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EPH Series Hybrid Inverter

Experience the future of solar energy with our state-of-the-art EPH Hybrid Inverter. Enjoy pure sine wave solar output for optimal performance and reliability. Its compact and attractive 6.25″ design seamlessly blends with any space, while the LCD display with touch buttons offers intuitive control and monitoring.

With utility/battery priority input mode, the EPH Hybrid Inverter allows seamless switching between utility and generator inputs, ensuring uninterrupted power supply. Take advantage of utility and PV complementary power supply loads, maximizing the utility of your solar energy.

Stay connected with multiple communication modes, including RS232, RS485, WIFI, and Bluetooth. Monitor and control your system effortlessly with the optional WIFI monitoring and setting feature. Additionally, you can enhance performance and longevity with the optional dust filter.

Upgrade your solar power system with the EPH Hybrid Inverter and harness the full potential of solar energy. Embrace sustainability, efficiency, and convenience like never before.

EPH Series Hybrid Inverter

  • Energy Independence
  • Multiple communication
  • Backup Power
  • Energy Management & Monitoring
  • Scalability and Flexibility
  • Grid Interaction and Net Metering
  • Environmental Benefits
  • Cost Savings
  • Smart Integration & Control
  • Long-term Investment
  • Optimal Energy Utilization
  • 5 years warranty

Yes, a hybrid inverter can be used in both grid-tied and off-grid systems, making it a versatile solution for various energy setups. Here’s how a hybrid inverter can be used in each scenario:

  1. Grid-Tied Systems: In a grid-tied system, a hybrid inverter works in conjunction with the utility grid. It allows you to generate electricity from solar panels and consume it directly in your home or business. Any excess energy generated by the solar panels that is not immediately consumed is fed back into the grid, usually in exchange for credits or financial incentives through net metering programs. The hybrid inverter manages the energy flow, ensuring efficient conversion, monitoring grid requirements, and facilitating the export of surplus power.
  2. Off-Grid Systems: In an off-grid system, a hybrid inverter is a crucial component that enables you to operate independently from the utility grid. It combines solar panels, batteries, and the inverter to create a self-sustaining energy system. During the day, solar panels generate electricity, which is used to power electrical loads and charge the batteries. The hybrid inverter controls the charging process, ensuring efficient utilization of solar energy. When the sun is not available or during high-demand periods, the system draws power from the batteries. The inverter converts the DC power from the batteries into AC power for use by your home or business.

In both grid-tied and off-grid systems, a hybrid inverter plays a vital role in managing the energy flow and optimizing the system’s performance. It allows for seamless integration of solar panels, batteries, and the grid (in grid-tied systems) or standalone operation (in off-grid systems). This flexibility makes hybrid inverters suitable for a range of applications, whether you want to reduce your reliance on the grid or completely disconnect from it.

A hybrid inverter, also known as a multi-mode inverter, is a device that combines the functionality of both a grid-tied (or grid-connected) inverter and an off-grid (or standalone) inverter. It is designed to work with renewable energy systems, typically solar photovoltaic (PV) systems, and provides greater flexibility and functionality compared to traditional inverters.

Here are some key differences between a hybrid inverter and a traditional inverter:

  1. Operating Modes: A traditional inverter is designed for grid-tied systems and is primarily responsible for converting DC power generated by the solar panels into AC power for use in the electrical grid. In contrast, a hybrid inverter can operate in multiple modes, including grid-tied mode, off-grid mode, and hybrid mode. This means it can work with or without a connection to the grid and support energy storage systems.
  2. Energy Storage Integration: One of the main distinctions of a hybrid inverter is its ability to integrate with energy storage systems, such as batteries. It can charge and discharge the batteries based on the energy needs of the system, allowing for the utilization of stored energy during periods of low solar generation or during power outages.
  3. Energy Management: Hybrid inverters often come with advanced energy management capabilities. They can intelligently manage the energy flow between the solar panels, batteries, and the grid, optimizing the energy usage based on user preferences and electricity tariffs. This allows homeowners to maximize self-consumption of solar energy, reduce reliance on the grid, and potentially save on energy costs.
  4. Backup Power: Unlike traditional inverters that shut down during power outages, hybrid inverters with energy storage can provide backup power to critical loads when the grid goes down. This feature ensures uninterrupted power supply and can be particularly beneficial in areas with unreliable or unstable grid infrastructure.

Overall, the hybrid inverter offers greater flexibility and control over energy usage in solar PV systems, allowing homeowners to optimize self-consumption, store excess energy, and have backup power capabilities.

A hybrid inverter enables the integration of solar panels with battery storage systems by providing the necessary functionality to manage the flow of energy between these components. Here’s how it works:

  1. DC Power Conversion: Solar panels generate direct current (DC) electricity from sunlight. The hybrid inverter first converts this DC power into alternating current (AC) electricity, which is the standard form of electricity used in homes and buildings.
  2. Grid Interaction: In grid-tied mode, the hybrid inverter can synchronize the AC power output with the utility grid. This allows any excess solar power to be fed back into the grid, earning credits or reducing electricity bills through net metering programs. When solar power is insufficient, the hybrid inverter can draw additional power from the grid.
  3. Battery Charging: When the solar panels produce more power than is being consumed or fed back into the grid, the hybrid inverter can divert the excess energy to charge the battery storage system. It regulates the charging process to ensure optimal battery performance and longevity.
  4. Battery Discharging: During periods when solar generation is low or during a power outage, the hybrid inverter can draw power from the battery storage system. It converts the DC power stored in the batteries back to AC power, providing electricity to power the loads in the house or building.
  5. Energy Management: A key feature of hybrid inverters is their ability to intelligently manage energy flow. They incorporate advanced algorithms and control systems to optimize the utilization of solar power, battery storage, and grid power based on user preferences, energy demand, and electricity tariffs. This helps maximize self-consumption of solar energy, minimize grid reliance, and potentially reduce energy costs.

The hybrid inverter acts as the central control unit that coordinates the interaction between the solar panels, the battery storage system, and the grid. It ensures that energy is efficiently managed and utilized according to the system owner’s needs, whether it’s maximizing self-consumption, achieving energy independence, or providing backup power during outages.

Using a hybrid inverter in a residential or commercial solar energy system offers several advantages:

  1. Energy Independence: A hybrid inverter allows you to store excess solar energy in batteries for use during times of low solar generation or power outages. This enhances energy independence by reducing reliance on the grid and providing a reliable backup power source.
  2. Increased Self-Consumption: With a hybrid inverter, you can maximize self-consumption of solar energy by storing excess power in batteries instead of exporting it to the grid. This means you can use more of the clean energy you generate, reducing your dependence on grid electricity and potentially lowering your energy bills.
  3. Time-of-Use Optimization: Hybrid inverters enable smart energy management, allowing you to take advantage of time-of-use (TOU) electricity pricing. You can program the inverter to prioritize battery charging during periods of low electricity rates and use stored energy during peak-rate periods, helping you save on energy costs.
  4. Grid-Tied Flexibility: Hybrid inverters offer grid-tied functionality, allowing you to export excess solar power to the grid and potentially earn credits or financial incentives through net metering programs. This provides additional flexibility and opportunities to offset electricity costs.
  5. Seamless Integration: Hybrid inverters are designed to integrate seamlessly with solar panels and battery storage systems. They provide the necessary conversion, control, and monitoring capabilities to ensure efficient and reliable operation of the entire solar energy system.
  6. Smart Energy Management: Hybrid inverters often come with advanced monitoring and control features. You can monitor the performance of your solar panels, battery storage, and energy consumption in real-time, and adjust settings for optimal energy management. This empowers you to make informed decisions and optimize the efficiency of your solar energy system.
  7. Environmental Benefits: By utilizing a hybrid inverter in your solar energy system, you can maximize the use of clean, renewable solar energy, reducing your carbon footprint and contributing to a more sustainable future.

Overall, a hybrid inverter offers increased flexibility, control, and efficiency in managing your solar energy system. It allows you to make the most of your solar power, store excess energy, and have backup power available when needed, providing both economic and environmental benefits.

A hybrid inverter is a device that combines the functionalities of a traditional solar inverter and a battery inverter. It enables the integration of solar panels with battery storage systems, allowing for efficient energy management and optimization. Here’s how a hybrid inverter works and its key features:

  1. Solar Energy Conversion: Like a traditional solar inverter, a hybrid inverter converts the direct current (DC) electricity generated by solar panels into alternating current (AC) electricity that can be used to power electrical devices in your home or business. It ensures that the solar power is efficiently converted for immediate consumption or export to the grid.
  2. Battery Charging and Discharging: A key feature of a hybrid inverter is its ability to charge and discharge batteries. It controls the charging process, ensuring that the batteries are charged efficiently using the excess solar energy generated during the day. It also manages the discharging of the batteries, supplying power to your home or business during times of low solar generation or power outages.
  3. Energy Management and Optimization: Hybrid inverters have advanced energy management capabilities. They use sophisticated algorithms and control mechanisms to optimize the energy flow between solar panels, batteries, and the grid. This includes smart charging and discharging strategies to maximize self-consumption, time-of-use optimization, and grid interaction for net metering or grid support.
  4. Monitoring and Control: Hybrid inverters often come with monitoring and control systems that allow you to track the performance of your solar panels, batteries, and energy consumption in real-time. You can access this information through user-friendly interfaces, mobile apps, or online platforms, giving you insights into your energy usage and system performance.
  5. Grid-Tied Functionality: Hybrid inverters can operate in grid-tied mode, meaning they can be connected to the utility grid. In this mode, they enable the export of excess solar energy to the grid, allowing you to earn credits or financial incentives through net metering or feed-in tariffs. They also provide grid support functions, such as frequency and voltage regulation.
  6. Backup Power Supply: One of the significant advantages of a hybrid inverter is its ability to provide backup power during grid outages. When the grid goes down, the hybrid inverter can automatically switch to backup mode, utilizing the stored energy in the batteries to power critical loads in your home or business. This provides peace of mind and uninterrupted power supply when needed.
  7. Integration with Energy Management Systems: Hybrid inverters can be integrated with energy management systems, smart home automation, and monitoring platforms. This allows for seamless integration and control of various energy resources, such as solar panels, batteries, electric vehicle charging stations, and smart appliances. It enables you to optimize energy usage, reduce costs, and improve overall system efficiency.

Overall, a hybrid inverter combines the functions of a solar inverter and a battery inverter, providing advanced energy management and optimization capabilities. It ensures efficient conversion of solar energy, enables battery charging and discharging, offers grid-tied functionality, and provides backup power supply during outages. Its key features include monitoring and control, integration with energy management systems, and the ability to maximize self-consumption and optimize grid interaction.

Using a hybrid inverter in your solar energy system can offer several benefits in terms of energy management and cost savings. Here are some key advantages:

  1. Efficient Energy Utilization: A hybrid inverter enables you to maximize the use of the solar energy you generate. It ensures efficient conversion of DC power from the solar panels into usable AC power for your home or business. By optimizing the energy flow and managing the charging and discharging of batteries, a hybrid inverter helps you extract the most value from your solar system.
  2. Energy Independence and Resilience: With a hybrid inverter, you have the ability to operate independently from the utility grid, especially in off-grid systems or during power outages. By coupling solar panels with battery storage, you can store excess solar energy and use it when needed, reducing your reliance on the grid and enhancing your energy resilience.
  3. Peak Demand Management: Hybrid inverters offer features like load shifting and peak shaving. Load shifting allows you to shift the consumption of electricity to periods of lower grid demand or when solar generation is high, optimizing your energy usage. Peak shaving involves using stored energy from the batteries during times of high electricity demand, reducing your peak power consumption and avoiding costly peak-demand charges.
  4. Time-of-Use (TOU) Optimization: In regions with time-of-use pricing, where electricity costs vary based on the time of day, a hybrid inverter can help you save money. By storing excess solar energy during off-peak hours and using it during peak-rate periods, you can reduce your electricity costs and increase your overall energy savings.
  5. Financial Incentives: In some regions, there may be financial incentives or programs that reward the integration of energy storage systems with solar installations. By utilizing a hybrid inverter, you may be eligible for such incentives, providing additional cost savings and return on investment.

Overall, a hybrid inverter offers improved energy management, increased self-consumption of solar energy, energy independence, and potential cost savings. It allows you to make the most of your solar energy system, optimize energy usage, and enhance the overall efficiency of your energy system.

Parallel installation in a hybrid inverter refers to the ability to connect multiple inverters together to work in unison. It allows for the expansion of the solar power system by adding more inverters, thereby increasing the overall system capacity and output.

In parallel installation, each hybrid inverter operates independently but synchronizes with the others to create a seamless and efficient power generation system. This setup offers several advantages, including:

  1. Increased Power Output: Parallel installation allows for the aggregation of power from multiple inverters, resulting in higher total power output. It enables the system to meet higher energy demands, especially during peak usage periods.
  2. Enhanced Flexibility and Scalability: By adding more hybrid inverters in parallel, the system can be easily scaled up to accommodate future energy needs. This flexibility makes it suitable for both residential and commercial applications.
  3. Redundancy and Reliability: Parallel installation improves system reliability and provides redundancy. If one inverter fails, the others continue to operate, ensuring uninterrupted power supply. This redundancy feature enhances system reliability and minimizes downtime.
  4. Optimal Performance and Load Balancing: Parallel installation allows for load balancing among the inverters, ensuring that the workload is evenly distributed. This optimization helps maximize the efficiency of each inverter and extends the overall lifespan of the system.

In summary, a hybrid inverter with parallel installation capability provides the flexibility to expand the solar power system, increases power output, enhances system reliability, and optimizes performance. It is a versatile solution that meets the growing energy demands of residential and commercial users while ensuring a sustainable and efficient power generation experience.

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