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光伏系統(tǒng)接地裝置的作用、規(guī)格及檢測方法

返回列表 來源: 陽光工匠 發(fā)布日期: 2022.06.30 瀏覽次數(shù):
安裝光伏系統(tǒng)后,有時候會出現(xiàn)一些奇怪的問題,如經(jīng)常報對地漏電流和絕緣電阻故障,但在檢測時卻又沒有任何故障;有時候報電網(wǎng)電壓故障,電壓顯示不準;陰雨天逆變器工作時,家用電器會帶電;雷雨天逆變器工作時,逆變器有時候會被雷擊壞。出現(xiàn)這些問題,一般是光伏接地裝置可能出現(xiàn)問題。

01、光伏系統(tǒng)接地的作用


在光伏系統(tǒng)安裝中, 組件需要接地,逆變器也需要接地,組件和逆變器的接地都有什么用途呢?

光伏系統(tǒng)接地裝置分為工作接地和安全接地。組件接地主要作用是防雷擊接地。防雷接地將雷電導入大地,防止雷電流使人身受到電擊或財產(chǎn)受到破壞。 光伏發(fā)電系統(tǒng)的主要部分都安裝在露天狀態(tài)下,且分布的面積較大,因此存在著受直接和間接雷擊的危害。同時,光伏發(fā)電系統(tǒng)與相關(guān)電氣設(shè)備及建筑物有著直接的連接,光伏組件如果受到雷擊,還會涉及相關(guān)的設(shè)備和建筑物內(nèi)的用電負載。為了避免雷擊對光伏發(fā)電系統(tǒng)的損害,就需要設(shè)置防雷接地系統(tǒng)進行防護。

逆變器接地包括防雷接地和工作接地,安全接地和組件的功能一樣,工作接地有3種:

1、逆變器參考電位

大地常被作為電氣系統(tǒng)中的參考地來使用。電網(wǎng)側(cè)的電壓也是把大地當作零電位。以大地為零電位,逆變器的交流電壓和直流電壓可以檢測得更準確,更穩(wěn)定,檢測組件對地的漏電流也需要把地作為一個參考點。

2、防電磁干擾的屏蔽接地

逆變器是把直流電轉(zhuǎn)為交流電的設(shè)備,里面有電力電子變換,頻率一般為5-30KHz,因此會產(chǎn)生交變電場,所以也會產(chǎn)生電磁輻射。外界的電磁干擾也會對逆變器運行造成影響,將電氣干擾源引入大地,抑制外來電磁干擾對逆變器的影響,也可減少逆變器產(chǎn)生的干擾影響其它電子設(shè)備。

3、防組件出現(xiàn)PID

PID(PotentialInducedDegradation)效應全稱為電勢誘導衰減。PID直接危害就是大量電荷聚集在電池片表面,使電池表面鈍化,PID效應的危害使得電池組件的功率急劇衰減。減少太陽能電站的輸出功率,減少發(fā)電量,減少太陽能發(fā)電站的電站收益。接地系統(tǒng)可以延緩組件的衰減過程。

02、光伏系統(tǒng)接地規(guī)格

光伏系統(tǒng)要求有一個良好的接地系統(tǒng),做好接地系統(tǒng)既是設(shè)備穩(wěn)定、可靠工作的需要,也是保障設(shè)備和人身安全的需要。光伏接地系統(tǒng)包括防雷地、安全地、工作地,三種接地線在某一公共點接在一起后再通過等電位連接帶接到接地體。一個良好的接地系統(tǒng)除了必須有良好的接地體以外,接地線的長度和用材規(guī)格是極其重要的方面。

長度要求:為防止雷電流或故障電流所產(chǎn)生的高電位對設(shè)備的損害,要求接地線長度盡可能短,還要盡可能避免彎曲、繞圈。一般情況下,接地支線的長度應該小于15米。

用材規(guī)格: 光伏標準對接地線有明確的規(guī)定,接地線和交流相線或者直流線面積有關(guān),當相線截面積小于2.5平方;當相線截面積小于16平方時,地線的截面積最小為35平方,地線截面積為相線截面積的一半。

接地類型和要求包括以下幾個方面。一是防雷接地:包括避雷針(帶)、引下線、接地體等,要求接地電阻小于10歐姆,并最好考慮單獨設(shè)置接地體;二是安全保護接地、工作接地、屏蔽接地等,要求接地電阻小于等于4歐姆。當安全保護接地、工作接地、屏蔽接地和防雷接地4種接地共用一組接地裝置時,其接地電阻按其中最小值4歐姆確定;若防雷已單獨設(shè)置接地裝置時,其余3種接地宜共用一組接地裝置,其接地電阻不應大于其中最小值。

03、光伏系統(tǒng)接地的測量方法

接地系統(tǒng)做好之后,正確測量接地阻,則是很關(guān)鍵,但接地電阻和我們常見的電阻元器件有點不一樣,用普通的萬用表測不準,必須要用專用的儀器。測量方法通常有以下幾種:兩線法、三線法、四線法、單鉗法和雙鉗法。各有各的特點,實際測量時,盡量選擇正確的方式,才能使測量結(jié)果準確無誤。

(1)電壓法

兩線法、三線法、四線法都是電壓法,具體的原理如下圖所示,給地電極C和電極E施加一個交流電流I,再測量E點和P點的電勢差V,地電阻R等于V/I。
 
 
注意事項:必須有兩個接地棒:一個輔助地和一個探測電極。各個接地電極間的距離不小于20米,接地極要打到地深1.5米處左右,排成一行,土壤要潮濕,如果是干燥的土地,或者石質(zhì)、沙地要加足夠水才能測試。

四線法基本上同三線法,在低接地電阻測量和消除測量電纜電阻對測量結(jié)果的影響時替代三線法,四個小尺寸的電極以相同的深度和相等的距離(直線)被插入地里,并進行測量。該方法是所有接地電阻測量方法中準確度最高的。

 
(2)電流法

單鉗法和雙鉗法都是電流法,它能夠在不斷開地面系統(tǒng)的情況下測量電阻。不需要斷開引下錢,不需要輔助電極,快速、簡便、可靠,并且還包括測量中的接地和整體接地連接電阻。

鉗形接地電阻測試儀測量接地電阻的基本原理是測量回路電阻。鉗表的鉗口部分由電壓線圈及電流線圈組成。電壓線圈提供激勵信號,并在被測回路上感應一個電勢E。在電勢E的作用下將在被測回路產(chǎn)生電流I。鉗表對E及I進行測量,即可得到被測電阻R=E/I。

(3)單鉗法

測量多點接地中的每個接地點的接地電阻,而且不能斷開接地連接防止發(fā)生危險。適用于多點接地,不能斷開連接,測量每個接地點的電阻。方法是用電流鉗監(jiān)測被測接地點上的電流。

(4)雙鉗法

多點接地,不打輔助地樁,測量單個接地。方法是使用電流鉗接到相應的插口上,將兩鉗卡在接地導體上,兩鉗間的距離要大于0.25米。

光伏系統(tǒng)接地注意事項

從原理上看,安全接地和工作接地盡量不要接在一起,因為安全接地不經(jīng)常工作,但工作時電流很大,電壓比較高;而工作接地電流則是設(shè)備工作時就運行,和逆變器PCB弱電部分相連接,電流很小,電壓也很低。如果接在一起,就有可能產(chǎn)生干擾。

組件的接地,如果條件允許,可以單獨引一根地線,如果條件不允許,也可以和建筑物內(nèi)防雷帶接在一起。逆變器一般有兩個接地點,機殼接地點和輸出接線端子接地點,機殼接地點一般是安全接地,可以和組件系統(tǒng)的接地點接在一起,但不要和組件直接接在一起,最好直接和和埋在地下的接地帶連接,如果條件不允許,也可以和建筑物內(nèi)防雷帶接在一起。輸出接線端子接地點,是工作接地,要和輸出電源端的地線接在一起。

After the installation of the photovoltaic system, sometimes some strange problems will occur, such as frequently reporting the ground leakage current and insulation resistance fault, but there is no fault during the detection; Sometimes the power grid voltage fault is reported, and the voltage display is inaccurate; When the inverter works in cloudy and rainy days, household appliances will be charged; When the inverter works in thunderstorm days, sometimes the inverter will be damaged by lightning. In case of these problems, the photovoltaic grounding device may have problems.




01. Role of photovoltaic system grounding



In the installation of photovoltaic system, the module needs to be grounded, and the inverter also needs to be grounded. What is the purpose of the grounding of the module and the inverter?



The grounding device of photovoltaic system is divided into working grounding and safety grounding. The main function of component grounding is lightning protection grounding. Lightning protection grounding leads lightning to the earth to prevent lightning current from causing electric shock to people or damage to property. The main parts of the photovoltaic power generation system are installed in the open air, and the distribution area is large, so there are direct and indirect lightning hazards. At the same time, the photovoltaic power generation system is directly connected with the relevant electrical equipment and buildings. If the photovoltaic module is struck by lightning, it will also involve the electrical loads in the relevant equipment and buildings. In order to avoid the damage of lightning to photovoltaic power generation system, it is necessary to set lightning protection grounding system for protection.



Inverter grounding includes lightning protection grounding and working grounding. The functions of safety grounding and components are the same. There are three types of working grounding:



1. Inverter reference potential



The earth is often used as a reference ground in electrical systems. The voltage on the grid side also regards the earth as zero potential. With the ground as the zero potential, the AC voltage and DC voltage of the inverter can be detected more accurately and stably. The ground should also be used as a reference point for detecting the leakage current of the components to the ground.



2. Shielding grounding against electromagnetic interference



Inverter is a device that converts direct current into alternating current. It has power electronic conversion. The frequency is generally 5-30khz. Therefore, it will generate alternating electric field, so it will also generate electromagnetic radiation. External electromagnetic interference will also affect the operation of the inverter. The electrical interference source will be introduced to the earth to suppress the impact of external electromagnetic interference on the inverter, and also reduce the impact of interference generated by the inverter on other electronic equipment.



3. Anti component PID



PID (potentialinduceddegradation) effect is called potential induced attenuation. The direct harm of PID is that a large number of charges gather on the surface of the battery, making the battery surface passivated. The harm of PID effect makes the power of the battery module decay sharply. Reduce the output power of the solar power station, reduce the power generation, and reduce the power station income of the solar power station. The grounding system can delay the attenuation process of components.



02. Grounding specification of photovoltaic system



Photovoltaic system requires a good grounding system, which is not only the need for stable and reliable operation of equipment, but also the need to ensure equipment and personal safety. The photovoltaic grounding system includes lightning protection ground, safety ground and working ground. The three grounding wires are connected together at a common point and then connected to the grounding body through equipotential bonding belt. In addition to having a good grounding body, the length and material specification of the grounding wire are extremely important for a good grounding system.



Length requirements: in order to prevent damage to equipment caused by high potential generated by lightning current or fault current, the length of grounding wire shall be as short as possible, and bending and winding shall be avoided as much as possible. Generally, the length of grounding branch line shall be less than 15m.



Material specification: the photovoltaic standard has clear provisions for grounding wire. The grounding wire is related to the area of AC phase line or DC line. When the sectional area of phase line is less than 2.5 square meters; When the cross-sectional area of phase line is less than 16 square meters, the minimum cross-sectional area of ground wire is 35 square meters, and the cross-sectional area of ground wire is half of the cross-sectional area of phase line.



Grounding types and requirements include the following aspects. First, lightning protection and grounding: including lightning rod (strip), down lead, grounding body, etc., the grounding resistance is required to be less than 10 ohms, and it is best to consider setting the grounding body separately; Second, safety protection grounding, working grounding, shielding grounding, etc. the grounding resistance is required to be less than or equal to 4 ohms. When safety protection grounding, working grounding, shielding grounding and lightning protection grounding share a set of grounding devices, the grounding resistance shall be determined according to the minimum value of 4 ohms; If the lightning protection has been provided with a separate grounding device, the other three grounding devices should share a set of grounding devices, and the grounding resistance should not be greater than the minimum value.



03. Measurement method for grounding of photovoltaic system



After the grounding system is completed, it is very important to correctly measure the grounding resistance. However, the grounding resistance is a little different from our common resistance components. It can not be measured with an ordinary multimeter, so special instruments must be used. There are usually the following measurement methods: two-wire method, three wire method, four wire method, single clamp method and double clamp method. Each has its own characteristics. In the actual measurement, try to select the correct way to make the measurement results accurate.



(1) Voltage method



The two-wire method, three wire method and four wire method are all voltage methods. The specific principle is shown in the figure below. Apply an AC current I to the ground electrode C and electrode e, and then measure the potential difference V between point E and point P. the ground resistance R is equal to v/i.





Note: there must be two grounding rods: an auxiliary ground and a detection electrode. The distance between each grounding electrode shall not be less than 20 meters. The grounding electrode shall be laid to about 1.5 meters deep in a row. The soil shall be wet. If it is dry land, or stone or sand, it shall be tested with enough water.



The four wire method is basically the same as the three wire method. It replaces the three wire method when measuring the low ground resistance and eliminating the influence of the measured cable resistance on the measurement results. Four electrodes of small size are inserted into the ground at the same depth and the same distance (straight line) and measured. This method has the highest accuracy among all the grounding resistance measurement methods.




(2) Current method



Both the single clamp method and the double clamp method are current methods, which can measure the resistance without disconnecting the ground system. It is fast, simple and reliable without disconnecting the lead wire and auxiliary electrode, and also includes the grounding and overall grounding connection resistance in measurement.



The basic principle of the clamp type grounding resistance tester is to measure the loop resistance. The jaw part of the clamp meter is composed of a voltage coil and a current coil. The voltage coil provides an excitation signal and induces an electric potential E on the measured circuit. Under the action of potential E, current I will be generated in the measured circuit. Clamp the meter to measure E and I, and then the measured resistance r=e/i can be obtained.



(3) Single clamp method



Measure the grounding resistance of each grounding point in the multi-point grounding, and do not disconnect the grounding connection to prevent danger. It is applicable to multi-point grounding without disconnecting the connection. Measure the resistance of each grounding point. The method is to use current clamp to monitor the current on the measured grounding point.



(4) Double clamp method



Multi point grounding, no auxiliary ground pile, single grounding measurement. The method is to connect the current clamp to the corresponding socket, clamp the two clamps on the grounding conductor, and the distance between the two clamps should be greater than 0.25m.



Precautions for grounding of photovoltaic system



In principle, the safety grounding and working grounding should not be connected together as much as possible, because the safety grounding does not work often, but the current is large and the voltage is relatively high; The working grounding current is that the equipment operates when it is working and is connected with the weak current part of the inverter PCB. The current is very small and the voltage is also very low. If connected together, interference may occur.



For the grounding of components, if conditions permit, a ground wire can be led separately. If conditions do not permit, it can also be connected with the lightning protection belt in the building. The inverter generally has two grounding points, the chassis grounding point and the output terminal grounding point. The chassis grounding point is generally a safety grounding, which can be connected with the component system grounding point, but not directly with the component. It is better to be directly connected with the buried grounding strip. If conditions do not permit, it can also be connected with the lightning protection strip in the building. The output terminal grounding point is the working grounding, which shall be connected with the ground wire at the output power terminal.

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