CN102968126B - A kind of biaxial sun-tracking follower - Google Patents

A kind of biaxial sun-tracking follower Download PDF

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Publication number
CN102968126B
CN102968126B CN201210510732.6A CN201210510732A CN102968126B CN 102968126 B CN102968126 B CN 102968126B CN 201210510732 A CN201210510732 A CN 201210510732A CN 102968126 B CN102968126 B CN 102968126B
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supporting construction
photovoltaic module
module plate
mirror board
girder truss
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CN102968126A (en
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丁慈鑫
张庆中
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Zhang Qingzhong
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    • YGENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
    • Y02TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
    • Y02BCLIMATE CHANGE MITIGATION TECHNOLOGIES RELATED TO BUILDINGS, e.g. HOUSING, HOUSE APPLIANCES OR RELATED END-USER APPLICATIONS
    • Y02B10/00Integration of renewable energy sources in buildings
    • Y02B10/10Photovoltaic [PV]
    • YGENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
    • Y02TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
    • Y02EREDUCTION OF GREENHOUSE GAS [GHG] EMISSIONS, RELATED TO ENERGY GENERATION, TRANSMISSION OR DISTRIBUTION
    • Y02E10/00Energy generation through renewable energy sources
    • Y02E10/50Photovoltaic [PV] energy

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Abstract

Embodiments provide a kind of biaxial sun-tracking follower, comprise basis, the first supporting construction, the second supporting construction, the first driving mechanism, the second driving mechanism, photovoltaic module plate and mirror board; First supporting construction is rotatably supported on basis; Second supporting construction is hinged in the first supporting construction; First driving mechanism is connected with basis and the first supporting construction; Second driving mechanism is connected between the first supporting construction and the second supporting construction; Photovoltaic module plate and mirror board are fixed in the second supporting construction, and mirror board is fixed on the lower end of photovoltaic module plate and has one with photovoltaic module plate and be greater than 90 degree and be less than the angle of 135 degree.Biaxial sun-tracking follower of the present invention, both be applicable to power station, roof and be also applicable to surface power station, it adds mirror board in the lower end of photovoltaic module plate, to fail to obtain the light energy reflected of Appropriate application on photovoltaic module plate, its cost relative moderate, Stability Analysis of Structures and generated energy income can be increased substantially.

Description

A kind of biaxial sun-tracking follower
Technical field
The present invention relates to a kind of biaxial sun-tracking follower being applied to photo-voltaic power generation station.
Background technology
In current photo-voltaic power generation station support scheme, mainly contain fixed angle support, single-axis sun tracking follower and biaxial sun-tracking follower three kinds of mounting meanss.According to the Practical Project statistics in China's To Golmud of Qinghai area, under identical installed capacity condition: single-axis sun tracking follower comparable fixed angle support mode increases annual electricity generating capacity about 15% ~ 25%, biaxial sun-tracking follower comparable fixed angle support mode increases annual electricity generating capacity about 30% ~ 40%.But due to the investment cost of single shaft or biaxial sun-tracking follower and long-time running maintenance cost higher, the ratio of the income therefore increased and the input of increase is too low, and its economic advantages are also not obvious, and the application at present in photo-voltaic power generation station is less.Moreover, it also has some defects on technical economical index, such as land used is more, and installed capacity density is lower, and consumption low-voltage cable is more, mechanism's center of gravity is higher, steel quantity consumption is comparatively large, need configure accurate gearing, need excavate larger foundation ditch during construction, need build large volume gravity type concrete basis, consumption building materials are more etc.For above-mentioned various reasons, the mounting means of current industry main flow or fixed angle support mode.
But consider the long term growth of photovoltaic generation industry, people expect that biaxial sun-tracking follower can become the mounting means of main flow, thus progressively eliminate fixed angle support mode.Therefore, be necessary to research and develop novel biaxial sun-tracking follower, give full play to the advantage that its annual generated energy is more, overcome the weakness of its prior art economic target parameter simultaneously, improve cost performance.
Summary of the invention
In view of this, be necessary for the problems referred to above, a kind of cost relative moderate, Stability Analysis of Structures and can increase substantially the biaxial sun-tracking follower of annual generated energy income are provided.
For achieving the above object, the present invention by the following technical solutions:
A kind of biaxial sun-tracking follower, it comprises basis, the first supporting construction, the second supporting construction, the first driving mechanism, the second driving mechanism, photovoltaic module plate and mirror board; Described basic upper surface is fixed with round circular orbit; Described first supporting construction is rotatably supported on described basis; Described second supporting construction is hinged in the first supporting construction; Described first driving mechanism is connected with basis and the first supporting construction, rotates on basis for driving the first supporting construction around the axis of a vertical direction; Described second driving mechanism is connected between the first supporting construction and the second supporting construction, rotates in the first supporting construction for driving the second supporting construction around the axis of a horizontal direction; Described photovoltaic module plate and mirror board are fixed in the second supporting construction, and mirror board is fixed on the lower end of photovoltaic module plate and has one with photovoltaic module plate and be greater than 90 degree and be less than the angle of 135 degree; Described first supporting construction is a triangle extended in the horizontal direction or girder truss that is trapezoidal or square-section, at least six rollers are distributed with in the form of a ring bottom described girder truss, described roller to be fixedly installed under described girder truss and to roll and is installed on round circular orbit, and girder truss is rotatably supported on round circular orbit by roller.
Described second supporting construction passes through at least two bearing hinge connections on the top boom at described girder truss top; Described second driving mechanism comprises at least two electric pushrod parts, and the lower stiff end of described electric pushrod parts is articulated with on the web member of girder truss side, and upper movable end and second supporting construction of electric pushrod parts are hinged.
Be fixed on the photovoltaic module plate in the second supporting construction parallel with the bearing of trend of girder truss with the pattern length bearing of trend of mirror board.
It is characterized in that the angle between photovoltaic module plate and mirror board, between the combined width of mirror board and the combined width of photovoltaic module plate, there is following relation:
L 2=L 1×[sin(180°-α)×cot(α-90°)-cos(180°-α)]
Wherein, L 1for the combined width of photovoltaic module plate, L 2for the combined width of mirror board, α is the angle between photovoltaic module plate and mirror board.
Described photovoltaic module plate is identical with the pattern length of mirror board, and the pattern length of photovoltaic module plate is 1.5 to 5 times of the combined width of photovoltaic module plate.
Described first driving mechanism comprises windlass and wire rope, windlass is fixed on girder truss, output terminal and the basis or round circular orbit of windlass are passed through together with wirerope-winding, and described motor drags girder truss by wire rope and rotates along round circular orbit on basis.
Described basis is annular solid foundation, the uniform pile foundation of annular or the uniform pile foundation of annular.
An arm of force beam is provided with, the extending in the horizontal direction and perpendicular to the bearing of trend of girder truss, arm of force beam be fixed with balancing weight of described arm of force beam in the middle part of described girder truss.
The bottom of described arm of force beam is provided with at least two rollers, and described roller to be fixedly installed under arm of force beam and to roll and is installed on round circular orbit.
Biaxial sun-tracking follower of the present invention, add mirror board in the lower end of photovoltaic module plate, will fail to obtain the light energy reflected of Appropriate application on photovoltaic module plate, input with low cost, but under the prerequisite of demand not increasing soil, very large generated energy income can be obtained.Meanwhile, use girder truss as the supporting construction of vertical direction, girder truss by multiple roller as fulcrum support on basis, add the stability of biaxial sun-tracking follower.Biaxial sun-tracking follower of the present invention, cost relative moderate, Stability Analysis of Structures and annual generated energy income can be increased substantially.
Accompanying drawing explanation
Fig. 1 is one-piece construction schematic diagram of the present invention.
Fig. 2 is the side structure schematic diagram of the embodiment of the present invention.
Fig. 3 is the I-I face cut-open view of Fig. 2.
Reference numeral:
Basis 1 first supporting construction 2 second supporting construction 3
First driving mechanism 4 second driving mechanism 5 photovoltaic module plate 6
Mirror board 7 round circular orbit 10 roller 20
Arm of force beam 21 balancing weight 22 windlass 41
Wire rope 42 bearing 30 direct sunlight A
Embodiment
Below in conjunction with accompanying drawing and specific embodiment, the present invention will be described in detail.
As shown in Figure 1, biaxial sun-tracking follower of the present invention comprises basis the 1, first supporting construction 2, second supporting construction 3, first driving mechanism 4, second driving mechanism 5, photovoltaic module plate 6 and mirror board 7; Described first supporting construction 2 is rotatably supported on described basic 1; Described second supporting construction 3 is hinged in the first supporting construction 2; Described first driving mechanism 4 is connected with basis 1 and the first supporting construction 2, rotates for driving the axis of the first supporting construction 2 around a vertical direction on basis 1; Described second driving mechanism 4 is connected between the first supporting construction 2 and the second supporting construction 3, rotates in the first supporting construction 2 for driving the second supporting construction 3 around the axis of a horizontal direction; Described photovoltaic module plate 6 and mirror board 7 are fixed in the second supporting construction 3, and mirror board 7 is fixed on the lower end of photovoltaic module plate 6 and has one with photovoltaic module plate 6 and be greater than 90 degree and be less than the angle α of 135 degree.
As shown in Figures 2 and 3, be a preferred embodiment of the present invention.Particularly, described basic 1 is fixed on level ground, and it has multiple way of realization, and typically basic 1 way of realization comprises annular solid foundation, the uniform pile foundation of annular and the uniform pile foundation of annular.The embodiment of the present invention adopts annular solid foundation, and the upper surface on basis 1 is fixed with round circular orbit 10.Described first supporting construction 2 is the girder truss of a triangle extended in the horizontal direction, trapezoidal or square-section.In embodiments of the present invention, the first supporting construction 2 is triangular truss beam.The bottom of described girder truss is distributed with at least six rollers 20 in the form of a ring, described roller 20 to be fixedly installed under described girder truss and to roll and is installed on round circular orbit 10, and girder truss is rotatably supported on the round circular orbit 10 on basis 1 by least six rollers 20; As improvement, also can configure rail clamping device or overturn-preventing hook under girder truss, described rail clamping device or overturn-preventing hook are connected with round circular orbit 10, in case girder truss and superstructure entirety thereof are toppled.
Be provided with an arm of force beam 21 formed as one with girder truss in the middle part of described girder truss, described arm of force beam 21 extends and in the horizontal direction perpendicular to the bearing of trend of girder truss.Described arm of force beam 21 is fixed with balancing weight 22, and described balancing weight 22 is positioned at the opposite side of photovoltaic module plate 6 and mirror board 7, for making the center of gravity of biaxial sun-tracking follower near vertical turning axle, strengthens stability and the resistance to capsizing of the first supporting construction 2.Be fixed with a roller 20 bottom the two ends of arm of force beam 21 respectively, described roller 20 to be fixedly installed under described girder truss and to roll and is installed on round circular orbit 10.
Described first driving mechanism 4 comprises windlass 41 and wire rope 42, windlass 41 is fixed on the arm of force beam 21 of girder truss, the output terminal of windlass 41 is intertwined by wire rope 42 with basis 4 or round circular orbit 10, described windlass 41 drags girder truss by wire rope 42, is rotated on basis 1 by roller 20 along round circular orbit 10.Particularly, in embodiments of the present invention, windlass 41 is fixed on one end of arm of force beam 21, and wire rope 42 is wound around a circle and fixes with it in basic 1 southern side on basis 1, also on the output terminal roll shaft of windlass 41, is wound around a few simultaneously.When windlass 41 rotates, by the dragging effect of wire rope 42, windlass 41 self is rotated around basis 1, drag the first supporting construction 2 axis vertically simultaneously and rotate.
Described second supporting construction 3 is articulated with on the top boom at described girder truss top by least two bearings 30.Described second driving mechanism 5 comprises at least two electric pushrod parts, and the lower stiff end of described electric pushrod parts is articulated with on the web member of girder truss side, and upper movable end and second supporting construction 3 of electric pushrod parts are hinged.
Be fixed on the photovoltaic module plate 6 in the second supporting construction 3 parallel with the bearing of trend of girder truss with the length bearing of trend of mirror board 7.Described photovoltaic module plate 6 is identical with the pattern length of mirror board 7, and the pattern length of photovoltaic module plate 6 is 1.5 to 5 times of the combined width of photovoltaic module plate 6, and namely the pattern length of photovoltaic module plate 6 is much larger than its combined width.This makes the combined area of photovoltaic module plate 6 be flattening, causes array center of gravity lower.It should be noted that, the plate of photovoltaic module described in the embodiment of the present invention 6 can be formed by some sub-photovoltaic module plate permutation and combination, described mirror board 7 can be formed by some sub-mirror board permutation and combination, therefore the pattern length of the photovoltaic module plate 6 described in the present embodiment and combined width refer to entire length and the width of the photovoltaic module plate 6 after combination respectively, the pattern length of mirror board 7 and combined width refer to mirror board 7 entire length after combination and width respectively.
Described second driving mechanism 5 is connected with the controller of windlass 41 with an outside, in the photovoltaic arrays of multiple biaxial sun-tracking follower composition, second driving mechanism 5 of all biaxial sun-tracking followers and windlass 41 can be connected to unified controller, to realize colony's synchro control.During biaxial sun-tracking follower work of the present invention, windlass 41 is under the electric signal instruction that controller sends controls, drag girder truss along vertical axis rotary motion by wire rope 42, thus realize the azimuthal variation of photovoltaic module plate 6, namely according to the azimuthal variation of the sun and real-time change; Electric pushrod parts, under the electric signal instruction that controller sends controls, promote the second supporting construction 3 along horizontal axis rotary motion, thus realize the luffing angle change of photovoltaic module plate 6, namely change and real-time change according to the elevation angle of the sun.Generally speaking, first driving mechanism 4 and the second driving mechanism 5 close fit, drive the first supporting construction 2 and the second supporting construction 3 respectively around vertical axis and horizontal axis rotary motion, make photovoltaic module plate 6 keep vertical relation with the projecting direction of direct sunlight A all the time, keep maximum generation income amount to make photovoltaic module plate 6.
Biaxial sun-tracking follower in hinge structure, the greatest improvement of the embodiment of the present invention is: mirror board 7 has been set up in the bottom of the second supporting construction 3, and within the shade behaviour area of mirror board between each array photovoltaic panel, and mirror board 7 is relative fixing with photovoltaic module plate 6 position, synchronous axial system.Be greater than 90 degree because mirror board 7 and photovoltaic module plate 6 have one and be less than the angle α of 135 degree, and photovoltaic module plate 6 keeps vertical with the projecting direction of direct sunlight A all the time, so the sunshine received can reflex on photovoltaic module plate 6 by mirror board 7, strengthen the light radiation that photovoltaic module plate 6 receives, and then increase generated energy income.
Especially, consider the Cost Problems of mirror board 7, to make the sunlight that mirror board 7 reflects obtain the most sufficient and equally distributed utilization, then need to make the sunlight of mirror board 7 low order end edge incidence in shown in Fig. 1 just reflex to the top edge of photovoltaic module plate 6.Now, the angle α between photovoltaic module plate 7 and mirror board 6, the combined width L of mirror board 2with the combined width L of photovoltaic module plate 1between there is following relation:
L 2=L 1×[sin(180°-α)×cot(α-90°)-cos(180°-α)]
According to above relational expression, as the combined width L of mirror board 2with the combined width L of photovoltaic module plate 1when determining, the best value of the angle α between photovoltaic module plate 7 and mirror board 6 can be calculated very soon.
Based on above-mentioned improvement, the present invention has following beneficial effect:
1, annual generated energy income significantly increases.
In China's To Golmud of Qinghai area, according to statistics display, use the biaxial sun-tracking follower not with mirror board 7 in prior art, comparable fixed angle support mode increases annual generated energy about 35%.
The biaxial sun-tracking follower of the embodiment of the present invention, the direct sunlight A received by mirror board 7 all and reflex on photovoltaic module plate 6 equably, significantly can increase the generated energy of photovoltaic module plate 6.
Suppose the combined width L of mirror board in Fig. 1 2the combined width L of photovoltaic module plate 150%, namely the area of mirror board 7 is 50% of photovoltaic module plate 6 area.Now, mirror board 7 is 126.5 ° with the optimum angle α of photovoltaic module plate 6, is about 29.5% by calculating the light radiation of known increase.Then compared to fixed angle support mode, the annual generated energy that can increase is (1 × 1.35 × 1.295-1) × 100%=75%, and namely increasable annual generated energy is about 75% in theory.Consider the consume in Practical Project, still can increase about 60% of annual generated energy.
Suppose the combined width L of mirror board in Fig. 1 2the combined width L of photovoltaic module plate 1100%, i.e. the area of mirror board 7 and the area equation of photovoltaic module plate 6.Now, mirror board 7 is 120 ° with the optimum angle α of photovoltaic module plate 6, is about 50% by calculating known increase light radiation.Then compared to fixed angle support mode, the annual generated energy that can increase is (1 × 1.35 × 1.50-1) × 100%=102.5%, and namely increasable annual generated energy is about 100% in theory.Consider the consume in Practical Project, still can increase about 80% of annual generated energy.
2, the utilization ratio of land resource improves greatly.
In prior art, in order to the light radiation intensity improving photovoltaic module plate 6 unit area must increase the consumption of land resource.Biaxial sun-tracking follower of the present invention, adds mirror board 7 at the lower eaves of photovoltaic module plate 6, and in photovoltaic array, the distance between adjacent biaxial sun-tracking follower still remains unchanged.Its nature and feature the optical radiation resource be wasted in shade zone of action between former array is carried out excavating and utilizes.Its feature being different from prior art is: the light radiation intensity improving photovoltaic module plate 6 unit area, and does not increase the consumption of land resource.This raising land resources utilization rate, to improve the theory of soil natural endowment development of resources quantum of output, has important social and economic significance, especially for south, the Middle East densely inhabited district that China's land resource is precious.
In To Golmud of Qinghai area, the land use index of existing photo-voltaic power generation station is: identical installed capacity, and traditional solar tracking follower is than the soil of fixed angle support scheme multiplex 75% ~ 80%; Comparatively speaking, when adopting traditional solar tracking follower, although the generated energy of installed capacity improves 30% ~ 40%, the output generated energy in unit area soil greatly reduces 25% ~ 30%.
But adopting the biaxial sun-tracking follower of the embodiment of the present invention, the shade behaviour area due to Appropriate application between adjacent biaxial sun-tracking follower, decreases the waste of land resource; Comparatively speaking, when adopting novel solar tracking follower, the generated energy of installed capacity improves more than 60%, and the quantum of output in unit area soil also improves more than 30%.
3, array resistance to overturning is better.
The biaxial sun-tracking follower of single column of the prior art due to center of gravity higher, single-point support upper load, column root bending moment is very large, need the solid foundation configuring larger-diameter steel column and the larger scale of construction, therefore be difficult to build component palette area more economically more than 100 ㎡, installed capacity is more than single array product of 15KW.And adopting technical scheme provided by the invention, then lower cost can be used to build component palette area more than 100 ㎡, and installed capacity is more than single array product of 15KW.
Because the second supporting construction 3 is that multi-point support is in the first supporting construction 2, and the first supporting construction 2 multi-point support is on round circular orbit 10, round circular orbit 10 is contacted by face or multi-point support is fixed on basis 1, basis 1 be contacted by face or multi-point support on soil base, therefore each level is all multi-point support from top to bottom, and the spacing dimension between each layer strong point is comparatively large, makes array resistance to tipping moment comparatively large, improve resistance to overturning.Again owing to employing girder truss, make the flattening of array component plate combined shaped area, make biaxial sun-tracking follower center of gravity lower, improve resistance to overturning further.Each part of the present invention is simple and practical, and cost relative moderate, makes that the overall manufacturing cost of biaxial sun-tracking follower reduces greatly and technical feature greatly improves.
4, above-mentioned three beneficial effects, impel cost of electricity-generating to reduce further and online sales rate of electricity reduces, and accelerate the development of photovoltaic generation industry.In addition, the embodiment of the present invention had both been applicable to power station, roof and had also been applicable to surface power station.
The above embodiment only have expressed several embodiment of the present invention, and it describes comparatively concrete and detailed, but therefore can not be interpreted as the restriction to the scope of the claims of the present invention.It should be pointed out that for the person of ordinary skill of the art, without departing from the inventive concept of the premise, can also make some distortion and improvement, these all belong to protection scope of the present invention.Therefore, the protection domain of patent of the present invention should be as the criterion with claims.

Claims (7)

1. a biaxial sun-tracking follower, is characterized in that, comprises basis, the first supporting construction, the second supporting construction, the first driving mechanism, the second driving mechanism, photovoltaic module plate and mirror board; Described basic upper surface is fixed with round circular orbit; Described first supporting construction is rotatably supported on described basis; Described second supporting construction is hinged in the first supporting construction; Described first driving mechanism is connected with basis and the first supporting construction, rotates on basis for driving the first supporting construction around the axis of a vertical direction; Described second driving mechanism is connected between the first supporting construction and the second supporting construction, rotates in the first supporting construction for driving the second supporting construction around the axis of a horizontal direction; Described photovoltaic module plate and mirror board are fixed in the second supporting construction, and mirror board is fixed on the lower end of photovoltaic module plate and has one with photovoltaic module plate and be greater than 90 degree and be less than the angle of 135 degree; Described first supporting construction is a triangle extended in the horizontal direction or girder truss that is trapezoidal or square-section, at least six rollers are distributed with in the form of a ring bottom described girder truss, described roller to be fixedly installed under described girder truss and to roll and is installed on round circular orbit, and girder truss is rotatably supported on round circular orbit by roller; Be fixed on the photovoltaic module plate in the second supporting construction parallel with the bearing of trend of girder truss with the pattern length bearing of trend of mirror board;
Angle between photovoltaic module plate and mirror board, between the combined width of mirror board and the combined width of photovoltaic module plate, there is following relation:
L2=L1×[sin(180°-α)×cot(α-90°)-cos(180°-α)]
Wherein, L1 is the combined width of photovoltaic module plate, and L2 is the combined width of mirror board, and α is the angle between photovoltaic module plate and mirror board.
2. biaxial sun-tracking follower according to claim 1, is characterized in that, described second supporting construction passes through at least two bearing hinge connections on the top boom at described girder truss top; Described second driving mechanism comprises at least two electric pushrod parts, and the lower stiff end of described electric pushrod parts is articulated with on the web member of girder truss side, and upper movable end and second supporting construction of electric pushrod parts are hinged.
3. biaxial sun-tracking follower according to claim 1, is characterized in that, described photovoltaic module plate is identical with the pattern length of mirror board, and the pattern length of photovoltaic module plate is 1.5 to 5 times of the combined width of photovoltaic module plate.
4. biaxial sun-tracking follower according to claim 1, it is characterized in that, described first driving mechanism comprises windlass and wire rope, windlass is fixed on girder truss, output terminal and the basis or round circular orbit of windlass are passed through together with wirerope-winding, and described windlass drags girder truss by wire rope and rotates along round circular orbit on basis.
5. the biaxial sun-tracking follower according to claim 1 or 4, is characterized in that, described basis is annular solid foundation, the uniform pile foundation of annular or the uniform pile foundation of annular.
6. biaxial sun-tracking follower according to claim 1, is characterized in that, is provided with an arm of force beam in the middle part of described girder truss, and described arm of force beam extends in the horizontal direction and perpendicular to the bearing of trend of girder truss, arm of force beam is fixed with balancing weight.
7. biaxial sun-tracking follower according to claim 6, is characterized in that, the bottom of described arm of force beam is provided with at least two rollers, and described roller to be fixedly installed under arm of force beam and to roll and is installed on round circular orbit.
CN201210510732.6A 2012-12-03 2012-12-03 A kind of biaxial sun-tracking follower Active CN102968126B (en)

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CN103558860B (en) * 2013-11-04 2016-05-11 上海理工大学 A kind of photovoltaic generation sunlight following device
CN104410356A (en) * 2014-12-19 2015-03-11 叶晓佶 Solar tracking and concentrating power generation system
CN105071760A (en) * 2015-09-08 2015-11-18 国网山东夏津县供电公司 Solar energy dual-axis tracking system
CN106301185B (en) * 2016-10-18 2019-02-12 丁慈鑫 A kind of solar energy tracking device for photovoltaic power generation
CN108111109B (en) * 2017-12-30 2019-10-11 宁波森赛威尔新能源科技有限公司 A kind of driving mechanism for the solar energy equipment that can adjust irradiating angle
CN109951146A (en) * 2019-04-02 2019-06-28 广州礼意诚科技研究有限公司 A kind of energy conservation photovoltaic solar system
CN113014185B (en) * 2021-03-25 2022-04-26 湖南迪泰尔综合能源规划设计有限公司 But energy-concerving and environment-protective angle regulation's photovoltaic board

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CN1780136B (en) * 2005-10-12 2010-12-22 陈应天 Solar photoroltaic battery generator for realizing multiple-time light focusing in globe by light hopper reflecting method
ES1064549U (en) * 2006-10-09 2007-04-01 Juan Pablo Cabanillas Saldaña Solar fixer to two axes (Machine-translation by Google Translate, not legally binding)
CN201725081U (en) * 2010-03-11 2011-01-26 中国科学技术大学 Solar concentrator by reflection of flat plate-type flat glass mirrors
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CN203054600U (en) * 2012-12-03 2013-07-10 丁慈鑫 Biaxial sun-chasing tracking mechanism

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