Background
The amount of power generated by a solar power system is positively correlated with the grid-connected working time of the system. Under the same conditions, the earlier the inverter starts up and connects to the grid, the higher the power generation. For example, in the same summer, one inverter can usually start up and be connected to the grid at around 05:00, but another inverter may start later, or even 2~3 hours slower than the other. What could cause this? How can it be resolved?
In this Solis seminar we will share with you the reasons for the later start of inverters and some related solutions.
Figure 1: Normally inverter , start early and shut down late
Cause
Different inverters have different start up voltages. For example, the startup voltage of low-power inverters is generally 60V~90V, and the startup voltage of medium-power inverters is generally 120V~180V. High-power inverters it is above 190V; this also leads to different inverters starting to work at different times.
Figure 2: Starting voltages of different inverters
2、A Possible PV String Problem
① Too few PV modules connected in series
If the number of modules connected in series is too few, the voltage generated by the string will be low due to the lack of irradiance early in the morning. This won't reach the starting voltage of the inverter, resulting in a later start up. This situation generally occurs in spring, winter or on rainy days.
Figure 3: The number of PV panels needs to be reasonable
SolutionDuring the design process, ensure enough panels are configured in series to ensure the inverter and system work efficiency.
② PV module shading, dirt or damage
Solar modules are affected by shading, or when surrounding vegetation blocks the modules or the modules are dirty/ damaged. This will all result in a low string voltage, which will cause the inverter to start late.
Figure 4: PV panel occlusion and damage
Solution:Reasonable design in the early stage, timely correction when design problems are found; regular maintenance and cleaning of PV modules.
3、System Error
The third key factor is system faults, such as insulation resistance, grid overvoltage/undervoltage and current leakage, etc., Most common being low insulation resistance and grid overvoltage problems
① Insulation Resistance
Insulation resistance is mainly that the insulation resistance of the DC side is detected to be too low before the inverter is connected to the grid. The inverter will disconnect from the grid, enter the protection mode, and send and display an error message. Such problems are likely to occur in the morning with heavy humidity and moisture in the air increases. This results in a lower impedance, causing the inverter to enter the protection mode and grid connection delay.
Figure 5: The PV system has a low impedance problem
Solution:Refer to Solis Seminar Episode 15: PV Isolation Protection
② Grid Overvoltage
Shortly after dawn, the local power grid can experience transient fluctuations and overvoltage, causing the inverter to shut down for protection. When the grid voltage returns to a normal value, the current alarm is cleared and the inverter is reconnected to the grid. If it is always higher than the upper limit of grid reconnection voltage, the inverter will display: grid detection or grid overvoltage. Overvoltage of the power grid in the morning will cause the inverter to be frequently disconnected and connected to the grid, delaying the connection time and causing the illusion of the inverter "starting late".
Solution:Refer to Solis Seminar [Episode 25] : Solution for "OV-G-V0X" alarm
The working time of a solar power system is positively related to its power generation. A system that starts earlier and stops later will produce more power so if your solar system starts late, troubleshoot and solve problems according to the solutions above, so that your system generation is maximized and maintained. At design stage, ensure enough panels are connected to a single string to provide enough voltage for the system to start up.