RU2803315C1 - Method of compiling solar module from photovoltaic converters - Google Patents

Abstract

FIELD: solar energy.

SUBSTANCE: combining a solar module from photovoltaic converters, including: selection of photovoltaic converters with efficiency with deviation from the average not exceeding 1% and power at the point of maximum power with deviation from the average not exceeding 2%; construction of the reverse branch of the current-voltage characteristics with the illuminated surface of the photoelectric converter; selection of photoelectric converters, the threshold breakdown voltage of the reverse branch of the current-voltage characteristics of which is below the upper threshold, determined by the maximum threshold power; compilation of a solar module from selected in this way, series-connected photovoltaic converters.

EFFECT: improved reliability of the solar module.

1 cl, 2 dwg

Description

The invention relates to photoenergy, namely to solar modules that are used at photovoltaic stations and are composed of photovoltaic converters (PVCs) based on photovoltaic p-n junctions made of silicon semiconductors.

Existing methods for composing solar modules from series-connected photovoltaic converters include selecting photovoltaic converters of the same class. Industrially produced solar cells have some variation in parameters, which is determined not only by the quality of the semiconductor materials being tried on, but also by the technology of production and assembly of solar modules. The characteristics and parameters of solar modules and elements provided by manufacturers are averaged and do not fully reflect the operating efficiency of a solar module or element under various unfavorable external conditions, for example, such as uneven illumination of the module surface due to partial shading. Experimental reading of current-voltage characteristics (CVC) as an input control of supplied solar converters allows us to obtain the energy parameters of solar cells under various operating modes. The operating efficiency of such converters depends on many factors, among which external factors such as irradiance and temperature have a significant influence, as well as on the operating parameters of the solar cells themselves. PV manufacturers provide in their passport the parameters and characteristics under standard test conditions (STC): irradiance 1000 W/ ^m2 , spectrum AM1.5, PV temperature 25°C. In laboratory conditions, the measurement of the current-voltage characteristics under standard test conditions is performed with short-term illumination of the light-receiving surface of the photovoltaic cell with a source of artificial light with an AM1.5 spectrum. Depending on the angle of incidence of the sun's rays on the receiving platform located on the surface of the earth, the sun's rays overcome different thicknesses of the air mass of the atmosphere. Therefore, the radiation spectrum arriving at the receiving site will differ due to the different degree of absorption of certain wavelengths by the atmosphere, associated with the thickness of the atmospheric air layer. The following notations are accepted: the AM0 spectrum determines the operation of solar modules on satellites and spacecraft, the AM1 spectrum corresponds to the distribution of solar radiation intensity on the Earth's surface when the Sun is at its zenith, the AM2 spectrum shows the spectral distribution of solar radiation on the Earth's surface, at the angle between the Sun and the zenith 60°, the AM1.5 spectrum corresponds to the average intensity of radiation transmitted through the air mass equal to 1.5, which corresponds to the position of the Sun at an angle of 45° to the horizon.

After the FEP is manufactured, automatic sorting and breakdown into classes is performed depending on the efficiency and quality of production. Such a selection of PV cells of the same type is required when assembling solar modules so that the parameters of the PV cells included in the modules are as close as possible to each other. Traditional operational parameters for selecting PV cells during classification are: efficiency (efficiency), power at the maximum power point, temperature coefficient, fill factor, open circuit voltage, short circuit current, current and voltage at the maximum power point (MPP), which are determined in a straight line branches of the current-voltage characteristic of the solar cell. TMM is the point on the current-voltage characteristic at which the power produced by the solar cell is maximum at a certain level of illumination. It is for this point that the rated power and efficiency of the solar cell are determined under standard test conditions. Changing the illumination level leads to a shift in the TMM, so various algorithms for tracking the maximum power point are used in order to obtain the maximum possible power at the PV output under any conditions. The power of a solar module directly depends on the quality and parameters of each solar cell of which it consists. The output power of the module is always less than the arithmetic sum of the powers of the solar cells that make up the module itself. This is explained by losses due to mismatch of characteristics of PV cells of the same type. Existing technologies require selection criteria for efficiency classes with a deviation from the average of no more than 1%, a deviation in power at the point of maximum power of no more than 2%, a deviation from the average of other parameters does not exceed 0.5%. In the manufacture of solar modules, a set of PV cells of the same type is used to ensure the smallest spread of the above parameters and reduce mismatch losses, since the efficiency of a series connection of PV cells is determined by the efficiency of PV cells with the lowest parameters.

Thus, there is a known method (according to patent JP2016192827, selected as a prototype) for constructing a solar module from photoelectric converters, which includes constructing a direct branch of the current-voltage characteristic of a solar cell to determine the open circuit voltage, short circuit current, and fill factor.

When PV cells are connected in series under conditions of non-uniform illumination of their surface, some of the least illuminated PV cells stop working as energy sources and become “parasitic” loads. The bulk of the PV cells continue to generate energy and pass current through the less illuminated PV cells, causing high energy losses in the form of heat dissipation, which can lead to the formation of local hot spots and thermal damage to the PV cells. To avoid this problem, bypass diodes are connected in parallel to each PV cell or PV group, which shunt the current in the series circuit, excluding shaded PV groups from operation. But even this method is not enough at high reverse threshold breakdown voltages of solar cells.

The task of selecting PV cells for composing a solar module with a reduced probability of damage to photovoltaic converters that have switched to parasitic load mode, for example, due to non-uniform illumination of the surface, mechanical damage, when they are connected in series as part of solar modules, remains relevant. The technical result of the proposed invention is to increase the reliability of the solar module. In addition, an increase in the efficiency of a solar module composed of series-connected solar cells is achieved.

The technical result is achieved in a method for composing a solar module from photovoltaic converters, including: selecting photovoltaic converters having an efficiency with a deviation from the average of no more than 1% and power, at the point of maximum power, with a deviation from the average of no more than 2%; construction of the inverse branch of the current-voltage characteristics with the illuminated surface of the photoelectric converter; selection of photoelectric converters whose threshold breakdown voltage of the reverse branch of the current-voltage characteristics is below the upper threshold determined by the maximum threshold power; compiling a solar module from photovoltaic converters selected in a specified manner, connected in series.

The invention is illustrated by drawings:

fig. 1 - shift of the operating point of the shaded solar cell;

fig. 2 - dependence of the thermal power released by the solar cell on the applied reverse voltage.

The method for composing a solar module from a solar cell at the first stage includes selecting photovoltaic converters that have an efficiency with a deviation from the average of no more than 1% and a power at the maximum power point (MPP) with a deviation from the average of no more than 2%. Thus, a small spread of these parameters is ensured, which reduces mismatch losses, since the efficiency of a series connection of PV cells is determined by the efficiency (efficiency) of PV cells with the lowest parameters. When PV cells are connected in series under conditions of non-uniform illumination of their surface, some of the least illuminated PV cells stop working as energy sources and become “parasitic” loads. The bulk of the PV cells continue to generate energy and pass current through the less illuminated PV cells, causing high energy losses in the form of heat dissipation, which can lead to the formation of local hot spots and thermal damage to the PV cells.

Next, the reverse branch of the current-voltage characteristics is constructed with the illuminated surface of the photoelectric converter. To do this, under standard test conditions (STC) (energy illumination 1000 W/m ² , AM1.5 spectrum, PV temperature 25°C), the current-voltage characteristics are measured when the light-receiving surface of the PV is briefly illuminated by an artificial light source with an AM1.5 spectrum.

Then, PV cells are selected whose threshold breakdown voltage of the reverse branch of the current-voltage characteristics is lower than the upper threshold determined by the maximum threshold power. This threshold determines the value of the threshold breakdown voltage obtained from the reverse branch of the current-voltage characteristic. Depending on the manufacturing technology and doping level of silicon photovoltaic converters, the threshold breakdown voltage usually does not exceed -25V, the characteristic value is about -15V. When the threshold breakdown voltage is halved, the loss of released power in the form of heat in the case of operation of photovoltaic converters as part of a power plant at reduced illumination is also halved, which significantly reduces the risk of the formation of local overheating points (“hot spot” effect) and subsequent damage to photovoltaic converters when operating in high-voltage systems up to 1000 V.

Thermal breakdown of the p-n junction of a solar cell, or in particular the formation of local overheating points, occurs due to the heterogeneity of the structure of the p-n junction and the presence of local defects in the crystal lattice. This type of breakdown is caused by the heating of the back-on PV when current flows through it. This situation can arise when PV cells are connected in series, when their surface is illuminated unevenly due to varying degrees of light concentration or the presence of shadows (Fig. 1). In this case, part of the solar cell will operate in diode mode with forward bias (photogeneration mode), and part with reverse bias (consumption mode).

The power released by the solar cell is determined by the relation: P _out = I _lines ⋅ U _out .

The power removed from the PV, dissipated in the form of heat into the environment, is determined by the temperature of the external environment and the thermal conductivity of the media through which the heat is removed. If the amount of heat generated by the PV exceeds the amount of heat removed from the PV, then the temperature of the PV begins to increase, which can lead to thermal breakdown of the PV.

For this reason, it is necessary to select PV cells with such values of the threshold breakdown voltage at which the maximum allocated threshold power P _max should not lead to the emergence of local overheating points, with a temperature leading to thermal destruction of the pn junction of the silicon PV cell, which is seen in the volt-watt characteristic (Fig. 2) corresponds to the linear section up to the inflection point at U _pr .

From the PV cells selected in this way, solar modules are made by connecting the PV cells in series using conductive busbars and placing them in a glazed frame made of aluminum profile, followed by laminating the PV cells and sealing the solar module.

Solar modules composed in this way can be used as energy sources for a solar photovoltaic power plant. The efficiency (efficiency) and reliability of operation of such a power plant increases by reducing the frequency of replacement of failing solar modules due to the formation of local hot spots.

Claims (1)

A method for composing a solar module from photovoltaic converters, including: selecting photovoltaic converters having an efficiency with a deviation from the average of no more than 1% and power at the point of maximum power, with a deviation from the average of no more than 2%; construction of the inverse branch of the current-voltage characteristics with the illuminated surface of the photoelectric converter; selection of photoelectric converters whose threshold breakdown voltage of the reverse branch of the current-voltage characteristics is below the upper threshold determined by the maximum threshold power; composing a solar module from series-connected selected photovoltaic converters.