CN206114933U - Photovoltaic module beam condensing unit, photovoltaic array and photovoltaic system - Google Patents
Photovoltaic module beam condensing unit, photovoltaic array and photovoltaic system Download PDFInfo
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- CN206114933U CN206114933U CN201620735021.2U CN201620735021U CN206114933U CN 206114933 U CN206114933 U CN 206114933U CN 201620735021 U CN201620735021 U CN 201620735021U CN 206114933 U CN206114933 U CN 206114933U
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- photovoltaic module
- photovoltaic
- speculum
- beam condensing
- condensing unit
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Abstract
The utility model relates to a photovoltaic power generation technical field discloses a photovoltaic module beam condensing unit, photovoltaic array and photovoltaic system, and wherein, the photovoltaic module beam condensing unit is including setting up at least one speculum between adjacent two lines photovoltaic module, at least one speculum be used for with light reflection to the sensitive surface moves towards on the photovoltaic module of delegation of its setting among two lines of adjacent photovoltaic module. Above -mentioned photovoltaic module beam condensing unit can be with the light reflection between two lines of adjacent photovoltaic module on to photovoltaic module to can improve photovoltaic module's income light quantity greatly, and then improve photovoltaic module's generated energy, so this photovoltaic module beam condensing unit can effectively improve photovoltaic array's generated energy, and then reduce the photovoltaic power generation cost.
Description
Technical field
The utility model is related to technical field of photovoltaic power generation, more particularly to a kind of photovoltaic module beam condensing unit, photovoltaic array
And photovoltaic system.
Background technology
At present, the power station in large-scale ground photovoltaic plant more than 90% is, using the connection in series-parallel of crystalline silicon photovoltaic module, to add
The parts such as support, header box, inverter, monitoring system, by the connection of various cables, finally to photovoltaic electrical network output power.
Although this photovoltaic plant has reduced as much as possible overall cost, its photovoltaic generation cost and conventional thermoelectricity cost phase
Than price is still higher by least one times;Trace it to its cause, it is relatively costly shared by photovoltaic module mainly due in photovoltaic plant, so
And, because the irradiation level during the overwhelming majority is regional a year is averagely less than 600 watts/square metre, it is only about standard test condition
The 60% of 1000 watts/square metre, thus the photovoltaic module overwhelming majority time be at being run under low irradiance, i.e. photovoltaic module
Most times to enter light quantity all less, and enter that light quantity is less to mean photovoltaic module in the case where generating area is constant
Generated energy it is relatively low, the generated energy of photovoltaic module is low to cause the photovoltaic generation cost of final photovoltaic plant relative to improve.Cause
This, in solar photovoltaic assembly running, increase photovoltaic module to enter light quantity is to improve its generated energy and then reduce photovoltaic generation
One of effective way of cost.
Utility model content
The utility model provides a kind of photovoltaic module beam condensing unit, photovoltaic array and photovoltaic system, existing to solve
The generated energy of photovoltaic module is less in the photovoltaic array of technology and then causes the of a relatively high problem of photovoltaic generation cost.
To reach above-mentioned purpose, the utility model provides technical scheme below:
A kind of photovoltaic module beam condensing unit, including at least one speculum being arranged between adjacent rows photovoltaic module,
At least one speculum be used for by light be reflected towards sensitive surface in the adjacent rows photovoltaic module towards its arrange one
On row photovoltaic module.
Light between two adjacent row photovoltaic modulies can be reflected towards photovoltaic module by above-mentioned photovoltaic module beam condensing unit
On, it is thus possible to greatly improve the light quantity that enters of photovoltaic module, and then the generated energy of photovoltaic module is improved, so, the photovoltaic module
Beam condensing unit can effectively improve the generated energy of photovoltaic array, and then reduce photovoltaic generation cost.
Preferably, the photovoltaic module beam condensing unit includes a speculum;The reflecting surface of the speculum and institute
The sensitive surface of a line photovoltaic module is stated in certain inclination angle, so that the light being irradiated on the reflecting surface is towards a line photovoltaic
The sensitive surface reflection of component.
Preferably, when the reflecting surface of the speculum is arranged perpendicular to horizontal plane, the inclination angle reaches minimum of a value;Work as institute
When the reflecting surface for stating speculum mutually splices respectively with two photovoltaic modulies being adjacent, the inclination angle reaches maximum.
Preferably, the speculum is level crossing or curved mirror.
Preferably, the speculum includes the reflecting layer with reflecting surface, the supporting layer for supporting reflecting layer, Yi Jiwei
Adhesive linkage between the reflecting layer and the supporting layer.
Preferably, at least one is provided with the reflecting surface of the speculum parallel to the reflecting surface and parallel to institute
State the miniature triangular prism structure that the sensitive surface of photovoltaic module is arranged.
Preferably, the speculum is disposed with multiple miniature triangular prism structures along the direction on its top to bottom,
And along the direction on the top of the speculum to bottom, the top angle of the miniature triangular prism increases successively.
Preferably, each described miniature triangular prism structure is translucent construction;Or, each described miniature triangular prism knot
Structure is impermeable photo structure.
Preferably, the photovoltaic module beam condensing unit also includes the carrier unit for fixedly mounting the speculum.
Preferably, the carrier unit includes being fixedly supported to the column on ground, and is installed on the column and edge
The crossbeam that the column direction of the photovoltaic array extends;The bottom of the speculum is installed on the crossbeam, the speculum
Top is installed on the column.
Preferably, the carrier unit is telescopic structure;The speculum is can stretching with the carrier unit
Contracting is moved and flexible telescopic structure;Or, the speculum with the stretching motion of the carrier unit can to slide
Sliding block type structure;Or, the speculum is the accordion structure that can fold with the stretching motion of the carrier unit.
A kind of photovoltaic array, including multirow photovoltaic module, also including the photovoltaic module described in any of the above-described technical scheme
Beam condensing unit.
Preferably, in the photovoltaic module beam condensing unit, the top of at least one speculum and the light being adjacent
The top of volt component contacts.
A kind of photovoltaic system, including the photovoltaic array described in above-mentioned two technical scheme.
The photovoltaic power generation technology scheme that the utility model is provided, by arranging light between per two adjacent row photovoltaic modulies
Volt component beam condensing unit, so as to the light between efficiently utilizing per two adjacent row photovoltaic modulies, considerably increases photovoltaic
Component enters light quantity, and then improves the generated energy of photovoltaic array, the cost so as to reduce photovoltaic generation;Also, due to this
The structure of the photovoltaic module beam condensing unit that utility model is provided, processing and mounting process are all fairly simple, and the photovoltaic module is poly-
Setting up for electro-optical device need not be improved to original photovoltaic module, this also reduce to a certain extent photovoltaic generation into
This.Therefore, the photovoltaic power generation technology scheme that the utility model is provided, can only increase the cost less than photovoltaic module 10%
In the case of, realization makes photovoltaic module enter light quantity and improves 1.5~2 times, so as to effectively reduce the cost of photovoltaic generation.
Description of the drawings
A kind of structural representation of photovoltaic array that Fig. 1 is provided for the utility model embodiment;
Photovoltaic module, the photovoltaic arranged on column direction in a kind of photovoltaic array that Fig. 2 is provided for the utility model embodiment
The tangent plane structural representation of component beam condensing unit and carrier unit;
In a kind of photovoltaic array that Fig. 3 is provided for another embodiment of the utility model on column direction arrange photovoltaic module,
The tangent plane structural representation of photovoltaic module beam condensing unit and carrier unit;
A kind of tangent plane structural representation of the speculum of photovoltaic module beam condensing unit that Fig. 4 is provided for the utility model embodiment
Figure;
A kind of tangent plane structure of the speculum of photovoltaic module beam condensing unit that Fig. 5 is provided for another embodiment of the utility model
Schematic diagram.
Specific embodiment
Below in conjunction with the accompanying drawing in the utility model embodiment, the technical scheme in the utility model embodiment is carried out
Clearly and completely describe, it is clear that described embodiment is only a part of embodiment of the utility model, rather than whole
Embodiment.Based on the embodiment in the utility model, those of ordinary skill in the art are not under the premise of creative work is made
The every other embodiment for being obtained, belongs to the scope of the utility model protection.
Refer to Fig. 1~Fig. 5.
As shown in Fig. 1~Fig. 5, a kind of photovoltaic module beam condensing unit that the utility model embodiment is provided, including being arranged at
At least one speculum 3 between adjacent rows photovoltaic module 1, at least one speculum 3 is adjacent for light to be reflected towards
A line light that sensitive surface 11 (i.e. photovoltaic module 1 is used to receive a side surface of light) is arranged towards it in two row photovoltaic modulies 1
On volt component 1.
As shown in figure 1, x directions and y directions are both direction orthogonal on horizontal plane, wherein, x directions are array arrangement
The line direction of photovoltaic module 1, y directions are the column direction of the photovoltaic module 1 of array arrangement;Z directions are and x directions and y directions institute
The vertical direction of plane;Above-mentioned photovoltaic module beam condensing unit 2 can be anti-by the light between two adjacent row photovoltaic modulies 1
On directive photovoltaic module 1, it is thus possible to greatly improve the light quantity that enters of photovoltaic module 1, and then the generated energy of photovoltaic module 1 is improved,
So, the photovoltaic module beam condensing unit 2 can effectively improve the generated energy of photovoltaic array, and then reduce photovoltaic generation cost.
As shown in Fig. 1~Fig. 5, in a kind of specific embodiment, the photovoltaic module optically focused that the utility model embodiment is provided
Device 2 includes a speculum 3;Reflecting surface 31 (i.e. speculum 3 is used for a side surface of the reflection light) direction of the speculum 3
It is adjacent and sensitive surface 11 is arranged towards its a line photovoltaic module 1 being obliquely installed, also, the reflecting surface 31 of the speculum 3
With the sensitive surface 11 of the row photovoltaic module 1 arrange in certain inclination alpha, so that the light being irradiated on the reflecting surface 31 can be with
Reflect towards the sensitive surface 11 of the row photovoltaic module 1.
As shown in Fig. 1~Fig. 5, on the basis of above-described embodiment, in a kind of specific embodiment, each photovoltaic module
In beam condensing unit 2, the top of the top of speculum 3 and sensitive surface 31 dorsad its a line photovoltaic module 1 for arranging contacts, specifically
Ground, the top of the speculum 3 mutually splices to form triangle roof shape structure with the top of the row photovoltaic module 1;Now, reflect
Mirror 3 will not be produced to the light of photovoltaic module 1 to direct projection and blocked.
As shown in Figures 2 and 3, in a kind of preferred embodiment, when the reflecting surface 31 of speculum 3 is arranged perpendicular to horizontal plane
When the value of inclination alpha that formed be its minimum of a value;When a line photovoltaic group that the bottom of speculum 3 is arranged with sensitive surface 31 towards it
The bottom of part 1 also contacts, and (i.e. the reflecting surface 31 of speculum 3 is mutually spelled with the sensitive surface 31 of two photovoltaic modulies 1 being adjacent
Connect) when, the value of the inclination alpha for being formed is its maximum.
As shown in Fig. 1~Fig. 5, in a kind of preferred embodiment, what the bottom of speculum 3 and sensitive surface 31 were arranged towards it
Also mutually splice the bottom of a line photovoltaic module 1;Now, the speculum 3 and the two row photovoltaic modulies 1 that are adjacent all splice and set
Put, then each speculum 3 all covers the region between the two row photovoltaic modulies 1 adjacent with the speculum 3, so as to be somebody's turn to do
Light between two row photovoltaic modulies 1 can all be received and then more light can be reflected towards into photovoltaic group by speculum 3
On part 1;Therefore, between the above-mentioned concrete setting to speculum 3 can be maximally utilised per two adjacent row photovoltaic modulies 1
Light, and then improve photovoltaic module 1 and enter light quantity.
As shown in Figures 2 and 3, on the basis of above-described embodiment, in a kind of specific embodiment, light of the present utility model
Volt component beam condensing unit 2 can also include the carrier unit 4 for fixedly mounting above-mentioned speculum 3, and the carrier unit 4 can pacify
Loaded on photovoltaic bracket 5, it is also possible to be directly fixed on ground;Preferably, photovoltaic module beam condensing unit 2 of the present utility model
In, carrier unit 4 can adopt the carrier unit 4 of controllability, be coordinated by the carrier unit 4 and speculum 3 of controllability
Can realize that the reflecting surface 31 to speculum 3 is adjusted relative to the inclination angle that the sensitive surface 11 of photovoltaic module 1 is in.
As shown in Figures 2 and 3, in a kind of specific embodiment, carrier unit 4 can include being fixedly supported to the vertical of ground
Post 41, and the crossbeam 42 for being installed on column 41 and extending along the column direction of photovoltaic array 1;It is installed on carrier unit 4
Speculum 3, its bottom is installed on crossbeam 42, and its top is installed on column 41;Preferably, between column 41 and crossbeam 42
Support bar 43 can also be connected with, so as to form stable triangular structure in carrier unit 4.Certainly, in order to ensure support list
The reliability of unit 4, carrier unit 4 can include many columns 41 and crossbeam 42, and many columns 41 and crossbeam 42 are along photovoltaic battle array
The line direction spread configuration of row.
Preferably, crossbeam 42 can be telescopic structure;Speculum 3 can for telescopic structure, sliding block type structure or
Person's accordion structure, when crossbeam 42 extends along direction stretching motion, one end is installed on the speculum 3 of crossbeam 42 can be with
Crossbeam 42 flexible and stretch, slide or fold, so as to (reflecting surface 31 of speculum 3 is relative to light at the inclination angle of speculum 3
The inclination angle that is in of sensitive surface 11 of volt component 1) (side that speculum 3 is installed on column 41 is to being installed on crossbeam 42 with length
On the distance between side) can change with the regulation of the length of crossbeam 42, you can with realize the inclination angle to speculum 3 with
Length is adjusted, and then, it is possible to achieve the light reflection direction of speculum 3 is adjusted.
As shown in Figures 2 and 3, on the basis of the various embodiments described above, in a kind of specific embodiment, the utility model reality
In applying the photovoltaic module beam condensing unit 2 of example offer, speculum 3 can include the reflecting layer with reflecting surface 31, anti-for supporting
Penetrate the supporting layer of layer, and the adhesive linkage three-decker between reflecting layer and supporting layer;Reflecting layer, adhesive linkage and supporting layer
The side of structure can be viscous by aluminum alloy frame and silica gel, stainless steel frame and silica gel or hot-galvanized steel frame and silica gel etc.
Knot material is fixed assembling;Preferably, the reflecting surface 31 in reflecting layer can coat self-cleaning coating, for reducing outdoor ash
The destruction of dirt and watermark to the reflecting properties of reflecting surface 31;Adhesive linkage can be using adhesives such as silica gel, and adhesive linkage one side can
Together with reflecting layer to be adhesively fixed with supporting layer, on the other hand can also provide for the deformation between reflecting layer and supporting layer
Buffering, especially in high wind load region;Supporting layer can adopt aluminium alloy, hot-dip galvanized alloy, stainless steel, magnadure or height
Intensity antiultraviolet plastic or other material, for improving the strength and stability in reflecting layer, to ensure that mirror surface structure is long-term out of doors
Under aging and wind load, the repeated action of snow load, there is no big irrecoverability deformation;Also, speculum 3 can pass through
The supporting layer is installed on carrier unit 4.
As shown in Fig. 2 on the basis of the various embodiments described above, in a kind of specific embodiment, the utility model embodiment
Speculum 3 in the photovoltaic module beam condensing unit 2 of offer can be level crossing.Level crossing has simple structure, processing installation side
Just advantage;When the speculum 3 in photovoltaic module beam condensing unit 2 is level crossing, need to consider its reflecting surface 31 relative to light
The inclination angle that the sensitive surface 11 of volt component 1 is in, so that the light being irradiated on its reflecting surface 31 can receiving towards photovoltaic module 1
Reflect on light face 11.
As shown in figure 3, in another kind of specific embodiment, the speculum 3 in photovoltaic module beam condensing unit 2 can also be recessed
Face mirror.The spotlight effect of concave mirror preferably, most of light of directive its reflecting surface 31 can be reflected towards on photovoltaic module 1;
When the speculum 3 in photovoltaic module beam condensing unit 2 is concave mirror, the slope for calculating concave mirror face 31 is needed, so that according to
Being mapped to the light on its reflecting surface 31 can reflect more towards on the sensitive surface 11 of photovoltaic module 1, for example, parabolic
The slope of concave mirror can be calculated by parabolic formula.
On the basis of the various embodiments described above, in a kind of specific embodiment, the photovoltaic that the utility model embodiment is provided
In component beam condensing unit 2, microreflection module can be provided with the reflecting surface 31 of speculum 3, using the anti-of microreflection module
Penetrate and/or refraction action can change the transmission direction of light, so that the light for exposing to thereon can reflect and/or refract to
On the sensitive surface 11 of photovoltaic module 1, so as to improve speculum 3 to the effect of optically focused on the sensitive surface 11 of photovoltaic module 1.Such as Fig. 4
With shown in Fig. 5, in a kind of preferred embodiment, the microreflection module can be miniature triangular prism structure 5, the miniature triangular prism
Reflecting surface 31 of the structure 5 parallel to the speculum 3 and sensitive surface 11 parallel to photovoltaic module 1 is arranged, as shown in Figure 4 and Figure 5,
Receiving for photovoltaic module 1 can be oriented to by light to the reflection of light and/or refraction action using the side of the miniature triangular prism structure 5
Light face 11, so as to improve photovoltaic module 1 light quantity is entered.Preferably, reflect through miniature triangular prism structure 5 to ensure and/or
Light after refraction can directive photovoltaic module 1, on each speculum 3, at the differing heights position of reflecting surface 31
Triangular prism structure 5, its shape can be differed;Specifically, along the direction on the top of speculum 3 to bottom, multiple miniature three
The top angle theta of prism 5 increases successively, i.e. the higher miniature triangular prism structure 5 in position, and its side 51 is relative to speculum
The inclination angle of 3 reflectings surface 31 is less.Also, the miniature triangular prism structure 5 can be lighttight structure, specifically can adopt stainless
The materials such as steel, aluminium plated film prepare to be formed, as shown in figure 4, when miniature triangular prism structure 5 is lighttight structure, it is possible to use
Light is oriented to the sensitive surface 11 of photovoltaic module 1 to the reflex of light on its surface;The miniature triangular prism structure 5 can also be
The structure of printing opacity, specifically can prepare to be formed using high transparent glass material, as shown in figure 5, when miniature triangular prism structure 5 is
During the structure of light, it is possible to use light is oriented to the sensitive surface 1 of photovoltaic module 1 for the effect of its reflection and refraction to light.
As shown in FIG. 1 to 3, the utility model embodiment additionally provides a kind of photovoltaic array, and the photovoltaic array includes battle array
The photovoltaic module 1 of row arrangement, the photovoltaic module beam condensing unit 2 for also providing including any of the above-described embodiment.
As shown in figure 1, in a kind of specific embodiment, the sensitive surface 11 of each photovoltaic module 1 and the row of photovoltaic array
Direction (such as the y directions in Fig. 1) is arranged in certain inclination angle, and the inclination angle is typically based on the geographical position at photovoltaic plant place and height above sea level
Arrange etc. feature, so that sensitive surface 11 as far as possible towards illumination direction and to receive light as much as possible be preferred;
Along the column direction (such as the y directions in Fig. 1) of the photovoltaic array, it is provided between every two adjacent row photovoltaic modulies 1
One photovoltaic module beam condensing unit 2, the light that the photovoltaic module beam condensing unit 2 can be emitted onto thereon is reflected towards what is be adjacent
In two row photovoltaic modulies, on a line photovoltaic module 1 for arranging towards it of sensitive surface.
In above-mentioned photovoltaic array, along the column direction (such as the y directions in Fig. 1) of photovoltaic array, two adjacent row photovoltaic groups
Light between part 1 can be reflected towards on photovoltaic module 1 by photovoltaic module beam condensing unit 2, i.e., the photovoltaic array can be effectively sharp
With the light between two adjacent row photovoltaic modulies 1, it is thus possible to greatly improve the light quantity that enters of photovoltaic module 1, and then light is improved
The generated energy of volt component 1, so, the photovoltaic array can effectively improve the generated energy of photovoltaic system, and then reduce photovoltaic generation
Cost.
Specifically, in the photovoltaic array that the utility model is provided, the photovoltaic cell in photovoltaic module 1 can be silicon heterogenous
Battery, or common polycrystalline silion cell, can also be back-contact monocrystalline silicon battery.
The utility model embodiment additionally provides a kind of photovoltaic system, and the photovoltaic system is included in any of the above-described embodiment
Photovoltaic array.Due in the photovoltaic array of the photovoltaic system, photovoltaic module enters that light quantity is larger, generated energy is higher, so as to the light
The generated energy of volt system is larger, advantage of lower cost.
The photovoltaic power generation technology scheme that the utility model is provided, by arranging light between per two adjacent row photovoltaic modulies
Volt component beam condensing unit, so as to the light between efficiently utilizing per two adjacent row photovoltaic modulies, considerably increases photovoltaic
Component enters light quantity, and then improves the generated energy of photovoltaic array, the cost so as to reduce photovoltaic generation;Also, due to this
The structure of the photovoltaic module beam condensing unit that utility model is provided, processing and mounting process are all fairly simple, and the photovoltaic module is poly-
Setting up for electro-optical device need not be improved to original photovoltaic module, this also reduce to a certain extent photovoltaic generation into
This.Therefore, the photovoltaic power generation technology scheme that the utility model is provided, can only increase the cost less than photovoltaic module 10%
In the case of, realization makes photovoltaic module enter light quantity and improves 1.5~2 times, so as to effectively reduce the cost of photovoltaic generation.
Obviously, those skilled in the art the utility model embodiment can be carried out it is various change and modification without deviating from
Spirit and scope of the present utility model.So, if these modifications of the present utility model and modification belong to the utility model right
Within the scope of requirement and its equivalent technologies, then the utility model is also intended to comprising these changes and modification.
Claims (14)
1. a kind of photovoltaic module beam condensing unit, it is characterised in that including at least be arranged between adjacent rows photovoltaic module
Individual speculum, at least one speculum is used to for light to be reflected towards in the adjacent rows photovoltaic module sensitive surface towards it
On a line photovoltaic module of setting.
2. photovoltaic module beam condensing unit according to claim 1, it is characterised in that the reflecting surface of the speculum with it is described
The sensitive surface of a line photovoltaic module is in certain inclination angle, so that the light being irradiated on the reflecting surface is towards a line photovoltaic group
The sensitive surface reflection of part.
3. photovoltaic module beam condensing unit according to claim 2, it is characterised in that when the reflecting surface of the speculum it is vertical
When horizontal plane is arranged, the inclination angle reaches minimum of a value;When the speculum reflecting surface respectively and two light being adjacent
When volt component mutually splices, the inclination angle reaches maximum.
4. photovoltaic module beam condensing unit according to claim 2, it is characterised in that the speculum is level crossing or song
Face mirror.
5. photovoltaic module beam condensing unit according to claim 4, it is characterised in that the speculum is included with reflecting surface
Reflecting layer, the supporting layer for supporting reflecting layer and the adhesive linkage between the reflecting layer and the supporting layer.
6. photovoltaic module beam condensing unit according to claim 4, it is characterised in that arrange on the reflecting surface of the speculum
There is at least one miniature triangular prism structure.
7. photovoltaic module beam condensing unit according to claim 6, it is characterised in that the speculum is along its top to bottom
Direction on be disposed with multiple miniature triangular prism structures, it is described and along the direction on the top of the speculum to bottom
The top angle of miniature triangular prism increases successively.
8. photovoltaic module beam condensing unit according to claim 6, it is characterised in that each described miniature triangular prism structure
For translucent construction;Or, each described miniature triangular prism structure is impermeable photo structure.
9. the photovoltaic module beam condensing unit according to any one of claim 1~8, it is characterised in that also include for fixing
The carrier unit of the speculum is installed.
10. photovoltaic module beam condensing unit according to claim 9, it is characterised in that the carrier unit includes fixed
Support the column in ground, and be installed on the column and along the crossbeam that extends of bearing of trend of each column photovoltaic module;
The bottom of the speculum is installed on the crossbeam, and the top of the speculum is installed on the column.
11. photovoltaic module beam condensing units according to claim 10, it is characterised in that the carrier unit is extension type
Structure;
The speculum be can with the stretching motion of the carrier unit flexible telescopic structure;Or,
The speculum is the sliding block type structure that can slide with the stretching motion of the carrier unit;Or,
The speculum is the accordion structure that can fold with the stretching motion of the carrier unit.
12. a kind of photovoltaic arrays, it is characterised in that including multirow photovoltaic module, are also included such as any one of claim 1~11 institute
The photovoltaic module beam condensing unit stated.
13. photovoltaic arrays according to claim 12, it is characterised in that in the photovoltaic module beam condensing unit, it is described extremely
The top of a few speculum and the top of the photovoltaic module being adjacent contact.
14. a kind of photovoltaic systems, it is characterised in that include the photovoltaic array as described in claim 12 or 13.
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CN107528538A (en) * | 2017-10-09 | 2017-12-29 | 青海天创新能源科技有限公司 | A kind of photovoltaic power station component mounting system for increasing wind loading rating and generated energy |
CN109245708A (en) * | 2018-09-27 | 2019-01-18 | 南昌大学 | A kind of simple reflective enhancing device of fixed Flat type photovoltaic assembly array electricity generation system |
CN109818566A (en) * | 2017-11-22 | 2019-05-28 | 大唐新能源沭阳有限公司 | A kind of device for converting solar energy |
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Cited By (4)
Publication number | Priority date | Publication date | Assignee | Title |
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CN107528538A (en) * | 2017-10-09 | 2017-12-29 | 青海天创新能源科技有限公司 | A kind of photovoltaic power station component mounting system for increasing wind loading rating and generated energy |
CN109818566A (en) * | 2017-11-22 | 2019-05-28 | 大唐新能源沭阳有限公司 | A kind of device for converting solar energy |
CN109245708A (en) * | 2018-09-27 | 2019-01-18 | 南昌大学 | A kind of simple reflective enhancing device of fixed Flat type photovoltaic assembly array electricity generation system |
IL271679A (en) * | 2019-12-24 | 2021-06-30 | Yagel Yosef | Solar harvesting field and device for same |
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