The tasks of a PV inverter are as varied as they are demanding:
1. Low-loss conversion
One of the most important characteristics of an inverter is its conversion efficiency. This value indicates what proportion of the energy “inserted” as direct current comes back out in the form of alternating current. Modern devices can operated with an efficiency of around 98 percent.
One of the most important characteristics of an inverter is its conversion efficiency. This value indicates what proportion of the energy “inserted” as direct current comes back out in the form of alternating current. Modern devices can operated with an efficiency of around 98 percent.
2. Power optimization
The power characteristics curve of a PV module is strongly dependent on the radiation intensity and the temperature of the module – in other words, on values that continually change over the course of the day. For this reason, the inverter must find and continually observe the optimal operating point on the power characteristics curve, in order to “bring out” maximum power from the PV modules in every situation. The optimal operating point is called the "maximum power point" (MPP), and the search for, and tracking of, this MPP is correspondingly called "MPP tracking." MPP tracking is extremely important for the energy output of a PV plant.
The power characteristics curve of a PV module is strongly dependent on the radiation intensity and the temperature of the module – in other words, on values that continually change over the course of the day. For this reason, the inverter must find and continually observe the optimal operating point on the power characteristics curve, in order to “bring out” maximum power from the PV modules in every situation. The optimal operating point is called the "maximum power point" (MPP), and the search for, and tracking of, this MPP is correspondingly called "MPP tracking." MPP tracking is extremely important for the energy output of a PV plant.
3. Monitoring and securing
On the one hand, the inverter monitors the energy yield of the PV plant and signals any problems. On the other, it also monitors the power grid that it is connected to. Thus, in the event of a problem in the power grid, it must immediately disconnect the plant from the grid for reasons of safety or to help support the grid – depending on the requirements of the local grid operator.
On the one hand, the inverter monitors the energy yield of the PV plant and signals any problems. On the other, it also monitors the power grid that it is connected to. Thus, in the event of a problem in the power grid, it must immediately disconnect the plant from the grid for reasons of safety or to help support the grid – depending on the requirements of the local grid operator.
In addition, in most cases the inverter has a device
that can safely interrupt the current from the PV modules. Because PV
modules are always live when light is shining on them, they cannot be
switched off. If the inverter cable is disconnected during operation,
this can lead to dangerous light arcs forming, which do not go out on
account of the direct current. If the cutout device is integrated
directly in the inverter, installation and wiring efforts are reduced
considerably.
4. Communication
Communication interfaces on the inverter allow control and monitoring of all parameters, operational data, and yields. Data can be retrieved and parameters can be set for the inverter via a network connection, industrial fieldbus such as RS485, or wireless via SMA Bluetooth®. In most cases, data is retrieved through a data logger, which collects and prepares the data from several inverters and, if desired, transmits them to a free online data portal (e.g. Sunny Portal from SMA).
Communication interfaces on the inverter allow control and monitoring of all parameters, operational data, and yields. Data can be retrieved and parameters can be set for the inverter via a network connection, industrial fieldbus such as RS485, or wireless via SMA Bluetooth®. In most cases, data is retrieved through a data logger, which collects and prepares the data from several inverters and, if desired, transmits them to a free online data portal (e.g. Sunny Portal from SMA).
5. Temperature management
The temperature in the inverter housing also influences conversion efficiency. If it rises too much, the inverter has to reduce its power. Under some circumstances the available module power cannot be fully used.
The temperature in the inverter housing also influences conversion efficiency. If it rises too much, the inverter has to reduce its power. Under some circumstances the available module power cannot be fully used.
On the one hand, the installation location affects
the temperature – a constantly cool environment is ideal. On the other
hand, it directly depends on the inverter operation: even an efficiency
of 98 percent means a power loss of two percent –in form of heat. If
the plant power is 10 kW, the maximum thermal capacity is still 200 W.
Therefore, an efficient and reliable cooling system for the enclosure
is very important – such as SMA’s “OptiCool” cooling concept. The
optimum thermal layout of the components allows them to dissipate their
heat directly to the environment, while the whole encasing acts as a
heat sink at the same time. This allows the inverters to work at
maximum rated capacity even at ambient temperatures of up to 50° C.
6. Protection
A weather-proof enclosure, ideally built in line with protective rating IP65, allows the inverter to be installed in any desired place outdoors. The advantage: the nearer to the modules the inverter can be installed, the lower the expenditure for the comparatively expensive DC wiring.
A weather-proof enclosure, ideally built in line with protective rating IP65, allows the inverter to be installed in any desired place outdoors. The advantage: the nearer to the modules the inverter can be installed, the lower the expenditure for the comparatively expensive DC wiring.
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