a horizontal cross-sectional shape in a fan shape. That is, the locking protrusion 42 includes both side surfaces and curved surfaces connecting the outer ends of the two side surfaces. Both sides of the locking projections 42 are located on radial center lines passing through the center of the shaft portion 41, respectively. As another example of the locking protrusion 42, the locking protrusion 42 is formed in a cross section in the horizontal direction. That is, both side surfaces of the locking protrusion 42 are parallel to the radial center line passing through the center of the shaft portion 41. When the coupling member 40 is coupled to the support holder 20, the shaft portion 41 of the coupling member 40 is inserted into the shaft insertion hole 22 in the support holder 20, and the locking protrusion 42 is limited to the rotation angle. Is inserted into the groove (G), the shaft portion 41 is rotatable in the shaft insertion hole 22, the locking projection 42 is the first inner contact surface of the rotation angle limited groove (G) in accordance with the rotation of the shaft portion 41 (1) or the second inner contact surface (2) in contact with the engaging projection 42 is limited to the movement only between the first and second inner contact surface (1) (2) of the rotation angle limited groove (G) shaft portion ( 41) In addition, angular rotation is performed only in the region between the first and second inner contact surfaces 1 and 2 of the rotation angle limiting groove G. It is preferable that the release preventing plate 70 is coupled to both sides of the support holder 20 so as to prevent the engaging protrusion 42 of the connecting member 40 from being separated from each other. Departure preventing plate 70 is coupled to the side of the support holder 20, it is coupled to cover the rotation angle limited groove (G). When the release preventing plate 70 is coupled to the support holder 20, a part of the locking protrusion 42 of the connection member 40 is cut to form a groove, and the release preventing plate 70 is positioned in the groove to stop the locking protrusion. 42 becomes rotatable. In order to absorb the shock when the engaging projection 42 contacts the first inner contact surface 1 or the second inner contact surface 2, as shown in FIGS. 6 and 7, the two projections 42 each have elasticity on both sides of the engaging projection 42. It is preferable that the board 80 is provided. Coupling grooves 6 are respectively provided on both side surfaces of the locking protrusion 42, and coupling protrusions 81 are provided on one side of the elastic plate 80 to be coupled to each other. Meanwhile, in order to absorb shock when the locking protrusion 42 contacts the first inner contact surface 1 or the second inner contact surface 2, the first inner contact surface 1 and the second inner side of the rotation angle limiting groove G are located. The contact surfaces 2 may be provided with elastic plates to absorb shocks, respectively. A flange 43 is provided at one end surface of the connection member 40, and coupling plates 31 are coupled to both ends of the main support bar 30, respectively, so that the flange 43 and the main support bar of the connection member 40 ( The coupling plate 31 of 30 is preferably fastened by fastening means. The fastening means may comprise welding or a plurality of bolts and nuts.

The solar cell module 50 is inclinedly coupled to the main support bar 30 and is movable in an angular range set by the connecting members 40 according to the acting wind power. The solar cell module 50 receives solar light (light) to generate electrical energy. In general, the solar cell module 50 is formed in a rectangular plate shape. The solar cell module 50 is preferably coupled to the C-shaped steels 90 and the C-shaped steels 90 to the main support bar 30. For example, the two C-beams 90 are coupled to the main support bar 30 in a direction perpendicular to the main support bar 30 at intervals from each other and the solar cell module 50 to the two C-beams (90) This is installed.

When the solar cell module 50 is horizontally positioned, the locking protrusion 42 of the connecting member 40 is positioned vertically so that one side of the locking protrusion 42 is the second inner contact surface of the rotation angle limiting groove G. (2) is in contact with the support, the solar cell module 50 is inclined in a state that the locking projection 42 of the connecting member 40 is positioned in the horizontal direction so that the other side of the locking projection 42 is limited to the rotation angle It is contact-supported by the 1st inner side contact surface 1 of the groove | channel G.

As illustrated in FIG. 8, an air damper D may be connected to the vertical support shaft 10 and the solar cell module 50. After the solar cell module 50 is inclined, the wind acts to move in the horizontal direction, and then the wind weakens to absorb the shock acting on the solar cell module 50 to move to its original position.

Hereinafter, the operation and effects of the wind power reduction type solar power generation system according to the present invention.

First, when a strong wind such as a typhoon does not occur, as shown in FIG. 9, the solar cell module 50 coupled to the main support bar 30 is positioned to be inclined to its own maximum load. At this time, the locking projection 42 of the connecting member 40 connected to the main support bar 30 is positioned in the horizontal direction so that the locking projection 42 is the first inner side of the rotation angle limiting groove G of the support holder 20. The contact surface 1 is supported by contact. Since the solar cell module 50 is positioned in an inclined state, the efficiency of absorbing sunlight from the solar cell module 50 is increased. On the other hand, when a strong wind such as a typhoon occurs, the wind due to the strong wind acts on the solar cell module 50 in the maximum inclined state, the inclined solar cell module ( The solar cell module 50 is rotated about the main support bar 30 to move in a horizontal state so that the surface pressure acts on the surface 50 while acting on the surface 50. As the solar cell module 50 moves in a horizontal state, the main support bar 30 rotates together, and as the main support bar 30 rotates, the connecting member 40 rotates angularly. As the locking protrusion 42 rotates in the rotation angle limiting groove G, the locking protrusion 42 is positioned in the vertical direction so that the other side of the locking protrusion 42 is the rotation angle limiting groove of the support holder 20. It is contact-supported by the 2nd inner side contact surface 2 of G). As the strong wind becomes weaker, the solar cell module 50 positioned in the horizontal state is inclined to the maximum inclined state due to its own weight, and at the same time, the main support bar 30 and the connecting member 40 rotate at each connection. The locking projection 42 of the 40 rotates angularly within the rotation angle limiting groove G so that the other side of the locking projection 42 contacts the first inner side contact surface 1 of the rotation angle limiting groove G. do. Because of this, the solar cell module 50 is positioned in the maximum inclined state.

As such, when the strong wind does not occur, the solar cell module 50 is inclined by its own weight so that the solar cell module 50 absorbs the sunlight effectively, and when the strong wind occurs, the solar cell The solar cell module 50 moves in a horizontal state so that the wind pressure acting on the solar cell module 50 decreases due to the wind pressure caused by the strong wind acting on the module 50. Since the solar cell module 50 moves to its original position by its own weight and is in an inclined state, when the strong wind occurs, the solar cell module 50 is prevented from being damaged by the strong wind.

In addition, the present invention, since the elastic plate is provided on both sides of the engaging projection portion 42 of the connecting member 40 is inserted into the support holder 20, the solar cell module 50 moves in the horizontal state at the maximum inclined position or in the horizontal state When moving to the maximum inclined position to absorb the impact of the engaging projection 42 and the support holder 20 of the connection member 40 to minimize the impact on the solar cell module 50.

10; Vertical support shaft 20; Support Holder
30; Main support bar 40; Connecting member
50; Solar cell module

Claims (7)

Two vertical support shafts adjacent to each other;
A support holder provided at each upper end of the two vertical support shafts;
A main support bar positioned between the two support holders;
Connecting members respectively coupled to both ends of the main support bar, the connecting members being rotatably inserted in the angle ranges set in the support holders, respectively;
Includes a solar cell module coupled to the main support bar is inclined, moving in an angular range set by the connecting members in accordance with the wind power to act;
The support holder includes a body portion having a length in the horizontal direction, a shaft insertion hole formed in the longitudinal direction through the body portion, and a rotation angle limited groove provided on both sides of the body portion,
The connecting member is rotatably inserted into the shaft insertion hole of the support holder and the rotation angle limited groove protrudes on the outer circumferential surface of the shaft and is rotatable in the region of the rotation angle limited groove of the support holder. Wind reduction type solar power generation system including a locking projection. According to claim 1, wherein the rotation angle limiting groove of the support holder is located in the vertical direction at a predetermined angle with the first inner contact surface positioned in the horizontal direction and the first inner contact surface with respect to the shaft insertion hole with respect to the center line. A wind power reduction type photovoltaic power generation system comprising a second inner contact surface. The method of claim 2, wherein the engaging projection portion of the connecting member includes both sides, the distance between the two sides is a wind power saving type solar power generation system, characterized in that less than the width of the rotation angle limit groove of the support holder. The method of claim 1, wherein one side of the support holder is a wind power reduction type solar power generation system characterized in that the separation prevention plate for preventing the separation of the engaging projection portion is coupled. The method of claim 1, wherein the wind power reduction type solar power generation system, characterized in that the elastic plate is provided on both sides of the engaging projection of the connecting member. The wind turbine according to claim 1, wherein a coupling plate is coupled to both ends of the main support bar, and a flange is provided at one end surface of the connection member so that the coupling plate and the flange are fastened by a fastening means. Power generation system. The method of claim 1, wherein the vertical damping shaft and the solar cell module, characterized in that the air damper for absorbing shock is connected to the solar power generation system.

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