2000 Watt Solar Power Inverter

Hot Products

GSC Series PV Array Combiner Box DC1000V / DC1500V

DC 1500V Turnkey Solution GSM6250C-MV/GSM5000C-MV

String Grid-Tied PV Inverter KSG-50K-HV / KSG-60K-HV

3.6KW 4KW 4.6KW 5KW 6KW Single Phase Hybrid solar inverter

Grid Tied Solar Inverter 8000w-11000w max 8300w TUV/UL/CSA/FCC

DC1500V Turnkey Solution/Inverter GSL2500C-MV

5.5KW Off-grid Hybrid Solar Home Inverter With MPPT Charge Controller

DC 1500V Turnkey Solution/Inverter GSM2500C-MV

Three Phase AC DC Hybrid Solar Inverter 5KVA-12KVA/8-19.2KW

DC1500V Central Inverter GSM3125C/GSM3400C/GSM2500C/GSM3000C

FAQ

A solar inverter is designed to handle voltage and frequency variations caused by grid disturbances by employing various control mechanisms and protection features. Firstly, the inverter continuously monitors the voltage and frequency levels of the grid, and it adjusts its output accordingly to match the grid's requirements. If there is a voltage or frequency fluctuation, the inverter will either increase or decrease the output power to maintain the desired voltage and frequency levels. To handle voltage variations, the solar inverter utilizes a voltage regulation mechanism. If the grid voltage increases or decreases beyond a certain threshold, the inverter adjusts its internal voltage regulation circuitry to ensure a stable and regulated output voltage. This helps protect the inverter and connected devices from potential damage due to overvoltage or undervoltage conditions. Similarly, to handle frequency variations, the solar inverter incorporates a frequency control mechanism. If the grid frequency deviates from the specified range, the inverter adjusts its internal frequency control circuitry to maintain a stable and accurate output frequency. This ensures that the power generated by the solar panels remains synchronized with the grid, allowing for efficient power transfer and preventing any damage to the inverter or connected devices. Furthermore, solar inverters often include advanced features such as anti-islanding protection. This feature detects any abnormal grid conditions, such as voltage or frequency fluctuations beyond a safe limit. If an islanding condition is detected, where the solar system continues to generate power even when the grid is down, the inverter will disconnect from the grid to prevent any potential safety hazards for utility workers. Overall, a solar inverter is designed to handle voltage and frequency variations caused by grid disturbances through continuous monitoring, voltage regulation, frequency control, and protective features. These capabilities ensure reliable and safe operation of the solar power system while maintaining a stable connection with the utility grid.

A grid-tied solar inverter functions by converting the direct current (DC) produced by solar panels into usable alternating current (AC) that can be fed into the electrical grid. This inverter synchronizes the frequency and voltage of the generated electricity with that of the grid, allowing for seamless integration and distribution of solar power to homes and businesses. Additionally, it continuously monitors the grid voltage and shuts down in the event of a power outage to ensure safety and prevent back-feeding.

A solar inverter handles grid faults or disturbances by continuously monitoring the grid voltage and frequency. When a fault or disturbance is detected, the solar inverter quickly disconnects from the grid to ensure safety and protect the system. It then enters a standby mode until the grid returns to normal conditions. Once the grid stabilizes, the solar inverter reconnects and resumes its normal operation of converting solar energy into usable electricity.

The role of isolation in a solar inverter is to provide electrical safety and protect sensitive electronic components. It helps to separate the direct current (DC) input from the alternating current (AC) output, ensuring that any faults or fluctuations in one do not affect the other. Isolation also prevents any potential ground faults, reducing the risk of electric shock and improving system reliability.

The role of a solar inverter in a microgrid system is to convert the direct current (DC) electricity generated by solar panels into alternating current (AC) electricity that can be used to power the various loads within the microgrid. It also manages the flow of electricity between the microgrid and the utility grid, allowing for bidirectional power flow and enabling the system to operate in both grid-connected and islanded modes. Additionally, the solar inverter ensures the stability and quality of the electricity supply, regulating voltage and frequency levels to match the requirements of the microgrid.

The working principle of photovoltaic grid - connected inverter

In the small-capacity inverter generally push-pull inverter circuit, full-bridge inverter circuit and high-frequency step-up inverter circuit three, push-pull circuit, the step-up transformer neutral plug connected to the positive power supply, two power Alternating current, the output to get AC power, due to the power transistor to ground, drive and control circuit is simple, and because the transformer has a certain leakage inductance, can limit the short circuit current, thus improving the reliability of the circuit. The disadvantage is the low utilization of the transformer, driving the emotional load is poor.

Yes, a solar inverter can be used with a solar-powered irrigation system. The solar inverter is responsible for converting the direct current (DC) generated by the solar panels into alternating current (AC) that can be used to power the irrigation system. This allows the solar energy to be efficiently utilized for irrigation purposes.

The role of a maximum power point tracker (MPPT) in a solar inverter is to optimize the energy harvesting efficiency of the solar panels. It continuously monitors the output voltage and current of the panels and adjusts the operating point to ensure maximum power extraction from the panels. By tracking the maximum power point, the MPPT allows the solar inverter to generate the highest possible energy output from the available sunlight, thus maximizing the overall system performance.