KR20150026296A - the track style sunlight prodution of electric - Google Patents

Abstract

The present invention relates to a solar tracking type electric generator which tracks and moves a solar array for obtaining maximum condensing efficiency by always maintaining an altitude angle of 90 degrees and an azimuth of 90 degrees according to the movement of the Earth that is caused by a revolution and a rotation around the Sun. According to the present invention, the solar tracking type electric generator comprises: a structure which supports a solar cell panel and is simply configured so as to be easily manufactured; and an energy transfer component which is configured as a cable structure adjusting the altitude angle and the azimuth and has a simple structure so as to be manufactured and installed at low cost. Since a plurality of power supplies are not required, a failure rate considerably reduced. Accordingly, long-term maintenance costs are reduced and power generation efficiency is maximized by employing the mechanism tracking sunlight.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a solar-

 The present invention relates to a tracking and moving solar photovoltaic generator capable of maintaining a 90 ° altitude and azimuthal angle at all times along the earth's motion by revolution and rotation based on the sun, .

 The present invention is based on the assumption that the angle of incidence of the sun is maintained at 90 degrees at all times (hereinafter referred to as " moving from one end to the other, " To a solar-powered electric generating device for collecting light on a battery panel.

         Conventional solar concentrators are mainly focused on the incidence angle of sun by fixed type and tracking type. Fixed type installation costs are somewhat small, but the earth slope is 23.5 degrees with respect to the sun. In the structure that revolves and rotates, the stationary type is not able to maintain the incidence angle of 90 degrees at all seasons. The electricity generation efficiency is low as below, and the price of electricity generation compared to investment has a problem in high end.

         As a result, many traced electricity generators have been filed and registered for tracking the sun moving from east to west and keeping the incidence angle of the sun at 90 degrees at altitude and 90 degrees of azimuth at all times.

While the main purpose of the electricity generating device is to generate high profit compared to the investment, the conventional tracking electricity generating device requires a very expensive investment cost compared to the fixed type,

          1 is a schematic view of a traction type electricity generating apparatus according to an embodiment of the present invention.

          1 of the patent application 10-2006-0097372 shows a tracking type solar photovoltaic device having a biaxial structure, which is a drawing of a "solar photovoltaic power generation device", which is referred to as an azimuth angle and altitude angle tracking device A concrete problem of the photovoltaic power generation apparatus will be described as follows.

The above-described solar photovoltaic generator includes a vertical support 60; A rotation support 70 rotatably coupled to an upper side of the vertical support 60; A solar cell panel 50 connected to the upper portion of the rotation support 70 by a white structure 73; An altitude adjusting unit 80 connected to the solar cell panel 50 at a lower portion of the solar cell panel 50 in a direction of the rotation support 70 so as to have a hinge 57 to adjust the vertical angle of the solar cell panel 50; A control drive box 90 installed at a position where the altitude regulating portion and the rotation support 70 meet; A rotation driving unit 75 installed in the control drive box for driving the rotation support 70 to rotate around the vertical support 60; And an altitude driving unit 85 installed in the control driving box 90 or the altitude adjusting unit 80 to drive the altitude adjusting unit 80.

           Here, the vertical support 60 is formed at its upper portion with a fitting shaft 63 on which the rotary support 70 is fitted from the outside, and the fitting shaft is formed to be smaller than the outer diameter of the lower supporting portion.

           The rotary support 70 is formed in a cylindrical structure and is fitted to the fitting shaft 63, and a plurality of bearings are formed between the rotary support 70 and the fitting shaft so as to reduce rotational resistance.

          The rotation drive unit 75 includes a center gear provided around the vertical support 60 and a drive motor 76 fixed to the rotation support 70. The center gear of the center gear 70, And a driving gear that rotates along the axis.

          The height adjusting unit 80 includes two outer cylinders 81 and 82 fitted in a lengthwise manner and a height driving unit 85 having a ball screw 88 structure for adjusting the length is formed .

          A drive motor 86 for providing a driving force to the altitude driving unit 85 is formed on the control driving box 90 side.

          The altitude regulating unit 80 has an altitude regulating limit unit for fixing the variable length.

          The sunlight tracking type solar panel set described above includes an azimuth driving motor, an altitude driving motor, a required power transmitting device, electric wires, and components mounted on a unit-specific solar panel on a supporting structure for supporting a set of solar panels, And moves along the data of the tracking system by driving the motor.

            However, as described above, each unit solar panel set (the combination of the solar module and the module, the panel frame supporting the array, the panel vertical support, and the rotating operation unit is referred to as a "solar panel set" In this paper, we propose a solar panel system which is composed of two sets of motor drive units. In this way, a large number of solar panel sets are installed in a large area to generate a large amount of power in the same time period. Which is twice as high as that of the conventional method.

            In addition, due to the nature of the solar panel set which requires long-term electricity generation due to the driving part of many (1000 kw / h power production unit solar panel set is about 3000 sets, and the driving motor required is 6000 sets), the failure rate is high There were no disadvantages,

            In addition, when installing a solar panel set, there are disadvantages of installing a plurality of driving parts in order to have a normal operation structure,

            At this time, since the respective devices are separately constructed and assembled together, the overall structure is complicated, and assembly and maintenance management is also difficult.

            In addition, the wires exposed to the outside are exposed to the sun for a long time, and thus are hardened or aged due to solar heat, resulting in loss of insulation.

SUMMARY OF THE INVENTION The present invention has been made in order to solve the above problems, and it is an object of the present invention to provide a support structure for supporting and rotating a set of solar panels by unit and an azimuth drive motor, an altitude drive motor, A wire, a chain, a round bar shaft, and other power transmission parts as a power transmission means, and a plurality of guide pulleys are connected to a slot for accommodating a plurality of guide pulleys on a fixed vertical support, ), A small number of driving motors are installed in four directions (or a predetermined position in the middle part) installed at a plurality of positions in a unit-specific solar panel set, so that the initial investment cost is low and the installation is easy, The present invention is directed to a solar photovoltaic power generating apparatus for use in a solar cell.

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a solar panel set for generating electricity by tracking sunlight along a solar path,

          A first slot 111 is formed at a predetermined position on the front and back of the vertical frame 116, a pin bolt through-hole is formed at a predetermined position on the left and right sides, a height angle guiding pulley 123 is formed, A second slot 112 is formed at a predetermined position on the right side surface, a pin bolt through-hole is formed at a predetermined position on the front and back sides, an azimuth guide pulley 124 is formed, and one side of the cross- A main frame 110 having a base 150 integrated with a lower end thereof; An array 101 (which is referred to as a module in which solar cells are combined in a certain form and which is a combination of modules in a certain form is referred to as an array.) Hereinafter, A panel bracket 118 is formed at a central portion of the lower fixed position, a longitudinal wire white paper sheet 115-1 is formed at a predetermined position on the front and rear sides, An array supporting plate 100 on which a horizontal wire portion 115 is formed; A pinion bolt receiving hole is formed in a central portion thereof and a first guide groove 123-1 is formed on one side of the guide groove center portion and a second guide groove 123-2 is formed on the other side, 123); And an azimuthal guidance pulley 124-1 having a first guide groove 124-1 formed at one side thereof and a second guide groove 124-2 formed at the other side thereof with a pin bolt receiving hole formed at the center portion thereof, ): The other side of the first operation cable 121 is connected to the rear side of the altitude main cable 120 by the engaging clip 113 and the second side of the operation cable 121 is connected to the engaging clip 113 at the predetermined position in front of the altitude main cable 120 An elevation angle main cable 120 to which the other side is coupled; The other side of the third operation cable 131 is coupled to the fixed position of the azimuth angle main cable 130 at the predetermined position on the left side of the azimuth angle main cable 130 and the fourth operation cable 132) an azimuth angle main cable 120 connecting the other side; A V-belt 53 is coupled to a motor pulley 54 formed on one side of the altitude driving motor 50 to form a power transmission pulley 52 coupled to the other side of the V-belt 53, A plurality of pulleys 52 are formed at a predetermined position of the shaft shaft 51 so that one side of the elevation angle main cable 220 is connected to the power transmission pulley A left and right edge elevation angle driving unit 170 coupled to the left and right edge elevation angle driving units 52; A V-belt 53 is coupled to a motor pulley 54 formed on one side of the azimuth drive motor 50 to form a power transmission pulley 52 coupled to the other side of the V-belt 53, A shaft shaft 51 coupled to a central portion of the pulley 52 is formed and a plurality of pulleys 52 are formed at a predetermined position of the shaft shaft 51 so that one side of the elevation angle main cable 220 is connected to the power transmission pulley 52 A left and right edge azimuth driving section 180 coupled to the left and right edge azimuth driving section 180;

And includes a turn buckle (290) at a predetermined position of the elevation angle meande cable and the azimuth angle mee cable.

          A first elevation angle guide pulley 223 is formed at a predetermined position on the front surface of the vertical frame 216 according to an embodiment of the present invention. The first elevation angle guide pulley 223 is coupled to the pin bolt through- A second elevation angle guiding pulley 224 is formed by a pin bolt on a pin bolt through hole at a predetermined position on the left and right sides, 214 formed with a frame bracket (217) for engaging with the base frame (200), and a flange type support (201) at the lower end thereof;

          The array supporting plate 100 is formed on the vertical frame 216 to mount the array 101 and a white paper sheet 214 is formed at the center of the array supporting plate 100. The front and rear hinge parts 214, An array supporting plate 100 in which longitudinal wire whitening parts 215-1 and 215-2 are formed at predetermined positions and support whitening parts 241 are formed at left and right fixed positions of the center whitening part 214;

          A first elevation angle guidance pulley 223 having a pin bolt receiving hole formed at its center and having a guide groove formed therein,

          A second altitude guiding pulley 224 having a pin bolt receiving hole formed at its center and having a guide groove,

          One end of the first operation cable 221 is engaged with the longitudinal wire white paper 215-1 formed on the front side of the white paper sheet 214 at the lower portion of the base 260, The other side of the first operation cable 221 is coupled to the fixed angle main cable 220 at a fixed position on the right side of the height angle main cable 220 while being supported by the groove 223-1 formed in the altitude guiding pulley 223, One end of the second actuating cable 222 is engaged with the longitudinal wire rough portion 215-2 formed on the rear side with respect to the portion 214 and the other end is engaged with the second elongated angle guiding pulley 224 An elevation angle main cable 220 which is supported by the groove 224-2 and engages the second operation cable 221 at a predetermined position on the left side of the elevation angle main cable 220 with the engagement clip 213;

           An azimuth angle main cable 230 for coupling the azimuth angle main cables 230 and 231 to the first cap 251 and the second rotation clamp 252 formed at both ends of the rotary operation arm 250 with the coupling cap 255 and the coupling bolt 230 , 231);

           A key receiving groove is formed in the vertical frame 216 coupling hole 216-1 at a lower outer circumferential surface of the vertical frame 216. A coupling hole of the first rotary clamp 251 is formed at one side edge, The second rotary clamp 252 includes a rotary operation arm 250 having a coupling hole formed therein.

            A shaft 253 is formed at a lower portion to be engaged with both ends of the rotatable operation arm 250 and a support 254 formed with a bolt coupling hole for coupling the azimuth angle main cables 230, First 251, second rotary clamp 252;

            A coupling cap 255 having a coupling groove and a coupling bolt coupling hole for coupling the azimuth main cables 230 and 231;

            A vertical frame 216 receiving hole is formed at a central portion for supporting the rear supporting plate 201 integrally formed at the lower end of the main body frame 200. A coupling groove for the hinging support 201 is formed on the inner peripheral surface, And a coupling bolt through-hole is formed at a predetermined position on the outer circumferential surface of the body frame housing 202,

            The first and second operating cables 222 and 222 are formed at the central portion of the main body frame housing 202 to support the main body frame housing 202. The third and fourth altitude angle brackets 225, A base 260 formed with a bracket 227 for coupling the pulley 226 facing each other at certain positions of the through hole and having a set anchor 261 receiving hole at a predetermined position on the outer circumferential surface,

            A V-belt 55 is coupled to the motor pulley 52 at one side of the altitude driving motor 50, a primary power transmission pulley 53 is formed at the other side of the V-belt 55, A shaft shaft 51 coupled to a central portion of the pulley 53 is formed and a plurality of secondary power transmission pulleys 54 are formed at predetermined positions of the shaft shaft 51, A left and right edge height driving unit 270 coupled to the transmission pulley 54;

            A V belt 55 is coupled to a motor pulley 52 formed on one side of the azimuth drive motor 60 and an operation arm pulley 56 is formed on the other side of the V belt 55. The first 251, A double rotary operation arm 255 having a second 252, a third 253 and a fourth rotary clamp 254 is formed and the first rotary 251 and the second rotary 252 are connected to the first rotary 252 and the second rotary 252, (253) and the fourth rotary clamp (254) are engaged with the first rotary clamp (254) and the second rotary clamp (254) A left and right edge azimuth driving unit 280 coupled to the fourth rotary clamp 254 by a first power transmission cable 232 and a second power transmission cable 234;

           An altitude main cable and an azimuth angle main cable, and a turn buckle 290 at a predetermined position.

The photovoltaic generator according to the present invention configured as described above not only solves the existing fixed and non-efficient structure but also significantly reduces the investment cost compared to the currently registered and applied tracking methods, There is an advantage that the problem that the supplier requires is solved.

For example, in the case of a conventional traced electricity generating device, two deceleration motors, a bracket, a terminal, a control, a plurality of electric wires, and an electric tube (or underground work) Cable, and terminal costs. In particular, one of the key factors of photovoltaic power generation due to the remarkable difference in the cost of constructing the structure due to motor drive is the initial cost. The first advantage of the present invention is that it is a small initial investment cost and it is not necessary to wire a large number of electric wires, And obsolete problems are eliminated at all costs, the power driving part is very small and the maintenance cost is reduced, This type has an advantage that can be applied to the nature of the release cable in some form.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a left side view showing a conventional solar photovoltaic power generation device. FIG.
BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a photovoltaic apparatus,
FIG. 3 is an assembled flat cross-sectional view of a solar power generator according to the present invention, in which an elevation angle and an azimuth angle are provided with a cable drive device.
FIG. 4 is a vertical cross-sectional view of an assembled rear surface of a solar power generation apparatus according to the present invention, in which an elevation angle and an azimuth angle are provided with a cable drive device.
5 is an assembly right side view of an altitude angle and an azimuth angle of a solar photovoltaic device according to the present invention in which a cable drive device is installed.
6 is a perspective view in which a plurality of sets of unit solar panels provided with a cable driving device are integrated by a cable driving device in terms of an altitude angle and an azimuth angle of the photovoltaic device according to the present invention.
FIG. 7 is a plan view of a plurality of sets of unit solar panel sets in which a cable driving device is installed, in which altitude angles and azimuth angles of the photovoltaic device according to the present invention are integrated by a cable driving device.
FIG. 8 is an assembled perspective view of a cable drive apparatus and a drive arm of a rotary operation arm of the solar power generation apparatus according to the present invention. FIG.
FIG. 9 is a rear vertical cross-sectional view of a cable drive device and a rotary operation arm of the solar power generation device according to the present invention installed as a drive device. FIG.
10 is a right side sectional view of a cable drive device and a rotary operation arm of a solar photovoltaic device according to the present invention.
11 is a vertical cross-sectional view of an operation sequence provided by a cable drive device and a drive device by a rotary operation arm of the solar power generation device according to the present invention.
12 is a plan view of an operation sequence in which a plurality of sets of unit solar panels installed by a driving device of a cable driving device and a rotary actuating arm of a solar photovoltaic device according to the present invention are integrated by a cable driving device
13 is a perspective view in which a plurality of sets of unit solar panels installed with a cable drive device and a drive device by a rotary operation arm of a solar photovoltaic device according to the present invention are integrated by a cable drive device.
FIG. 14 is a plan view of a cable drive device and a drive device using a rotary operation arm of a solar photovoltaic device according to the present invention, in which a plurality of sets of unit solar panels are integrated by a cable drive device.

 The present invention will now be described in detail with reference to the accompanying drawings.

 As shown in FIGS. 2 to 7, the present invention relates to a solar panel set for generating electricity by tracking sunlight along a solar movement path,

          The vertical frame 116 is formed with a slot 111 at a predetermined position on the upper and rear sides of the upper frame 116. The elevation angle guiding pulley 123 is coupled to the pin bolt through- A second slot 112 is formed at a predetermined position on the left and right sides of the lower portion. An azimuth guide pulley 124 is coupled to a pin bolt through hole at a predetermined position on the front and rear sides with a pin bolt, and a cross hinge 119 A frame bracket 117 for joining the left and right sides of the solar panel set to the left and right sides to couple the one side (left and right side) and the base 150 to the lower side to support the solar panel set.

          The array support plate 100 is disposed above the vertical frame 116 to mount the array 101 to form an array support plate 100 of a certain shape and has a cross hinge 119 at the center of the lower constant position, The front and rear sides of the cross hinge 119 are coupled to each other by a panel bracket 118 for joining the front and rear sides The wire hinge portion 115-1 is formed and the horizontal wire hinge portion 115 is formed at a predetermined position in the left and right direction of the central cross hinge portion 114. [

          The elevation angle guiding pulley 123 is installed on one pulley in such a manner that the first guiding cable 121 and the second guiding cable 122 are disposed so as to cross each other in opposite directions, A second guide groove 123-2 is formed on the other side, and a pin bolt accommodating hole is formed in a central portion thereof.

          The first guide grooves 124 (124) are formed on one side of the guide groove center portion so that the third guide ring 131 and the fourth guide cable 132 are installed so as to cross each other so as to move in opposite directions to one pulley of the azimuth guide pulley 124 -1) is formed on the other side, a second guide groove 124-2 is formed on the other side, and a pin bolt receiving hole is formed at the center.

          The height angle main cable 120 is connected to one end of the first operation cable 121 at the lower portion of the array support plate 100 and connected to the vertical wire hinge portion 115-1 formed at the front side of the cross hinge portion 114 And the other side is supported by the first guide groove 123-1 formed in the altitude guiding pulley 123 and fixed to the back side of the altitude main cable 120 by the engaging clip 113, The other end of the operation cable 122 is engaged with the vertical wire hinge portion 115-2 formed on the rear side of the cross hinge portion 114, The operation cable 122 is supported by the second guide groove 123-2 formed on the pulley 123 and fixed to the front side of the height angle main cable 120 by the engaging clip 113 before and after the other side of the operation cable 122 Let him move to the room.

           The azimuth angle main cable 120 is positioned below the array support plate 100 and is coupled to one side of the third operation cable 131 on the horizontal wire hinge part 115-3 formed on the right side of the cross hinge part 114 And the other end is supported by the first guide groove 124-1 formed on the azimuth angle guiding pulley 124 and connected to the third operation cable 121 by the engaging clip 113 at a predetermined position on the left side of the azimuth angle main cable 130, One end of the fourth operating cable 132 is engaged with the horizontal wire hinge portion 115-4 formed on the left side of the cross hinge portion 114 and the other end is connected to the azimuth guide pulley 124 The other side of the fourth operation cable 132 is coupled to the left and right sides of the azimuth angle main cable 130 by the engagement clip 113 at a predetermined position on the right side of the azimuth angle main cable 130.

           The front and rear edge elevation angle driving portions 170 and 170-1 are formed by coupling one side of the V-belt 55 to the motor pulley 52 coupled to one side of the altitude angle driving motor 50, The other side of the V-belt 55 is connected to the primary power transmission pulley 53 coupled with the primary shaft 51 and a plurality of secondary power transmission pulleys 54 are formed at certain positions of the shaft shaft 51, The front end of the main cable 120 is coupled to the plurality of secondary power transmission pulleys 54 so that the altitude angle drive motor 50 of the altitude angle drive units 170 and 170-1 is rotated by the shaft axis 51 A plurality of secondary power transmission pulleys 54 coupled to a plurality of secondary power transmission pulleys 54 are forwardly rotated and a plurality of secondary power transmission pulleys 54 are coupled to the high altitude main cable 120, Each main cable 120 is moved forward. At this time, the altitude angular drive motor 50 of the altitude angular drive unit 170-1 at the rear edge is reversely rotated, and the altitude angular main cable 120 is provided with the unwinding means.

          The left and right edge azimuth driving units 180 and 180-1 are formed by coupling one side of a V-belt 55 to a motor pulley 52 coupled to one side of an azimuth driving motor 60, And a plurality of secondary power transmission pulleys 54 are formed at predetermined positions of the shaft shaft 51 to form an azimuth angle main cable 130 are coupled to a plurality of secondary power transmission pulleys 54 so that the azimuth driving motor 60 of the azimuth driving units 180, The main power transmission pulley 54 coupled to the main power transmission pulley 54 is rotated forward and the main power transmission pulley 54 is coupled to the main power transmission pulley 54, Is moved to the right side. At this time, the azimuth driving motor 60 of the azimuth driving unit 180-1 at the left edge reversely rotates, and the azimuth angle main cable 130 is provided with a releasing unit.

           The turnbuckle 190 is characterized in that it includes a buckle 190 at a predetermined position of the elevation angle meande cable and the azimuth angle mee cable.

          Hereinafter, the operation and effect of the tracking support structure of the cable structure according to the present invention will be described.

 The elevation angle guiding pulley 123 is coupled to the first slot 111 of the vertical frame 116 integrated with the base 150 by a pin bolt, The azimuth guide pulley 124 is coupled to the slot 112 with the pin bolt and the frame bracket 117 at the upper end of the vertical frame 116 is coupled to one side of the cross hinge 119, The array supporting plate 100 having the vertical wire hinge part 115-1 at the back side fixed position and the horizontal wire whiskers 115 at the left and right fixed positions is coupled to the other side of the cross hinge 119, The array 101 is coupled to the top of the array support plate 100.

           One side of the first operating cable 121 is connected to the longitudinal wire whiskers 115-1 under the array supporting plate 100 and the other side is connected to the first guiding grooves 123 formed in the altitude guiding pulley 123 -1), and the other end of the first operation cable 121 is connected to the rear portion of the altitude main cable 120 at a predetermined position by the engaging clip 113, and the longitudinal wire- And the other side is supported by the second guide groove 123-2 formed in the elevation angle guide pulley 123 and the other side of the elevation angle main cable 120 to the other side of the No. 2 actuating cable 122 with the engaging clip 113 at a predetermined position forward.

          One side of the third operating cable 131 is connected to the horizontal wire white portion 115-3 formed on the right side of the crisscross white portion 114 on the lower side of the array supporting plate 100 and the other side is connected to the azimuth angle guiding pulley 124 The other side of the third operation cable 121 is connected to the first side of the azimuth angle main cable 130 at a predetermined position on the left side of the azimuth angle main cable 130 by the engagement clip 113, The other end of the fourth cable 132 is connected to the second wire guide groove 124-2 formed in the azimuth guide pulley 124 and the second wire guide groove 124-2 And connects the other end of the fourth operation cable 132 to the engagement clip 113 at a certain position on the right side of the azimuth main cable 130.

          The front and rear edge elevation angle drive units 170 and 170-1 couple one side of the V belt 55 to the motor pulley 52 of the altitude angle drive motor 50, The other side of the V-belt 55 is coupled to the primary power transmission pulley 53 and the plurality of vertical power transmission pulleys 54 at the predetermined position of the shaft shaft 51 are connected to the vertical angle main And the front end of the cable 120 is coupled. At this time, a rear end of the altitude main cable 120 having a plurality of longitudinal shapes is integrally coupled to the altitude angular driving unit 170-1 at the rear edge.

          The left and right edge azimuth driving units 180 and 180-1 are provided on one side of the V-belt 55 on the motor pulley 52 of the azimuth driving motor 60, The other side of the V-belt 55 is connected to the differential power transmission pulley 53 and a plurality of transverse-shaped azimuth angle main cables 130 ). At this time, the azimuth driving unit 180-1 at the left edge is driven to integrally drive the left end of the azimuth angle main cable 130 having a plurality of turning directions to the azimuth driving unit 180-1.

          The turn buckle 190 is installed at a predetermined position of the elevation angle meande cable and the azimuth angle mee cable.

          The operation and effect of the assembled solar panel set will be described below.

         First, when the sun tracking device senses the altitude angle of the sun by the sensor and transfers the electric signals to the front and rear edge altitude driving units 170 and 170-1, the front altitude angle driving motor 50 And the rear elevation angle drive motor 50 is rotated in the reverse direction to turn the elevation angle main cable 120 backward and the first operation cable 121 coupled to the elevation angle main cable 120 at a predetermined position, And the second operation cable 122 performs a release operation so that the array support plate 100 rotates in the vertical direction by a predetermined angle.

          When the sun tracking device senses the azimuth angle of the sun by the sensor and transfers the electric signals to the left and right edge azimuth drive sections 180 and 180-1, the right azimuth drive motor 60 rotates forward, The azimuth driving motor 60 is rotated in the opposite direction so that the azimuth angle main cable 130 moving in the left direction moves to the left and the third operation cable 131 coupled to a certain position of the azimuth angle main cable 130 performs the pulling operation, The second operation cable 132 is operated to perform a release operation so that the array support plate 100 rotates to the right by a predetermined angle.

          Also, as shown in FIGS. 7 to 13,

          The vertical frame 216 has a first slot 211 formed at a predetermined position on the front surface thereof and a first elevation angle guide pulley 223 formed by pin bolts on a pin bolt through hole at a predetermined position on the left and right sides, A second altitude guiding pulley 224 is formed at a predetermined position and is engaged with a pin bolt through hole at a predetermined position on left and right sides by a pin bolt, A frame bracket 217 for joining one side and a flange support 201 at the lower end are coupled to the base to rotate and support the solar panel set.

          The array support plate 100 is positioned above the vertical frame 216 to mount the array 101 to form the array support plate 100 of a certain type and form a white pad 214 at the center, Longitudinal wire whiteness 215-1 and 215-2 are formed at predetermined positions on the front and rear sides of the portion 214 and a support white paper sheet portion 241 is formed at a predetermined position on the left and right sides of the center white paper sheet 214, Let each exercise.

          The first elevation angle guiding pulley 223 is formed with a pin bolt receiving hole at a central portion thereof and forms a guide groove to support the first operating cable 221.

          The second elevation angle guiding pulley 224 is formed with a pin bolt receiving hole at the center thereof and forms a guide groove to support the second operating cable 222.

          The first elevation angle third guide pulley 225 has a pin bolt receiving hole formed at the center thereof and is formed with a guide groove and is rotated 90 degrees to the right of the elevation angle main cable 220. In the third elevation angle third guide pulley 225, The guide pulley 225 is installed so that the second operation cable 222 and the elevation angle main cable 220 form a parallel line in the same direction as the azimuth angle main cables 230 and 231 to support the second operation cable 222 .

           The second elevation angle fourth guide pulley 226 is formed with a pin bolt receiving hole at the center thereof and is formed with a guide groove and is rotated 90 degrees to the left direction of the altitude main cable 220, The guide pulley 226 is installed so that the No. 1 actuating cable 222 and the elevation angle main cable 220 form parallel in the same direction as the azimuth angle main cables 230 and 231 to support the No. 1 actuating cable 221 .

           The height angle main cable 220 is connected to one end of the first operation cable 221 on the vertical wire hinge part 215-1 located on the front side with respect to the hinge part 214, And the other side is supported by the groove 223-1 formed in the first altitude guiding pulley 223 and the operation cable 221 is coupled to one end of the second cable 222 and the other end of the second cable 222 is engaged with the longitudinal wire white portion 215-2 formed on the rear side with respect to the white portion 214, The other end of the second actuating cable 222 is coupled with the engaging clip 213 at a predetermined position on the left side of the altitude main cable 220 while being supported by the groove 224-1 formed in the altitude guiding pulley 224, .

            The azimuth angle main cables 230 and 231 are connected to the first and second rotation clamps 251 and 252 formed at the opposite ends of the rotary operation arm 250 by connecting the azimuth angle main cables 230 and 231 to the coupling cap 255 Combine with coupling bolts to adjust azimuth angle.

           The rotary operation arm 250 is positioned on the lower outer circumferential surface of the vertical frame 216 to form a key receiving groove with the vertical frame 216 coupling hole 216-1, Means for forming a coupling hole of the first rotary clamp 251 at one side edge and forming a coupling hole of the second rotary clamp 252 at the other side edge to perform azimuthal rotary motion.

            The first and second rotary clamps 251 and 252 are provided with a shaft shaft 253 at a lower portion thereof for coupling to the opposite ends of the rotary actuating arm 250 and are provided with an azimuth angle main cable 230 and 231 A coupling cap 254 having a bolt coupling hole and a cable receiving groove formed therein is formed and a coupling cap 255 having a cable receiving groove and a coupling bolt through hole for coupling the azimuth angle main cables 230 and 231 is formed, When the arm 250 rotates in the opposite direction, the azimuth angle main cables 230 and 231 rotate in azimuth angle and angle in a straight line.

            The body frame housing 202 includes a vertical frame 216 receiving hole formed at a central portion thereof for supporting the integral flange support 201 at the lower end of the body frame 200 and a flange- A groove 202-1 is formed at a predetermined position of the coupling groove and a coupling bolt through hole 202-3 is formed at a predetermined position of the outer periphery to support the solar panel set.

            The base 260 is formed with a through hole 260-1 for the first operating cable 221 and a second operating cable 222 at the center for coupling and supporting the body frame housing 202, A bracket 227 for coupling the altitude angle fourth guide pulleys 226 is formed to face each other on the edge of the through hole 206-1 and a set anchor 261 receiving hole 260-2 is formed at a predetermined position on the outer circumferential surface, To support the solar panel set.

          The left and right side elevation angle driving portions 270 are formed by coupling one side of a V-belt 55 to a motor pulley 52 coupled to one side of the altitude angle driving motor 50, The other side of the V-belt 55 is coupled to the primary power transmission pulley 53 coupled together and a plurality of secondary power transmission pulleys 54 are formed at a predetermined position of the shaft shaft 51, Is coupled to a plurality of secondary power transmission pulleys 54 so that the altitude angular drive motors 50 of the altitude angular drive units 270 and 270-1 are provided on the shaft shaft 51 at a plurality of The secondary power transmission pulley 54 coupled transversely is rotated in the normal direction so that the upper and lower main power transmission pulleys 54, 120 are moved forward. At this time, the altitude angular drive motor 50 of the altitude angular drive unit 170-1 at the rear edge is reversely rotated, and the altitude angular main cable 220 is provided with the unloading means so that a large number of the array support plates 100, Each rotation has means to operate.

          The left and right edge azimuth drive unit 280 is formed by coupling a V-belt 55 to a motor pulley 52 formed on one side of the azimuth drive motor 60, A pulley 56 is formed and a double rotary operation arm 255 having first 251, second 252, third 253 and fourth rotary clamps 254 is formed, The second rotary clamp 252 is formed to engage with the end of the azimuthal other side main cable 231 while the third rotary 251 is coupled to the end of the azimuthal one side main cable 230, The rotary clamp 254 is connected to the third 253-1 of the double rotary actuating arms 255 of the front and rear row extensions on the front and rear sides and the first power transmission cable 232 to the fourth rotary clamp 254-1, And the power transmission cable 234 are coupled to each other so that a plurality of array support plates 100 are unitarily rotated azimuthally.

           The turn buckle (290) is provided with a turn buckle (290) at a predetermined position of the altitude main cable and the azimuth angle main cable to adjust the tensile strength of the main cable.

          Hereinafter, the operation and effect of the tracking support structure of the cable structure according to the present invention will be described.

          First, a process of assembling the main body frame to install the main frame will be described.

          After coupling the rotary actuating arm 250 to the vertical frame 216 first and then coupling the body frame housing 202 and coupling the flange support 201 to the vertical frame 216, To the base 260 with a coupling bolt.

          An array supporting plate (not shown) having a center white portion 214, vertical wire whitening portions 215-1 and 215-2 and left and right support hinges 241 formed on the upper frame bracket 217 of the vertical frame 216 100).

          Then, the first elevation angle guiding pulley 223 is coupled to the first slot 211 together with the coupling bolt, the second elevation angle guiding pulley 224 is coupled to the second slot 212 together with the coupling bolt, 1 altitude Each third guide pulley 225 is coupled to a bracket 227 formed on the right side of the lower portion of the base 260 while being rotated 90 degrees to the right, And is coupled to a bracket 227 formed on the left side of the lower portion of the base 260 to support the first and second operation cables 221 and 222.

           One side of the first operation cable 221 is connected to the longitudinal wire white portion 215-1 and the other side is supported by the groove 223-1 formed in the first altitude guiding pulley 223, The first operation cable 221 is coupled with the coupling clip 213 at a predetermined position on the right side of the main cable 220 and the second operation cable 222 side is connected to the longitudinal wire white paper 215-2 formed on the rear side And the other side is supported by the groove 224-1 formed in the second height angle guiding pulley 224 and the other side of the operation cable 222 at the predetermined position on the left side of the altitude main cable 220, (213).

          The azimuth angle main cables 230 and 231 are coupled to the first cap 251 and the second rotation clamp 252 at the opposite ends of the rotary operation arm 250 with the coupling cap 255 and the coupling bolt, respectively.

           The left and right side elevation angular drive units 270 and 270-1 couple one side of the V-belt 55 to the motor pulley 52 of the altitude angular drive motor 50, Belt 55 to the primary power transmission pulley 53 and a plurality of secondary power transmission pulleys 54 at a certain position of the shaft shaft 51 are provided with a plurality of transversely arranged height- And the right end of the cable 220 is connected. At this time, a rear end of the altitude main cable 220 having a plurality of transverse shapes is connected to the altitude angular drive unit 270-1 at the left edge to drive the unit altogether.

           The left and right edge azimuth drive unit 280 is connected to the motor pulley 52 of the azimuth drive motor 60 and the operation arm pulley 56 coupled to the other side of the V- The double rotary actuating arm 255 to which the first 251, the second 252, the third 253 and the fourth rotary clamp 254 are coupled integrally with the vertical shaft, The rotary clamp 251 is coupled with the end of the azimuthal side main cable 230 and the second rotary clamp 252 is coupled with the end of the azimuthal other side main cable 231, The rotary clamp 254 is connected to the third 253-1 of the double rotary actuating arms 255 of the front and rear row extensions on the front and rear sides and the first power transmission cable 232 to the fourth rotary clamp 254-1, And are coupled with each other by a power transmission cable 234.

           The turn buckle 290 couples the turn buckle 290 to a predetermined position of the altitude main cable and the azimuth angle main cable.

          The operation and effect of the assembled solar panel set will be described below.

         First, when the sun tracking device senses the altitude of the sun by the sensor and transfers the electric signals to the left and right side elevation angle driving parts 270 and 270-1, the right altitude angle driving motor 50 And the first operation cable 221, which is rotated in the normal direction and is rotated in the opposite direction by the reverse rotation of the left elevation angle drive motor 50, moves to the right and the elevation angle main cable 220 is moved to the right, And the second operation cable 122 performs a pulling operation so that the array support plate 100 rotates at a right angle to the left (or right) vertical direction.

          When the sun tracking device senses the azimuth angle of the sun by the sensor and transfers electric signals to the left and right edge azimuth driving sections 280 and 280-1, the right azimuth angle The driving motor 60 rotates in the forward direction and the left azimuth driving motor 60 to which the double rotating arm 255 is coupled is rotated in the reverse direction so that one end and the other end of the azimuth angle main cables 230 and 231 are connected to the double rotary operation arm Angle side main cable 230 coupled to the rotary clamps 251-1 and 252-1 of the first and the second azimuth angle side main cables 231 and 255 and moved in the left direction of the azimuth other side main cable 231, The diagonal main cables 230 and 231 are moved to the left or right in opposite directions with the rotation clamps 251 and 252 of the mounted rotary operation arm 250 so that the array supporting plate 100 moves to the right ) Direction There is a rotating feature.

         Further, the present invention is not limited to the solar cable drive apparatus of the present invention, and it can be applied to a solar reflector, can be applied as a chain instead of a cable, can be applied as a round bar (or pipe) Timer Belt, Chain and Shaft are used to apply the above-mentioned parts to the proper place according to the characteristics of the installation site and to adapt to the initial construction cost and the durability of the outside environment.

00; Array support plate 116; Vertical frame
114; A cross hinge portion 120; Altitude each main cable
121; No. 1 operating cable 122; No. 2 operating cable
123; An altitude guiding pulley 124; Azimuth guide pulley
130; An azimuth angle main cable 131; No. 3 operating cable
132; No. 4 operating cable 150; Base
200; Body frame 240; support
250; A rotary operation arm 270; Altitude angular drive
280; An azimuth driving unit 290; Turn buckle

Claims (2)

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a solar panel set for generating electricity by tracking sunlight along a solar path,
A first slot 111 is formed at a predetermined position on the front and back of the vertical frame 116, a pin bolt through-hole is formed at a predetermined position on the left and right sides, a height angle guiding pulley 123 is formed, A second slot 112 is formed at a predetermined position on the right side surface, a pin bolt through-hole is formed at a predetermined position on the front and back sides, an azimuth guide pulley 124 is formed, and one side of the cross- A main frame 110 having a base 150 integrated with a lower end thereof; An array 101 (which is referred to as a module in which solar cells are combined in a certain form and which is a combination of modules in a certain form is referred to as an array.) Hereinafter, A panel bracket 118 is formed at a central portion of the lower fixed position, a longitudinal wire white paper sheet 115-1 is formed at a predetermined position on the front and rear sides, An array supporting plate 100 on which a horizontal wire portion 115 is formed; A pinion bolt receiving hole is formed in a central portion thereof and a first guide groove 123-1 is formed on one side of the guide groove center portion and a second guide groove 123-2 is formed on the other side, 123); And an azimuthal guidance pulley 124-1 having a first guide groove 124-1 formed at one side thereof and a second guide groove 124-2 formed at the other side thereof with a pin bolt receiving hole formed at the center portion thereof, ): The other side of the first operation cable 121 is connected to the rear side of the altitude main cable 120 by the engaging clip 113 and the second side of the operation cable 121 is connected to the engaging clip 113 at the predetermined position in front of the altitude main cable 120 An elevation angle main cable 120 to which the other side is coupled; The other side of the third operation cable 131 is coupled to the fixed position of the azimuth angle main cable 130 at the predetermined position on the left side of the azimuth angle main cable 130 and the fourth operation cable 132) an azimuth angle main cable 120 connecting the other side; A V-belt 53 is coupled to a motor pulley 54 formed on one side of the altitude driving motor 50 to form a power transmission pulley 52 coupled to the other side of the V-belt 53, A plurality of pulleys 52 are formed at a predetermined position of the shaft shaft 51 so that one side of the elevation angle main cable 220 is connected to the power transmission pulley A left and right edge elevation angle driving unit 170 coupled to the left and right edge elevation angle driving units 52; A V-belt 53 is coupled to a motor pulley 54 formed on one side of the azimuth drive motor 50 to form a power transmission pulley 52 coupled to the other side of the V-belt 53, A shaft shaft 51 coupled to a central portion of the pulley 52 is formed and a plurality of pulleys 52 are formed at a predetermined position of the shaft shaft 51 so that one side of the elevation angle main cable 220 is connected to the power transmission pulley 52 A left and right edge azimuth driving section 180 coupled to the left and right edge azimuth driving section 180;
Characterized in that it comprises a turn buckle (290) at a predetermined position of the elevation angle mezzanine cable and azimuth angle meem cable. The apparatus as claimed in claim 1, wherein a first slot (211) is formed at a predetermined position on a front surface of the vertical frame (216) according to the present invention, and a first elevation angle guidance pulley A second elevation angle guiding pulley 224 is formed by a pin bolt on a pin bolt through hole at a predetermined position on the left and right sides, A body frame 200 formed with a frame bracket 217 for engaging with the hinge part 214 and having a flange type support 201 integrated at the lower end thereof;
The array supporting plate 100 is formed on the vertical frame 216 to mount the array 101 and a hinge part 214 is formed at the center part of the array supporting plate 100. The front and rear sides of the hinge part 214 An array supporting plate 100 in which longitudinal wire hinges 215-1 and 215-2 are formed at predetermined positions and a support hinge part 241 is formed at a predetermined position on the left and right sides of the central hinge part 214;
A first elevation angle guidance pulley 223 having a pin bolt receiving hole formed at its center and having a guide groove formed therein,
A second altitude guiding pulley 224 having a pin bolt receiving hole formed at its center and having a guide groove,
One end of the operation cable 221 is engaged with the vertical wire hinge portion 215-1 located at the lower side of the base 260 and formed on the front side with respect to the hinge portion 214, The other end of the first operation cable 221 is engaged with the engaging clip 213 at a predetermined position on the right side of the altitude main cable 220 while being supported by the groove 223-1 formed in the altitude guiding pulley 223, One end of the second actuating cable 222 is engaged with the vertical wire hinge portion 215-2 formed on the rear side with respect to the hinge portion 214 and the other end of the second actuating cable 222 is engaged with the second elevation angle guiding pulley 224 An elevation angle main cable 220 which is supported by the formed groove 224-2 and is coupled to the other side of the operation cable 221 at a predetermined position on the left side of the altitude main cable 220 with the engaging clip 213;
An azimuth angle main cable 230 for coupling the azimuth angle main cables 230 and 231 to the first cap 251 and the second rotation clamp 252 formed at both ends of the rotary operation arm 250 with the coupling cap 255 and the coupling bolt 230 , 231);
A key receiving groove is formed in the vertical frame 216 coupling hole 216-1 at a lower outer circumferential surface of the vertical frame 216. A coupling hole of the first rotary clamp 251 is formed at one side edge, The second rotary clamp 252 includes a rotary operation arm 250 having a coupling hole formed therein.
A shaft 253 is formed at a lower portion to be engaged with both ends of the rotatable operation arm 250 and a support 254 formed with a bolt coupling hole for coupling the azimuth angle main cables 230, First 251, second rotary clamp 252;
A coupling cap 255 having a coupling groove and a coupling bolt coupling hole for coupling the azimuth main cables 230 and 231;
A vertical frame 216 receiving hole is formed at a central portion for supporting the rear type support 201 integrated at the lower end of the main body frame 200 and a flange type support 201 coupling groove is formed on the inner peripheral surface, A body frame housing 202 having a bearing engagement groove formed at a predetermined position and having a coupling bolt through-hole formed at a predetermined position on an outer peripheral surface thereof;
The first and second operating cables 222 and 222 are formed at the central portion of the main body frame housing 202 to support the main body frame housing 202. The third and fourth altitude angle brackets 225, A base 260 formed with a bracket 227 for coupling the pulleys 226 to face each other on the edge of the through hole and having a set anchor 261 receiving hole at a predetermined position on the outer circumferential surface,
A V-belt 55 is coupled to the motor pulley 52 at one side of the altitude driving motor 50, a primary power transmission pulley 53 is formed at the other side of the V-belt 55, A shaft shaft 51 coupled to a central portion of the pulley 53 is formed and a plurality of secondary power transmission pulleys 54 are formed at predetermined positions of the shaft shaft 51, A left and right edge height driving unit 270 coupled to the transmission pulley 54;
A V belt 55 is coupled to a motor pulley 52 formed on one side of the azimuth drive motor 60 and an operation arm pulley 56 is formed on the other side of the V belt 55. The first 251, A double rotary operation arm 255 having a second 252, a third 253 and a fourth rotary clamp 254 is formed and the first rotary 251 and the second rotary 252 are connected to the azimuthal side And the fourth rotary clamp 254 is engaged with the third and fourth rotary clamps 254 and 252 formed on the front and rear double row rotary actuating arms 255 on the front and rear sides, A left and right edge azimuth driving unit 280 coupled to the fourth rotary clamp 254 by a first power transmission cable 232 and a second power transmission cable 234;
And a turnbuckle (290) at an altitude main cable and an azimuth main cable at a predetermined position.

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