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The 3-Phase Solar Pump Inverter for Water represents a high-performance power conversion solution engineered specifically for large-scale solar-powered water pumping systems. This advanced inverter converts the direct current (DC) generated by solar photovoltaic arrays into three-phase alternating current (AC) to drive powerful water pumps, delivering reliable water supply for agricultural, municipal, and industrial applications. Designed for high-power applications, this inverter combines robust construction with intelligent control algorithms to maximize water output while ensuring system reliability in remote locations. Its three-phase design enables efficient operation of large pumps that require higher power and more stable operation than single-phase systems can provide, making it ideal for projects requiring significant water volume or pressure.
The inverter supports three-phase pumps ranging from 5kW to 120kW, making it suitable for large-scale water pumping applications. It features a robust power stage capable of handling peak loads up to 150% of rated capacity for 60 seconds, accommodating startup surges and transient demand increases.
Equipped with 2 independent MPPT channels, the inverter optimizes energy harvest from large solar arrays, even when different sections of the array experience varying light conditions due to shading or orientation. The MPPT operates across an extended voltage range of 300V to 1500V DC, maximizing energy production throughout the day.
Featuring sensorless vector control technology, the inverter delivers precise speed and torque regulation for three-phase induction motors commonly used in large water pumps. It supports soft starting, reducing mechanical stress on pump systems and preventing water hammer in piping networks.
Built to industrial standards, the inverter features an IP65 protection rating enclosure with enhanced cooling systems to maintain performance in high-temperature environments up to 60°C. It includes comprehensive protection against overvoltage, undervoltage, overload, short circuit, and ground fault conditions.
The inverter powers center pivot irrigation systems, large drip irrigation networks, and flood irrigation pumps for extensive agricultural operations, delivering the high volumes of water required for commercial crop production.
Small to medium-sized communities utilize the inverter to power water extraction pumps from wells or surface water sources, providing reliable drinking water and municipal services using renewable energy.
Mines, construction sites, and industrial facilities use the inverter for dewatering operations, process water supply, and wastewater management, benefiting from both energy savings and reliable performance.
The high-power capacity enables efficient filling of reservoirs and water transfer between locations, supporting water resource management and storage for various applications.
Three-phase inverters can handle much higher power levels (5kW to 120kW) compared to single-phase models, making them suitable for large pumps requiring significant water flow or pressure. Three-phase motors also offer smoother operation, longer lifespan, and higher efficiency than single-phase motors in high-power applications.
As a general guideline, the solar array should be sized at 1.2 to 1.5 times the pump's rated power to account for varying weather conditions and ensure sufficient water production throughout the year. A 50kW pump would typically require a 60kW to 75kW solar array.
Yes, hybrid models are available that can operate in both off-grid (solar-only) and grid-connected modes, providing flexibility for systems where grid power is available but expensive or unreliable. These models can switch between power sources based on availability and cost.
DC oversizing refers to installing a solar array larger than the inverter's rated capacity (typically up to 175% of inverter rating), allowing increased energy harvest during morning, evening, and cloudy conditions when the inverter can operate at full capacity despite lower irradiance.
The 3-Phase Solar Pump Inverter for Water represents a high-performance power conversion solution engineered specifically for large-scale solar-powered water pumping systems. This advanced inverter converts the direct current (DC) generated by solar photovoltaic arrays into three-phase alternating current (AC) to drive powerful water pumps, delivering reliable water supply for agricultural, municipal, and industrial applications. Designed for high-power applications, this inverter combines robust construction with intelligent control algorithms to maximize water output while ensuring system reliability in remote locations. Its three-phase design enables efficient operation of large pumps that require higher power and more stable operation than single-phase systems can provide, making it ideal for projects requiring significant water volume or pressure.
The inverter supports three-phase pumps ranging from 5kW to 120kW, making it suitable for large-scale water pumping applications. It features a robust power stage capable of handling peak loads up to 150% of rated capacity for 60 seconds, accommodating startup surges and transient demand increases.
Equipped with 2 independent MPPT channels, the inverter optimizes energy harvest from large solar arrays, even when different sections of the array experience varying light conditions due to shading or orientation. The MPPT operates across an extended voltage range of 300V to 1500V DC, maximizing energy production throughout the day.
Featuring sensorless vector control technology, the inverter delivers precise speed and torque regulation for three-phase induction motors commonly used in large water pumps. It supports soft starting, reducing mechanical stress on pump systems and preventing water hammer in piping networks.
Built to industrial standards, the inverter features an IP65 protection rating enclosure with enhanced cooling systems to maintain performance in high-temperature environments up to 60°C. It includes comprehensive protection against overvoltage, undervoltage, overload, short circuit, and ground fault conditions.
The inverter powers center pivot irrigation systems, large drip irrigation networks, and flood irrigation pumps for extensive agricultural operations, delivering the high volumes of water required for commercial crop production.
Small to medium-sized communities utilize the inverter to power water extraction pumps from wells or surface water sources, providing reliable drinking water and municipal services using renewable energy.
Mines, construction sites, and industrial facilities use the inverter for dewatering operations, process water supply, and wastewater management, benefiting from both energy savings and reliable performance.
The high-power capacity enables efficient filling of reservoirs and water transfer between locations, supporting water resource management and storage for various applications.
Three-phase inverters can handle much higher power levels (5kW to 120kW) compared to single-phase models, making them suitable for large pumps requiring significant water flow or pressure. Three-phase motors also offer smoother operation, longer lifespan, and higher efficiency than single-phase motors in high-power applications.
As a general guideline, the solar array should be sized at 1.2 to 1.5 times the pump's rated power to account for varying weather conditions and ensure sufficient water production throughout the year. A 50kW pump would typically require a 60kW to 75kW solar array.
Yes, hybrid models are available that can operate in both off-grid (solar-only) and grid-connected modes, providing flexibility for systems where grid power is available but expensive or unreliable. These models can switch between power sources based on availability and cost.
DC oversizing refers to installing a solar array larger than the inverter's rated capacity (typically up to 175% of inverter rating), allowing increased energy harvest during morning, evening, and cloudy conditions when the inverter can operate at full capacity despite lower irradiance.
