Network inverters

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Solplanet ASW 30K-LT-G2 inverter

1.615  netto +VAT 23%
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Solplanet ASW 30K-LT-G3 inverter

1.625  netto +VAT 23%
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Solplanet ASW 36K-LT-G2 inverter

1.749  netto +VAT 23%
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Solplanet ASW 40K-LT-G2 inverter

1.709  netto +VAT 23%
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Solplanet ASW 45K-LT-G2 inverter

1.921  netto +VAT 23%
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Solplanet ASW 80K-LT inverter

4.002  netto +VAT 23%
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SPI60K-B 60 kW 3F Kehua inverter

2.616  netto +VAT 23%
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Ai-Logger 1000 data logger

432  netto +VAT 23%
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Solplanet ASW 110K-LT inverter

3.716  netto +VAT 23%
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Solplanet ASW 100K-LT inverter

3.576  netto +VAT 23%
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HPT-33K 3F Hypontech inverter

1.677  netto +VAT 23%
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HPT-25K 3F Hypontech inverter

1.374  netto +VAT 23%
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HPT-20K 3F Hypontech inverter

1.127  netto +VAT 23%
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HPT-15K 3F Hypontech inverter

1.077  netto +VAT 23%
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HPT-30K 3F Hypontech inverter

1.602  netto +VAT 23%
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HPT-50K 3F Hypontech inverter

2.040  netto +VAT 23%
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HPT-40K 3F Hypontech inverter

1.822  netto +VAT 23%
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HPT-36K 3F Hypontech inverter

1.480  netto +VAT 23%
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Sofar 24KTLX-G3 3F inverter

1.696  netto +VAT 23%
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17KTLX-G3 3F Sofar Inverter

1.368  netto +VAT 23%
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Sofar 15KTLX-G3 3F inverter

1.284  netto +VAT 23%
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Sofar 20KTLX-G3 3F inverter

1.530  netto +VAT 23%
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2700TL-G3 1F Sofar inverter

380  netto +VAT 23%
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3KTLM-G2 1F Sofar inverter

568  netto +VAT 23%
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Sofar 3.3KTL-X 3F Inverter

738  netto +VAT 23%
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Sofar 22KTLX-G3 3F inverter

1.614  netto +VAT 23%
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Sofar 50KTLX-G3 3F inverter

2.781  netto +VAT 23%
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Sofar 30KTLX-G3 3F inverter

1.889  netto +VAT 23%
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4.4KTLX-G3 3F Sofar inverter

872  netto +VAT 23%
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Sofar inverter 6.6KTLX-G3 3F

900  netto +VAT 23%
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Sofar 11KTLX-G3 3F inverter

1.018  netto +VAT 23%
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Sofar 8.8KTLX-G3 3F inverter

944  netto +VAT 23%
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Sofar 5.5KTL-X-G3 3F Inverter

761  netto +VAT 23%
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Sofar 4.4KTL-X 3F inverter

806  netto +VAT 23%

On-grid photovoltaic inverters.

On-grid photovoltaic inverters, also known as on-grid inverters, are a key element in solar systems connected to the public power grid. Their main function is to convert direct current (DC) generated by solar panels into alternating current (AC), which is compliant with the parameters of the electrical network. These devices allow not only the use of solar energy to power current needs, but also to send surplus energy produced back to the grid.

The use of on-grid photovoltaic inverters brings many economic benefits, including the possibility of using net metering systems, which allows the surplus energy produced to be deducted from the energy consumed, which results in lower electricity bills. Thanks to this, these systems not only effectively reduce the maintenance costs of households and businesses, but also contribute to a faster return on investment in photovoltaics.

On-grid inverters are equipped with advanced monitoring and regulation technologies that ensure their efficient operation and protect against potential problems, such as overvoltages or overloads. These systems are capable of automatically adapting to the operating conditions of the network, which is important for the stability of both the local system and the entire power grid.

On-grid photovoltaic inverters are an irreplaceable component of modern solar installations, ensuring not only the efficient production and use of solar energy, but also supporting activities for sustainable development through integration with the energy system and enabling economic benefits for users.

 

Types of grid photovoltaic inverters.

Network photovoltaic inverters, key in the integration of solar systems with the public power grid, are divided into several types, differing in design and functionality. Each type is designed to meet the diverse requirements of photovoltaic installations and optimize their efficiency.

Central inverters are the most commonly used devices in large photovoltaic installations, such as solar farms or large commercial systems. They are characterized by high power and efficiency, which allows for the operation of many panels connected to a single inverter. Their advantage is the ability to be centrally managed and monitored, which makes it easier to operate large systems.

String inverters allow a string of solar panels to be connected to a single inverter. They are ideal for smaller photovoltaic installations or those that extend into shady areas, because each string can be optimized independently, minimizing the impact of shading on the performance of the entire system. These inverters are easier to install and are often chosen by homeowners and small businesses.

Micro inverters are used on the smallest scales, such as in photovoltaic systems on single residential buildings. Each solar panel is equipped with a separate micro inverter, which allows for maximizing the energy production from each panel independently. Micro inverters provide high efficiency even in partial shade, because each panel operates independently.

Hybrid inverters combine the functions of on-grid inverters with the ability to operate off-grid, so they can store excess energy in batteries. They offer high flexibility in energy management and are ideal for systems that require independence from the grid and continuity of energy supply.

Choosing the right grid inverter is crucial to optimizing the performance of the photovoltaic system and should be done taking into account the specifics of the location, the size of the installation and the individual energy needs. Each type of inverter offers unique benefits that can significantly impact the efficiency, cost, and reliability of the entire system.

 

Photovoltaic grid-tie inverters.

Photovoltaic grid-tie inverters play a fundamental role in the process of adapting solar energy for home and industrial use. Also known as grid-tie inverters, these devices convert direct current (DC) generated by solar panels into alternating current (AC), which is compatible with the public electricity grid. This allows solar energy to be used directly in facilities or exported to the grid.

The innovation of grid-tie inverters is demonstrated by their ability to optimize energy production. These devices monitor and regulate the voltage and frequency of the current in such a way as to maximize the use of solar energy while ensuring the stability of the electrical grid. Advanced inverter models are equipped with intelligent algorithms that adjust the system’s operation to current solar conditions and energy demand.

Photovoltaic grid-tie inverters are also designed with long-term efficiency and reliability in mind. Many models are equipped with safety features such as surge protection, insulation detection and automatic shutdown in the event of a grid failure. These features ensure that the photovoltaic system not only provides energy efficiently, but also does so in a safe manner for users and the electrical infrastructure.

Grid inverters for photovoltaics are key components of solar systems that enable the efficient and safe use of solar energy. Their advanced technology not only ensures optimal energy efficiency, but also contributes to the stability and security of both the solar system and the entire power grid.

 

The most important advantages of solar grid inverters.

Solar grid inverters are an indispensable element of modern photovoltaic installations, playing a key role in the efficient conversion and distribution of solar energy. Their main advantages are energy efficiency, adaptability and support for ecological initiatives.

Energy efficiency of grid inverters is one of their most important advantages. These devices convert direct current generated by solar panels into alternating current, which can be directly used in the household or sent to the public grid. Thanks to high conversion efficiency, inverters minimize energy losses during this process, which translates into greater savings for users and better use of natural resources.

Adaptivity is another important feature of grid inverters, enabling flexible management of energy production. Advanced monitoring and control systems in these devices allow for automatic adjustment to changing operating conditions, such as changes in sunlight or energy demand. This increases the overall efficiency of the system and ensures energy stability, regardless of external factors.

Support for sustainable development is a key aspect of using grid inverters in solar systems. They convert solar energy into an easily accessible and environmentally friendly form of energy, which helps reduce harmful emissions and increase the share of renewable sources in the overall energy mix. This makes grid inverters an important element in achieving global environmental goals, such as reducing the carbon footprint.

In summary, solar grid inverters not only offer technological advancement and efficiency, but also contribute to a greener and more sustainable future. They are essential for the efficient and economic use of solar energy, making them a valuable component of any photovoltaic installation.

 

Performance of solar grid inverters.

The efficiency of photovoltaic grid inverters plays a key role in assessing the efficiency of solar systems. These devices are responsible for converting direct current (DC) produced by solar panels into alternating current (AC), which complies with power grid standards. Thanks to this, solar energy can be used directly in homes, businesses or fed into the public grid.

Conversion efficiency is one of the most important parameters to pay attention to when assessing inverters. Modern devices can achieve an efficiency of 98%, which means minimal energy loss during the conversion process. High inverter efficiency translates directly into the cost-effectiveness of solar installations, enabling a faster return on investment.

Adaptation ability to different operating conditions is another important aspect affecting the efficiency of inverters. These devices must effectively cope with differences in sunlight, temperature and other environmental factors that can affect the amount of energy produced. Advanced algorithms managing the inverter operation allow for the optimization of performance depending on current conditions, which increases the overall efficiency of the photovoltaic system.

Durability and reliability of grid inverters are also important for maintaining high performance over a long period of time. High-quality components and a solid construction ensure a long service life of the devices and minimize the need for their service or replacement. In addition, modern inverters are equipped with monitoring systems that allow for quick diagnostics and solving potential problems, which additionally increases their operational efficiency.

The efficiency of photovoltaic grid inverters is the foundation for achieving maximum benefits from solar installations. High conversion efficiency, the ability to adapt to changing conditions and the durability of the devices are key features to consider when choosing an inverter for your system.

 

Application of grid-tied inverters.

Grid-tied inverters, also called on-grid inverters, play a key role in photovoltaic systems integrated with the public power grid. The main task of these devices is to convert direct current (DC) generated by solar panels into alternating current (AC), which complies with the standards and requirements of the power grid. Thanks to this, the energy produced by the solar panels can be used directly in households, businesses or transferred to the grid.

One of the main advantages of grid-tied inverters is their ability to use the net-metering system. It allows the amount of energy generated by the solar panels to be deducted from the amount of energy consumed, which can significantly reduce electricity bills. This is particularly attractive to property owners looking to reduce operating costs and to businesses looking to increase their ecological responsibility and reduce their carbon footprint.

Grid-tie inverters are also equipped with advanced monitoring technologies that allow users to constantly monitor the performance of their photovoltaic installation. These systems provide valuable operational data that can be used to optimize system performance and quickly identify and resolve technical issues. This makes the investment in photovoltaics more predictable and cost-effective.

Grid-tie inverters are an essential element of photovoltaic systems that are connected to the electricity grid. Their use allows for efficient and economical management of solar energy, contributing to sustainable development and supporting pro-ecological practices in the energy sector.

 

Price of grid-tie photovoltaic inverters.

The price of grid-tie photovoltaic inverters is variable and depends on many factors, including the power of the device, technological advancement, and additional functions offered by a given model. The price range can be wide, which allows you to adjust the choice of device to the specific needs and financial possibilities of each installation.

Inverters with lower power, which are intended for small to medium-sized photovoltaic systems, are usually cheaper. They are ideal for households that want to minimize the initial costs of installation. On the other hand, inverters with higher power, equipped with additional functions such as advanced monitoring systems or the possibility of integration with different types of batteries, are more expensive, but offer more energy management options and better efficiency, which is especially beneficial in larger commercial or industrial projects.

When choosing a grid-tie inverter, it is also worth considering the long-term benefits of its operation. While more technologically advanced and expensive models may have a higher upfront cost, they often offer lower operating and maintenance costs, as well as better energy efficiency. This translates into a faster return on investment and long-term savings.

The price of a grid-tie solar inverter should be considered in the context of both the initial cost and the potential savings and benefits. Technical support and warranty also add value, and can impact the durability and reliability of the system, making them important decision-making factors when making a purchase.

 

FAQ: Frequently Asked Questions.

What is a grid-tie inverter?

A grid-tie inverter is a device that converts direct current (DC) generated by solar panels into alternating current (AC), which is compatible with the parameters of the public electricity grid. The main task of a grid inverter is to enable the use of solar energy in standard electrical installations and its transmission to the public network.

Thanks to grid inverters, the energy produced by photovoltaic panels can be used directly in a household or company, and surplus energy can be sold to the local power grid. This not only reduces energy consumption costs, but also allows for the generation of additional income.

Grid inverters are equipped with modern energy monitoring and management technologies, which allows for the optimization of the use of solar energy. These devices are also capable of automatic shutdown in the event of a grid failure, which is required by safety regulations and protects both the installation and the grid from potential damage.

A grid-tied inverter is a key component of any grid-integrated photovoltaic system, enabling efficient use of solar energy, both for your own needs and in cooperation with energy suppliers.

Are inverters and inverters the same thing?

Inverters and inverters are terms that are often used interchangeably, but can differ depending on the context of their application. Both devices convert electricity, but their specific roles can differ. An inverter, also known as a converter, converts direct current (DC) to alternating current (AC) and is essential in photovoltaic systems and other applications requiring this type of conversion. The term “inverter” is often used in an industrial context to describe devices that regulate the speed of electric motors by manipulating the frequency of the AC current.

What are photovoltaic grid-tie inverters used for?

Photovoltaic grid-tie inverters are used to convert direct current (DC), generated by solar panels, into alternating current (AC), which can be used in the household or transmitted to the public grid. Solar energy can be used on an ongoing basis or sold to an energy supplier, which allows owners of photovoltaic installations to reduce electricity costs.

Grid-tie inverters monitor the parameters of the electrical network, ensuring security and stability for both the photovoltaic system and the grid. They are a key element in the efficient and economical use of renewable energy in everyday life.

Which inverter should you choose for a photovoltaic installation?

Choosing the right inverter for a photovoltaic installation is crucial to maximizing the efficiency and performance of the entire system. When making a decision, several factors should be considered, such as the power and scale of the installation, the type and number of solar panels, as well as specific requirements for integration with the power grid.

It is necessary to choose an inverter with a capacity adequate to the total power of the solar panels. It is also recommended to choose devices from reputable manufacturers, offering a long-term warranty and technical support. It is important that the inverter has the ability to be remotely monitored and managed, which makes it easier to maintain and operate the system. The final choice should be based on a thorough cost-benefit analysis, ensuring optimal adjustment to the needs and expectations of the user.

What is an on-grid inverter used for?

An on-grid inverter, also known as a grid-tied inverter, is a key element of a photovoltaic installation integrated with the public power grid. Its basic function is to convert direct current (DC) generated by the solar panels into alternating current (AC), which is compatible with the electricity grid. Thanks to this, solar energy can be used directly in the facility or transferred to the grid, which allows for reducing electricity bills or generating revenue from its sale.

The on-grid inverter also has the ability to monitor the grid, which is important for maintaining the security and stability of both the local system and the power grid. This device automatically adjusts the energy output parameters, ensuring their compliance with the technical requirements of the energy supplier, which is necessary for the efficient and proper functioning of the system.

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