01采用哪種安裝形式

不同的屋頂安裝光伏組件的方法也不一樣，常見(jiàn)的安裝方式包括附加型、壓載型及樁基型。

如果屋頂屬于彩鋼瓦型式，一般都考慮附加型，直接將組件平鋪在彩鋼瓦上，尤其是一般彩鋼瓦屋頂都沒(méi)有女兒墻，采用平鋪的型式防風(fēng)效果最好，最為安全；另外彩鋼瓦屋頂也有一定的傾角，雖然可能不是光伏發(fā)電對(duì)應(yīng)的最佳傾角，但加大傾角帶來(lái)的改造成本也是需要綜合考量的。

對(duì)于水泥屋頂，通常是純平，常見(jiàn)的安裝方式是壓載型和混凝土基礎(chǔ)樁基型，如圖所示。

很多時(shí)候，建筑物業(yè)主不允許在混凝土平屋頂上鉆孔，一方面是擔(dān)心老建筑的強(qiáng)度，或者是不想改變屋頂?shù)姆浪阅?。這就是選擇壓載型或混凝土基礎(chǔ)安裝的原因。

壓載型由于沒(méi)有和屋頂做錨固連接，因此側(cè)面可以考慮做防風(fēng)處理，尤其是沒(méi)有女兒墻的水泥屋頂。

混凝土基座的主要目的是確保即使在暴風(fēng)雨季節(jié)，支架系統(tǒng)也能保持完好無(wú)損。它保證了良好的安裝而不會(huì)導(dǎo)致屋頂漏水，還可以提高太陽(yáng)能電池組件的效率，減少女兒墻對(duì)陽(yáng)光的遮擋

02平屋頂不代表平鋪安裝

在平屋頂上采用平鋪方式安裝光伏組件，似乎是最想當(dāng)然的方式，不僅安裝量/面積可以最大化，還有可能將光伏作為屋頂頂棚使用，增加空間面積。

但事實(shí)上，在平屋頂上安裝光伏，并不意味著您還應(yīng)該將其傾斜度設(shè)置為0度，我們需要考慮很多因素，應(yīng)避免平裝，包括：

l 平鋪組件容易積灰，積灰可能造成10％甚至30%的發(fā)電量損失；

l 清洗更不方便，積水不易流出；

l 與傾斜安裝相比，發(fā)電量將減少；

l 投資回報(bào)期將更長(zhǎng)；

l 可能無(wú)法靠自然降雨來(lái)去除積灰；

傾斜安裝和純平鋪的光伏陣列發(fā)電量會(huì)有明顯的不同，通過(guò)對(duì)一個(gè)11.2kWp太陽(yáng)能系統(tǒng)進(jìn)行仿真模擬，傾角分別為10度、5度和0度。

仿真結(jié)果表明，如果傾角為0度，則11.2kWp系統(tǒng)年發(fā)電量約為13,480.3kWh，而在5度傾角下，該系統(tǒng)一年發(fā)電量達(dá)到14,066.9kWh。而事實(shí)上，當(dāng)傾角為10度時(shí)，該系統(tǒng)年發(fā)電量達(dá)到14,520kWh。

從結(jié)果中可以看出，每增加5度，系統(tǒng)每年增加500kWh的發(fā)電量（15度后，增加量會(huì)明顯減少，超過(guò)最佳傾角后反而會(huì)更低）。而且，上述仿真模擬還沒(méi)有考慮低傾角安裝時(shí)由于積灰而造成的發(fā)電量損失。

如果不愿意采用最佳傾角來(lái)安裝的話(huà)，安裝傾角盡可能還是高一些。如果必須平鋪，建議也將傾角設(shè)計(jì)在5-10度之間。對(duì)于平屋頂來(lái)說(shuō)，5-10度的角度也已經(jīng)足夠平了，而對(duì)于彩鋼瓦屋頂來(lái)說(shuō)，一般都會(huì)留有3度以上的角度，相比增加傾角的額外成本來(lái)說(shuō)，順其自然、隨坡就勢(shì)也是很好的選擇。

很多時(shí)候，建筑物業(yè)主不允許在混凝土平屋頂上鉆孔，一方面是擔(dān)心老建筑的強(qiáng)度，或者是不想改變屋頂?shù)姆浪阅?。這就是選擇壓載型或混凝土基礎(chǔ)安裝的原因。

壓載型由于沒(méi)有和屋頂做錨固連接，因此側(cè)面可以考慮做防風(fēng)處理，尤其是沒(méi)有女兒墻的水泥屋頂。

混凝土基座的主要目的是確保即使在暴風(fēng)雨季節(jié)，支架系統(tǒng)也能保持完好無(wú)損。它保證了良好的安裝而不會(huì)導(dǎo)致屋頂漏水，還可以提高太陽(yáng)能電池組件的效率，減少女兒墻對(duì)陽(yáng)光的遮擋

都會(huì)留有3度以上的角度，相比增加傾角的額外成本來(lái)說(shuō)，順其自然、隨坡就勢(shì)也是很好的選擇。

03平屋頂安裝必須考慮風(fēng)速

在太陽(yáng)能系統(tǒng)的設(shè)計(jì)階段，必須考慮當(dāng)?shù)乜赡艹霈F(xiàn)的最大風(fēng)速，尤其是在風(fēng)速超過(guò)每小時(shí)180公里的地區(qū)。

不是五年一遇，十年一遇，光伏系統(tǒng)的壽命是25年，必須考慮50年一遇！

2021年4月底發(fā)生在江蘇南通的臺(tái)風(fēng)足以說(shuō)明一切，隨著建筑質(zhì)量的提升，對(duì)于南通地區(qū)的建筑也來(lái)說(shuō)，幾乎沒(méi)有人會(huì)過(guò)多考慮到三十年前常發(fā)生的臺(tái)風(fēng)災(zāi)害，畢竟南通地區(qū)的臺(tái)風(fēng)，也就能對(duì)以前的平方、草屋、大棚帶來(lái)點(diǎn)影響。

但發(fā)生在南通的那場(chǎng)大風(fēng)，活生生地將屋頂?shù)奶?yáng)能光伏、太陽(yáng)能熱水器都吹到了地上，臺(tái)風(fēng)期間造成十多人死亡，50年一遇毫不夸張。

普通的平屋頂太陽(yáng)能發(fā)電系統(tǒng)可以承受160 km / h（十三級(jí)臺(tái)風(fēng)）的風(fēng)速，但如果沒(méi)有女兒墻擋風(fēng)，陣列間沒(méi)有考慮防風(fēng)，局部區(qū)域因氣流而造成的瞬間風(fēng)速會(huì)遠(yuǎn)遠(yuǎn)超過(guò)實(shí)際的風(fēng)速。

這時(shí)候?qū)τ谥Ъ艿倪x型、結(jié)構(gòu)設(shè)計(jì)、壓載或混凝土基礎(chǔ)強(qiáng)度設(shè)計(jì)必須依賴(lài)專(zhuān)業(yè)機(jī)構(gòu)的建議，即便是彩鋼瓦屋頂?shù)钠戒仯惨锌茖W(xué)的分析。

04平屋頂安裝的漏水風(fēng)險(xiǎn)

積水在平屋頂上很常見(jiàn)。由于屋頂是平坦的，所以水無(wú)處可去，或者說(shuō)排水變慢，在屋頂停留的時(shí)間會(huì)邊長(zhǎng)，因此，任何屋頂上的縫隙、孔洞都會(huì)變成積水的停留處。

此時(shí)，安裝了光伏系統(tǒng)的平屋頂，由于支架安裝和混凝土樁基安裝時(shí)可能造成的防水層破壞，就成為平屋頂光伏最大的漏水風(fēng)險(xiǎn)。

如果是彩鋼瓦屋頂，采用夾具安裝要比在彩鋼瓦上打孔要好；如果彩鋼瓦不適合用夾具連接，采用結(jié)構(gòu)膠粘結(jié)也是一種選擇。

05需要考慮平屋頂上的機(jī)械單元

在水泥平屋頂上設(shè)計(jì)和安裝光伏的挑戰(zhàn)之一是現(xiàn)有建筑樓頂?shù)母黝?lèi)機(jī)械裝置，如室外空調(diào)機(jī)組、排水管、排氣扇、通風(fēng)設(shè)施、水箱、欄桿、屋頂結(jié)構(gòu)、暖通系統(tǒng)和水管等等。

這些已有的設(shè)備，不僅影響了屋頂光伏的布局，影響了系支架間距和排列，還可能對(duì)光伏陣列產(chǎn)生陰影遮擋，或是影響到日后的運(yùn)維。

有的設(shè)計(jì)人員會(huì)考慮在這些設(shè)施上方加裝光伏，為設(shè)施遮風(fēng)擋雨，但由此帶來(lái)的另一個(gè)問(wèn)題是高度設(shè)計(jì)要求和防風(fēng)要求，以及運(yùn)維的困難。

對(duì)于屋頂設(shè)施，只能因地制宜地開(kāi)展設(shè)計(jì)，但這是屋頂光伏無(wú)法回避，必須重視的問(wèn)題。

06屋頂平鋪組件的增發(fā)

一般沒(méi)有絕對(duì)0度角的平鋪安裝，但低傾角確實(shí)是不能回避的問(wèn)題，即便是水泥屋頂也會(huì)有這樣的需求。

對(duì)于屋頂平鋪光伏，優(yōu)化設(shè)計(jì)后仍然可以獲得最佳發(fā)電能力，這可以通過(guò)不同的方式來(lái)完成。

Which installation method is used for 01
The method of installing photovoltaic modules on different roofs also varies, and common installation methods include additional, ballast, and pile foundation types.
If the roof belongs to the color steel tile type, the additional type is generally considered, and the components are directly laid on the color steel tile. In particular, the general color steel tile roof has no Parapet, and the flat type is the best and safest for wind protection; In addition, the color steel tile roof also has a certain inclination angle. Although it may not be the optimal inclination angle for photovoltaic power generation, the renovation cost brought about by increasing the inclination angle also needs to be comprehensively considered.
For cement roofs, they are usually flat, and the common installation methods are ballast type and concrete foundation pile foundation type, as shown in the figure.
In many cases, building owners are not allowed to drill holes on the concrete Flat roof. On the one hand, they are worried about the strength of the old building or do not want to change the waterproof performance of the roof. This is the reason for choosing ballast type or concrete foundation installation.
Since the ballast type is not anchored to the roof, wind proof treatment can be considered for the side, especially for the cement roof without Parapet.
The main purpose of the concrete foundation is to ensure that the support system remains intact even during stormy seasons. It ensures good installation without causing water leakage on the roof, improves the efficiency of solar cell modules, and reduces the Parapet's blocking of sunlight
02 Flat roof does not mean flat installation
It seems to be the most natural way to install photovoltaic modules on Flat roof in the way of tiling. Not only can the installation amount/area be maximized, but also it is possible to use photovoltaic as a roof ceiling to increase the space area.
However, the fact that photovoltaic is installed on a Flat roof does not mean that you should also set its inclination to 0 degrees. We need to consider many factors, including:
Tiled components are prone to dust accumulation, which may result in a 10% or even 30% loss of power generation;
Cleaning is more inconvenient, and accumulated water is not easy to flow out;
Compared to inclined installation, the power generation will be reduced;
The investment return period will be longer;
It may not be possible to rely on natural rainfall to remove accumulated ash;
There will be obvious differences between the power generation of tilted and flat Photovoltaic system. Through the simulation of an 11.2kWp solar system, the tilt angles are 10 degrees, 5 degrees and 0 degrees respectively.
The simulation results show that if the inclination angle is 0 degrees, the annual power generation of the 11.2kWp system is about 13480.3kWh, while at a 5 degree inclination angle, the annual power generation of the system reaches 14066.9kWh. In fact, when the inclination angle is 10 degrees, the annual power generation of the system reaches 14520kWh.
From the results, it can be seen that for every 5 degree increase, the system generates an annual increase of 500kWh of electricity (after 15 degrees, the increase will significantly decrease, but after exceeding the optimal inclination angle, it will actually be lower). Moreover, the above simulation has not yet taken into account the power generation loss caused by ash accumulation during low inclination installation.
If you are not willing to use the optimal inclination angle for installation, the installation inclination angle should be as high as possible. If it is necessary to lay flat, it is recommended to also design the inclination angle between 5 and 10 degrees. For Flat roof, 5-
03 Wind speed must be considered for installation of Flat roof
In the design phase of solar systems, it is necessary to consider the maximum wind speed that may occur locally, especially in areas with wind speeds exceeding 180 kilometers per hour.
Not once every five years, once every ten years. The lifespan of the photovoltaic system is 25 years, and a once every 50 years must be considered!
The typhoon that occurred in Nantong, Jiangsu at the end of April 2021 is a testament to everything. With the improvement of building quality, almost no one would think too much about the frequent typhoon disasters that occurred thirty years ago for buildings in the Nantong area. After all, typhoons in the Nantong area can also have some impact on the square, thatched houses, and greenhouses of the past.
But the strong wind that occurred in Nantong vividly blew the solar photovoltaic and solar water heaters on the roof to the ground, causing more than ten deaths during the typhoon, which is no exaggeration.
The ordinary Flat roof solar power generation system can withstand the wind speed of 160 km/h (Level 13 typhoon), but if there is no Parapet to wind, and wind protection is not considered between arrays, the instantaneous wind speed caused by airflow in local areas will far exceed the actual wind speed.
At this point, the selection of brackets, structural design, ballast or concrete foundation strength design must rely on the advice of professional institutions, even for the flat laying of colored steel tile roofs, there must be scientific analysis.
04 Water leakage risk of Flat roof installation
Ponding is common on Flat roof. Due to the flat roof, there is no place for water to go, or the drainage slows down, and the time spent on the roof will be longer. Therefore, any gaps or holes in the roof will become a place for stagnant water to stay.
At this time, for the Flat roof with photovoltaic system installed, the waterproof layer may be damaged during the installation of support and concrete pile foundation, which becomes the biggest risk of water leakage for Flat roof photovoltaic.
If it is a colored steel tile roof, using fixtures for installation is better than drilling holes on the colored steel tile; If colored steel tiles are not suitable for connecting with fixtures, using structural adhesive bonding is also an option.
05 Mechanical units on Flat roof need to be considered
One of the challenges of designing and installing photovoltaic on the cement Flat roof is the various mechanical devices on the roof of the existing building, such as outdoor air conditioning units, drainage pipes, Whole-house fan, ventilation facilities, water tanks, railings, roof structures, HVAC systems and water pipes.
These existing equipment not only affect the layout of roof photovoltaic, affect the spacing and arrangement of tie brackets, but also may have a shadow on the Photovoltaic system, or affect future operation and maintenance.
Some designers may consider installing photovoltaics above these facilities to provide shelter from wind and rain, but another issue that arises is the height design requirements and wind protection requirements, as well as the difficulty of operation and maintenance.
For rooftop facilities, design can only be carried out according to local conditions, but this is an issue that cannot be avoided by rooftop photovoltaics and must be taken seriously.
06 Additional issuance of roof tile components
Generally, there is no absolute 0 degree flat installation, but low inclination is indeed an unavoidable problem, even for cement roofs.
For rooftop tiled photovoltaics, optimized design can still achieve optimal power generation capacity, which can be achieved through different methods.