to a
PV system Photovoltaic modules consist of a large number of solar cells and use light energy from the Sun to generate electricity through the
photovoltaic effect. Most modules use
wafer-based
crystalline silicon cells or
thin-film cells. The structural (
load carrying) member of a module can be either the top layer or the back layer. Cells must be protected from mechanical damage and moisture. The cells and modules are usually connected electrically in
series, one to another to increase the desired voltage output, and then in parallel to increase current output to create the solar panel. Most panels are rigid, but semi-flexible ones based on thin-film cells are also available. The
power (in
watts) of the solar panel is the
voltage (in
volts) multiplied by the
current (in
amperes), and depends both on the amount of light and on the
electrical load connected to the panel. The manufacturing specifications on solar panels are obtained under standard conditions, which are usually not the true operating conditions the solar panels are exposed to on the installation site. A PV
junction box is attached to the back of the solar panel and functions as its output interface. External connections for most photovoltaic modules use
MC4 connectors to facilitate easy weatherproof connections to the rest of the system. A
USB power interface can also be used. Solar panels also use metal frames consisting of racking components, brackets, reflector shapes, and troughs to better support the panel structure.
Cell connection techniques Solar cells need to be connected together by electrodes to form a module, with front electrodes blocking the solar cell front optical surface area slightly. To improve solar cell efficiency manufacturers maximize frontal surface area available for sunlight and improve sunlight absorption using chronologically adopted, varying rear electrode solar cell connection techniques: • Aluminum back surface field (Al-BSF), a vintage technology, uses full aluminum rear contact face • Passivated emitter rear contact (PERC) uses a reduced aluminum rear contact face and adds a polymer film where aluminum was removed to capture light • Interdigitated back contact (IBC) places contacts fully on the back allowing full frontal light exposure to capture even more light • Extended back contact (XBC) uses a combination of the above technologies Tandem solar cells use one of the above connection techniques and a combination of cell chemistries to form a solar cell.
Arrays of solar panels A single solar panel can produce only a limited amount of power; most installations contain multiple panels adding their voltages or currents. A photovoltaic system typically includes an array of photovoltaic modules, an
inverter, a
battery pack for energy storage, a charge controller, interconnection wiring, circuit breakers, fuses, disconnect switches, voltage meters, and optionally a
solar tracking mechanism. Equipment is carefully selected to optimize energy output and storage, reduce power transmission losses, and many times convert from direct current to
alternating current.
Smart solar panels Smart solar panels have power electronics embedded in the panel and are different from traditional solar panels with power electronics attached to the frame or connected to the photovoltaic circuit through a connector. Solar power electronics can be used for: •
Maximum power point tracking power optimizers, a technology developed to maximize the power harvest from solar photovoltaic systems by compensating for shading effects, wherein a shadow falling on a section of a module causes the electrical output of one or more strings of cells in the module to fall to near zero, but not having the output of the entire module fall to zero. •
Solar performance monitors for data collection • Fault detection for enhanced safety
Technology Most solar modules are currently produced from crystalline silicon (c-Si)
solar cells made of
polycrystalline or
monocrystalline silicon. In 2021, crystalline silicon accounted for 95% of worldwide PV production, while the rest of the overall market is made up of thin-film technologies using
cadmium telluride (CdTe),
copper indium gallium selenide and
amorphous silicon .
Bifacial cells produce energy on both sides which increases the total output of the module, this boost depends on the
reflectivity of the surroundings and benefits from raised constructions since more light can reach the rear side. The gain is situational, the rear side benefits more from high-albedo surroundings such as snow, raised constructions and overcast weather but the gains might be minimal when the panels are installed directly on a surface with little clearance making it not cost-effective in those cases. The price of bifacial cells has dropped enough to be close to monofacial technologies, because of this as of 2024, bifacial panels are the leading choice for utility-scale PV installations. Emerging,
third-generation solar technologies use advanced thin-film cells. They produce a relatively high-efficiency conversion for a lower cost compared with other solar technologies. Also, high-cost, high-efficiency, and close-packed rectangular
multi-junction solar cells are usually used in
solar panels on spacecraft, as they offer the highest ratio of generated power per kilogram lifted into space. Multi-junction cells are
compound semiconductors and made of
gallium arsenide and other semiconductor materials. Another emerging PV technology using multi-junction cells is
concentrator photovoltaics.
Thin film Concentrator Some special solar PV modules include
concentrators in which light is focused by
lenses or mirrors onto smaller cells. This enables the cost-effective use of highly efficient, but expensive cells (such as
gallium arsenide) with the trade-off of using a higher solar exposure area. Concentrating the sunlight can also raise the efficiency to around 45%.
Light capture The amount of light absorbed by a solar cell depends on the sunlight
angle of incidence and intensity. Light absorption varies because the amount falling on the panel is proportional to the
cosine of the angle of incidence, and partly because at high angle of incidence more light is reflected. Modules usually are faced south (in the Northern Hemisphere) or north (in the Southern Hemisphere) with a particular tilt calculated according to the latitude, to maximize total energy output over a day.
Solar tracking can be used to adjust the tilt angle from dawn to dusk, to keep the angle of incidence small. Vertical orientation of bi-facial panels are oriented north south and capture the most light from the east in the morning and west in the afternoon. Photovoltaic manufacturers have been working to decrease reflectance with improved anti-reflective coatings or with textures.
Anti-reflective coatings use one or more thin layers of substances with refractive indices intermediate between that of silicon and that of air, causing
destructive interference of the reflected light.
Power curve In individual solar panels, if not enough current is taken, then power isn't maximised. If too much current is taken then the voltage collapses. The optimum current draw is roughly proportional to the amount of sunlight striking the panel. Solar panel capacity is specified by the MPP (maximum power point) value of solar panels in full sunlight.
Inverters Solar inverters convert the direct current power provided by panels to alternating current power. MPP (Maximum power point) of the solar panel consists of MPP voltage (V) and MPP current (I). Performing maximum power point tracking, a solar inverter samples the output (I-V curve) from the solar cell and applies the proper electrical load to obtain maximum power. An alternating current solar panel has a small direct current to alternating current
microinverter on the back and produces alternating current power with no external direct current connector. Alternating current modules are defined by
Underwriters Laboratories as the smallest and most complete system for harvesting solar energy. Micro-inverters work independently to enable each panel to contribute its maximum possible output for a given amount of sunlight, but can be more expensive.
Solar panel interconnection Solar panel electrical interconnections are made of conductors that carry current and are sized according to the current rating and fault conditions; sometimes including in-line fuses. Panels are typically connected
in series of one or more panels to form strings to achieve a desired output voltage, and strings can be connected
in parallel to provide the desired current (ampere) capability of the PV system. In string connections the voltages of the modules add, but the current is determined by the lowest performing panel. This is known as the "Christmas light effect". In parallel connections the voltages will be the same, but the currents add. Arrays are connected up to meet the voltage requirements of the inverters and to not greatly exceed the current limits. Blocking and bypass
diodes may be incorporated within the module or used externally to deal with partial array shading, in order to maximize output. For series connections, bypass diodes are placed in parallel with modules to allow current to bypass shaded modules with a lower output voltage which would severely limit the current. For paralleled connections, a blocking diode may be placed in series with each module's string to prevent current flowing backwards through shaded strings thus short-circuiting other strings. If three or more strings are connected in parallel, fuses are generally included on each string to eliminate the possibility of diode failures overloading the panels and wiring and causing fires.
Connectors Outdoor solar panels usually include
MC4 connectors, automotive solar panels may include an
auxiliary power outlet and/or
USB adapter and indoor panels may have a
microinverter. == Efficiency ==