CN108073766A - A kind of preferred method of two-sided photovoltaic module setting height(from bottom) - Google Patents

Abstract

The invention discloses a kind of preferred method of two-sided photovoltaic module setting height(from bottom), comprise the following steps：(a) two-sided photovoltaic module backside irradiation gain η under different height is calculated；(b) the positive and negative irradiation of two-sided photovoltaic module is combined, determines two-sided photovoltaic module total amount of irradiation G_tot；(c) according to the total amount of irradiation G of two-sided photovoltaic module_tot, calculate the gross generation Q in photovoltaic system Life cycle under installed capacity；(d) determine to correspond to the stent cost needed for two-sided photovoltaic module installation under different height, out-degree electricity cost LCOE is obtained according to the ratio between all costs of investment in Life cycle and the gross generation Q being calculated, the setting height(from bottom) that most low electric cost corresponds to is optimal setting height(from bottom).The optimized design in photovoltaic system Life cycle under dynamic investment can be calculated by the present invention, it can be deduced that double-side assembly optimal setting height(from bottom) in the case of guarantee degree electricity is lower-cost, gives full play to two-sided photovoltaic module irradiation.

Description

A kind of preferred method of two-sided photovoltaic module setting height(from bottom)

Technical field

The invention belongs to technical field of solar, and in particular to a kind of preferred method of two-sided photovoltaic module setting height(from bottom).

Background technology

Two-sided photovoltaic module is received significant attention with the characteristic that its pair of glass structure and two sides can all generate electricity, and double-side assembly is It realizes volume production and is used in soundproof wall, the complementation of fishing light, agriculture light complementation distributed electricity generation system.In recent years, two-sided photovoltaic Component is concerned, and " Han Jinfeng, Zhao Weiwei, Guo Zhengyang etc. influence the factor of double glass generating electricity on two sides module backside power generations to document [J] science and technology and enterprise, 2015 (22) " obtain component East and West direction right angle setting by contrast experiment and are better than 30 ° of angles peaces of standard Dress；Setting angle from 0 to 90 ° in, two-sided photovoltaic module setting angle is bigger, bigger compared with general components advantage；Identical Irradiation level under, the reflecting background color at two-sided photovoltaic module back is more shallow, and background reflectivity is higher, two-sided photovoltaic module backside Generating efficiency is higher；Two-sided photovoltaic module minimum point is liftoff higher, the higher conclusion of two-sided photovoltaic module backside generating efficiency.

Document " Ufuk A.Yusufoglu, Tobias M.Pletzer, at all.Analysis of the Annual Performance of Bifacial Modules and Optimization Methods[J].IEEE JOURNAL OF PHOTOVOLTAICS, VOL.5, NO.1,2015. " research find that two-sided photovoltaic module compares the gain that single side photovoltaic module generates Depending on the spatial distribution of incident radiation on back surface member surface, it is subject to albedo, reflecting surface size, component height and inclination The strong influence of angle, meanwhile, pass through the annual energy of the two-sided photovoltaic module of two places experiment proof under opposite weather conditions Volume production magnitude is linearly increasing with the increase of reflectivity, and the size and component height of reflecting surface can reach saturation, finally exist Under these optimal conditions, compared with standard module, two-sided photovoltaic module can provide up 25% gain.

The installation settings of two-sided photovoltaic module has very big influence for the performance of two-sided photovoltaic module, therefore by double The optimal design of face photovoltaic module electricity generation system, can degree of being greatly reduced electricity cost, the popularization and application for two-sided photovoltaic module Play an important roll.

Two-sided photovoltaic module is different from common single side photovoltaic module, and setting height(from bottom) can generate double-side assembly back side irradiation Large effect although the irradiation that the photovoltaic module back side receives can be increased by improving setting height(from bottom), and then promotes double-side assembly Generate electricity flow gain, but considers from economy point, and improving the setting height(from bottom) of component can cause stent cost to increase, and make entire light The initial construction cost of volt system becomes larger, so as to influence the degree electricity cost of entire photovoltaic system.So double-side assembly is installed high The optimal selection of degree can give full play to double-side assembly advantage in the case where guarantee degree electricity cost is minimum.

The content of the invention

To solve the above-mentioned problems, the present invention provides a kind of preferred method of two-sided photovoltaic module setting height(from bottom), ensure In the case of degree electricity is lower-cost, two-sided photovoltaic module irradiation is given full play to.

The technical scheme is that：A kind of preferred method of two-sided photovoltaic module setting height(from bottom), comprises the following steps：

(a) two-sided photovoltaic module backside irradiation gain η under different height is calculated；

(b) the positive and negative irradiation of two-sided photovoltaic module is combined, determines two-sided photovoltaic module total amount of irradiation G_tot；

(c) according to the total amount of irradiation G of two-sided photovoltaic module_tot, calculate under installed capacity in photovoltaic system Life cycle Gross generation Q；

(d) determine to correspond to the stent cost needed for two-sided photovoltaic module installation under different height, according in Life cycle All costs of investment and the ratio between the gross generation Q that is calculated out-degree electricity cost LCOE, most low electric cost correspond to obtain Setting height(from bottom) be optimal setting height(from bottom).

Preferably, two-sided photovoltaic module backside irradiation gain η is counted according to formula (1) under different height in the step (a) It calculates：

η=﹣ 3.3494H⁵+11.161H⁴﹣ 13.346H³+6.4141H²﹣ 0.622H+0.0919 (1).

Preferably, two-sided photovoltaic module total amount of irradiation G in the step (b)_totIt is calculated according to formula (2)：

G_tot=G_front+G_rear=(1+ η) × G_front (2)

Wherein, G_frontFor two-sided photovoltaic module front irradiation, G_rearFor two-sided photovoltaic module backside irradiation.

Preferably, when calculating gross generation Q in the step (c), calculate in photovoltaic system and wrapped first, in accordance with formula (3) The two-sided number of photovoltaic modules k contained：

K=C/P (3)

Wherein, C is installed capacity, and P is single two-sided photovoltaic module power；

Gross generation Q is calculated according still further to formula (4)：

Wherein, h=G_tot/1000 (5)

H is peak value hourage；PR is photovoltaic system efficiency；α_{Light is abandoned to ration the power supply}Light is abandoned for locality to ration the power supply ratio；α_AttenuationFor two-sided photovoltaic The year attenuation rate of component；For discount rate.

Preferably, step (d) the moderate electricity cost LCOE is calculated according to formula (6)：

LCOE=(initial outlay expense+total land lease expense+total operation and maintenance expenses+overall loan refund+value-added tax paid in total+ The income tax ﹣ projects residual value for the surtax paid in total+pay in total)/Q (6)

Wherein, initial outlay expense includes stent cost C_StentWith other initial costs, stent cost C_StentIt is counted according to formula (7) It calculates：

Stent cost C_Stent=(120+H × 100) × k (7)

Wherein, H is double-side assembly height off the ground, and k is two-sided number of photovoltaic modules included in photovoltaic system；

Finally, the height off the ground H of corresponding minimum LCOE is optimal setting height(from bottom).

Compared with prior art, beneficial effects of the present invention are embodied in：

Optimized design in photovoltaic system Life cycle under dynamic investment can be calculated by the present invention, such as The optimal setting height(from bottom) of Changzhou Prefecture double-side assembly can be drawn as 0.65m, obtain most low electric cost, guarantee degree electricity cost at this time In the case of relatively low, two-sided photovoltaic module irradiation is given full play to, helps to assess the economy of photovoltaic plant.

Description of the drawings

Fig. 1 is the sectional view of two-sided photovoltaic module difference setting height(from bottom) in the present invention.

Fig. 2 irradiates gain for two-sided photovoltaic module backside under different setting height(from bottom)s in the present invention.

Fig. 3 is the degree electricity cost curve figure under different setting height(from bottom)s in entire 25 years life cycles in the present invention.

Fig. 4 is the influence situation of two-sided photovoltaic module LCOE in the present invention.

Specific embodiment

Embodiment 1

As shown in Figure 1, it is the sectional view of two-sided photovoltaic assembly array difference setting height(from bottom), when sun altitude and two-sided group When the setting angle of part is consistent, component is because the shadow surface l sizes that the sun projects ground are constant, i.e. l₁=l₂.From two-dimensional section figure From the point of view of, it is assumed that the shadow surface surface of projection occurred is reflected into diffusing reflection, according to RADIATION ANGLE COEFFICIENT principle, l₁What is emitted is anti- Penetrating can be by a, b₁, c₁Face is absorbed, and the radiation that wherein face a is received accounts for l₁The ratio for emitting global radiation is a/ (a+b₁+c₁), i.e., it is two-sided Photovoltaic module backside area a is a/ (a+b compared with the ascent of shadow surface l₁+c₁).With height h₁Increase, b₂>b₁、c₂> c₁, a remains unchanged, and face a is less and less compared with the ascent of shadow surface l, and two-sided photovoltaic module is by the reflection spoke of shadow loss Penetrate the radiation increase also just smaller, the back side integrally receives.

Two-sided solar double-glass assemblies are chosen, Trina Solar field experiment measures double under unobstructed situation, different setting height(from bottom)s in Changzhou The face photovoltaic module back side irradiates gain, sees Fig. 2.After component setting height(from bottom) reaches 0.5m, irradiation gain tends towards stability, this experiment Earth's surface is white paint face, helps to increase Reflectivity for Growing Season, promotes two-sided gain, and mounted angle is 27 °.

The preferred method of two-sided photovoltaic module setting height(from bottom), step are as follows：

(a) two-sided photovoltaic module backside irradiation gain η under different height is calculated, is calculated according to formula (1)：

η=﹣ 3.3494H⁵+11.161H⁴﹣ 13.346H³+6.4141H²﹣ 0.622H+0.0919 (1).

(b) the positive and negative irradiation of two-sided photovoltaic module is combined, determines two-sided photovoltaic module total amount of irradiation G_tot, according to formula (2) calculate：

G_tot=G_front+G_rear=(1+ η) × G_front (2)

Wherein, G_frontFor two-sided photovoltaic module front irradiation, G_rearFor two-sided photovoltaic module backside irradiation.

(c) according to the total amount of irradiation G of two-sided photovoltaic module_tot, calculate under installed capacity in photovoltaic system Life cycle Gross generation Q calculates two-sided number of photovoltaic modules k included in photovoltaic system first, in accordance with formula (3)：

K=C/P (3)

Wherein, C is installed capacity, and P is single two-sided photovoltaic module power；

Gross generation Q is calculated according still further to formula (4)：

Wherein, h=G_tot/1000 (5)

H is peak value hourage；PR is photovoltaic system efficiency；α_{Light is abandoned to ration the power supply}Light is abandoned for locality to ration the power supply ratio；α_AttenuationFor two-sided photovoltaic The year attenuation rate of component；For discount rate；

Such as the commercial distribution 6MW power stations of design, obtain 27 ° of Changzhou Prefecture using meteorological data software meteonorm7.1 Inclination angle amount of radiation next year is 1343kWh/m², the radiation degree 1000W/m with standard testing solar cell²The ratio between be peak It is worth hourage；

(d) determine to correspond to the stent cost needed for two-sided photovoltaic module installation under different height, according in Life cycle All costs of investment and the ratio between the gross generation Q that is calculated out-degree electricity cost LCOE, most low electric cost correspond to obtain Setting height(from bottom) be optimal setting height(from bottom), degree electricity cost LCOE according to formula (6) calculating：

LCOE=(initial outlay expense+total land lease expense+total operation and maintenance expenses+overall loan refund+value-added tax paid in total+ The income tax ﹣ projects residual value for the surtax paid in total+pay in total)/Q (6)

Wherein, initial outlay expense includes stent cost C_StentWith other initial costs, stent cost C_StentIt is counted according to formula (7) It calculates：

Stent cost C_Stent=(120+H × 100) × k (7)

Wherein, H is double-side assembly height off the ground, and k is two-sided number of photovoltaic modules included in photovoltaic system；

Other initial costs for removing stent cost C stents include component, inverter, header box, case change, switchyard, line The configurations such as cable expense and installation fee are calculated according to 5.2 yuan/W.Total land lease expense C_SoilIt is calculated according to formula (8)

Wherein, p is soil unit price, is 3 yuan/m²/ year；Increase interest rate for land lease year；S is land area, takes Changzhou Front and rear row inter-module is corresponded under regional 27 ° of inclination angles away from for 2.8m, application experience formula, land area S is：

S=2.8 × k × 1.2 (9)

Wherein, k is two-sided number of photovoltaic modules in photovoltaic system.

It is 3,230,000 yuan that total land lease expense after discount, which is calculated,.

Project residual value is calculated according to depreciation-straight line method, final residual value C_{Residual value}For：

Depreciation period, is limited to 20 years, and system salvage value rate is 5%；

Total O＆M expense calculates for annual 0.083 yuan/W, and after discount, 25 years O＆M total costs are 5,780,000 yuan.

According to the rules, surtax is calculated with 12%, and enterprise income tax is calculated with 25%, and value-added tax is calculated according to 17%, false If loan is limited to 10 years in year, lending ratio 70%, loan interest rate 4.9%.

Final calculation result such as table 1, entire 25 years Life Cycles under the corresponding different setting height(from bottom)s of 11 yuan/cm of stent cost of table Degree electricity cost in phase.

Table 1

Fig. 3 is obtained by the drafting of table 1, Fig. 3 is the degree electricity cost curve in entire 25 years life cycles under different setting height(from bottom)s Scheme (considering initial construction cost, land lease expense, operation and maintenance expenses, loan, tax revenue etc.), from the figure 3, it may be seen that calculating according to the present invention Go out, two-sided photovoltaic module may be such that the electric cost of degree is minimum in whole life cycle at height 0.65m, and benefit relatively passes System single side common component height off the ground is higher by 10cm, and LCOE is substantially steady after setting height(from bottom) 0.65m, so, for using double It is optimal that the electricity generation system of face photovoltaic module will reach design, need to suitably increase double-side assembly setting height(from bottom), and integrated economics consider, It is optimal for 0.65m.

Consider that stent cost fluctuation to the influence situation of two-sided photovoltaic module LCOE, is shown in Fig. 4, when stent cost by 0.6 yuan/ When cm increases to 1.6 yuan/cm, two-sided photovoltaic module setting height(from bottom) is reduced to 0.63m by 0.68m, and integral installation height is influenced Less, substantially near 0.65m, it is possible to double-side assembly setting height(from bottom) is suitably adjusted according to stent price, ± 5cm with It is interior.

Finally, the height off the ground H of corresponding minimum LCOE is optimal setting height(from bottom), and photovoltaic system design at this time is in complete raw Order the optimal design under dynamic investment in the cycle.

Claims (5)

1. a kind of preferred method of two-sided photovoltaic module setting height(from bottom), which is characterized in that comprise the following steps：

(a) two-sided photovoltaic module backside irradiation gain η under different height is calculated；

(b) the positive and negative irradiation of two-sided photovoltaic module is combined, determines two-sided photovoltaic module total amount of irradiation G_tot；

(c) according to the total amount of irradiation G of two-sided photovoltaic module_tot, calculate total hair in photovoltaic system Life cycle under installed capacity Electricity Q；

(d) determine to correspond to the stent cost needed for two-sided photovoltaic module installation under different height, according to the institute in Life cycle Have the ratio between cost of investment and gross generation Q for being calculated out-degree electricity cost LCOE, the peace that most low electric cost corresponds to Dress height is optimal setting height(from bottom).

2. the preferred method of two-sided photovoltaic module setting height(from bottom) as described in claim 1, which is characterized in that the step (a) Two-sided photovoltaic module backside irradiation gain η is calculated according to formula (1) under middle different height：

η=﹣ 3.3494H⁵+11.161H⁴﹣ 13.346H³+6.4141H²﹣ 0.622H+0.0919 (1).

3. the preferred method of two-sided photovoltaic module setting height(from bottom) as claimed in claim 2, which is characterized in that the step (b) In two-sided photovoltaic module total amount of irradiation G_totIt is calculated according to formula (2)：

G_tot=G_front+G_rear=(1+ η) × G_front (2)

Wherein, G_frontFor two-sided photovoltaic module front irradiation, G_rearFor two-sided photovoltaic module backside irradiation.

4. the preferred method of two-sided photovoltaic module setting height(from bottom) as claimed in claim 3, which is characterized in that the step (c) During middle calculating gross generation Q, two-sided number of photovoltaic modules k included in photovoltaic system is calculated first, in accordance with formula (3)：

K=C/P (3)

Wherein, C is installed capacity, and P is single two-sided photovoltaic module power；

Gross generation Q is calculated according still further to formula (4)：

Wherein, h=G_tot/1000 (5)

H is peak value hourage；PR is photovoltaic system efficiency；α_{Light is abandoned to ration the power supply}Light is abandoned for locality to ration the power supply ratio；α_AttenuationFor two-sided photovoltaic module Year attenuation rate；For discount rate.

5. the preferred method of two-sided photovoltaic module setting height(from bottom) as claimed in claim 4, which is characterized in that the step (d) Moderate electricity cost LCOE is calculated according to formula (6)：

LCOE=(initial outlay expense+total land lease expense+total operation and maintenance expenses+overall loan refund+value-added tax paid in total+in total The income tax ﹣ projects residual value for the surtax paid+pay in total)/Q (6)

Wherein, initial outlay expense includes stent cost C_StentWith other initial costs, stent cost C_StentIt is calculated according to formula (7)：

Stent cost C_Stent=(120+H × 100) × k (7)

Wherein, H is double-side assembly height off the ground, and k is two-sided number of photovoltaic modules included in photovoltaic system；

Finally, the height off the ground H of corresponding minimum LCOE is optimal setting height(from bottom).