Russia Solar Tracker Market Overview, 2030

Russia's solar tracker market faces specific obstacles and developments, largely due to the country's varied climate, notably the problem of snow accumulation on trackers. Tracker systems in Russia's northern and eastern regions can suffer mechanical stress and performance loss due to lengthy winters with considerable snowfall. In order to combat this, manufacturers and developers have created unique tilting mechanisms that allow trackers to move to more acute angles throughout the winter, allowing snow to slip off easily and avoiding structural harm. Some designs incorporate hydrophobic coatings or heating elements to prevent snow accumulation and ice formation. Most of the initial significant solar tracker installations in Russia were located in southern areas like Astrakhan, Stavropol, and the Republic of Kalmykia, where solar radiation levels are among the highest in the nation and snow-related problems are rare. These initial installations established the groundwork for indigenous knowledge in the deployment of tracker-based photovoltaic systems specifically designed for Russia's diverse environment. Tracker designs have been modified for extreme durability due to Russia's severe winters and significant temperature variations. They include reinforced frames, anti-corrosion treatments, and cold-resistant lubrication in moving parts. Tracker systems can function effectively in both temperate and subarctic regions thanks to these technological improvements. The incorporation of trackers into hybrid fossil-renewable systems is a crucial developing use in Russia. Trackers are used alongside diesel generators in several off-grid communities and isolated businesses in Siberia and the Russian Far East, which lowers fuel usage and emissions. Unique dual-axis trackers with solar PV and thermal hybrid configurations have started to be employed in experimental an Arctic station, which helps to provide power during the lengthy daylight hours in the summer. Solar trackers created for harsh conditions will be crucial as Russia's energy mix gradually diversifies, especially in helping remote energy independence and military or scientific facilities in harsh climes.

According to the research report, ""Russia Solar Tracker Market Overview, 2030,"" published by Bonafide Research, the Russia Solar Tracker market is anticipated to grow at more than 13.09% CAGR from 2025 to 2030. The solar tracker sector in Russia is expected to grow significantly over the next ten years, supported by government-funded renewable energy projects and increasing utility-scale solar capacity. As Russia shifts its energy policy away from fossil fuels, the market is poised to expand further, with installed solar capacity increasing from about 1.4 GW in 2020 to over 1.5 GW by 2021. The state's goal of diversifying its energy supply is demonstrated by the rollout of capacity supply agreements (CSAs) and the Renewable Energy Development Program (REDP), which includes subsidies and long-term support contracts for renewable projects. Russia's growing need to diversify away from fossil fuels is a major market driver, especially given international pressure to lower carbon emissions. Targeted programs in isolated locations, providing hybrid solar-diesel systems, seek to reduce diesel usage, improve energy security, and advance Russia's commitment to carbon neutrality by 2060. Solar trackers can be installed in both grid-connected and off-grid settings thanks to these programs. Domestic innovation has concentrated on creating trackers that are resistant to frost and snow and are suited for Russia's harsh environment. To guarantee dependability throughout harsh winters and thaw cycles, companies are incorporating tilt adjustment mechanisms, reinforced structures, anti-corrosion coatings, and cold-resistant lubricants. Hevel Solar, which has led a number of important projects, including an off-grid solar + storage facility in the Arctic area of Chukotka, is one of the most active contributors. Tracker systems in this installation lower diesel fuel consumption by 30%, which is a noteworthy achievement in harsh conditions. The installation of government-backed solar tracker projects in remote and Arctic areas, particularly through competitive bidding processes, is an emerging trend. To ensure a consistent power supply throughout the polar winter, these initiatives integrate PV, energy storage, and, in many cases, diesel generators in hybrid systems.

Russia's solar tracker industry by axis type is divided into Single-Axis Tracker and Dual-Axis Tracker. Single-axis trackers are the foundation of the majority of large-scale photovoltaic (PV) installations in the Russian solar tracker market, especially in the southern regions of the nation. Their flat terrain and relatively consistent sunshine exposure, areas like Astrakhan, Stavropol, and Kalmykia are ideal for horizontal single-axis trackers (HSAT). These systems are favored over fixed-tilt arrays because they are more economical, mechanically straightforward, and provide a consistent energy yield increase of 15–25%. Due to the ideal balance of performance and affordability for expanding renewable power production, Russian energy developers in these areas favor single-axis trackers. Furthermore, in semi-remote areas, hybrid projects that combine diesel generators with single-axis trackers are becoming more and more popular in an effort to lessen reliance on fossil fuels. Due to their capacity to accurately track the sun's azimuth and elevation throughout the day and year, dual-axis trackers are becoming increasingly popular in experimental facilities in Arctic regions and in Russia's northern territories. In areas where there are fewer daylight hours and significant seasonal variations, the capacity of these trackers to boost power production by up to 35–40% compared to stationary systems is a major benefit. Due to their flexibility, panels can adapt to the low-angle sunlight that is typical in wintertime or at high latitudes. Dual-axis trackers are essential for research installations, remote scientific facilities, and off-grid communities that must make the most of every kilowatt of solar energy produced, despite being more expensive and technically complicated. Local businesses and research institutions in Russia have created robust dual-axis trackers that can withstand frost, snow buildup, and harsh winter winds because of the country's harsh climate and varied topography. Dual-axis trackers are becoming strategically important for certain applications, particularly in high-latitude areas where maximizing generation from limited winter sunlight is critical, even if they are now a smaller market segment than single-axis systems.

In accordance with worldwide trends and Russia's unique renewable energy plan, the majority of the Russian solar tracker industry is dominated by solar photovoltaic (PV) technology. Particularly in areas like Astrakhan, Orenburg, and Kalmykia, where single-axis trackers are frequently used to optimize the already high solar irradiation, crystalline silicon PV modules are the most popular type of installation. Solar PV with trackers is a cost-effective and scalable solution, making it the cornerstone of Russia's solar energy development, particularly for utility-scale projects supported by state-backed incentives like capacity supply agreements (CSAs). Russian companies like Hevel Solar have made investments in cutting-edge heterojunction (HJT) PV cells, which boost energy conversion efficiency. This is especially beneficial in areas where the sunlight is diffused or at a low angle during Russia's extended winters. Although Concentrated Solar Power (CSP) technology has a great deal of potential for large-scale power generation in high-irradiance areas worldwide, its usage in Russia is still quite restricted. CSP has been kept in the background due to the nation's generally moderate solar resources outside the southernmost areas, the high capital expenses associated with CSP projects, and the government's focus on PV. However, hybrid CSP-PV ideas have been tested in a few cases, particularly when heat energy is also needed, such as in industrial applications or remote communities. The use of optics such as lenses or mirrors to focus sunlight on high-efficiency cells is known as concentrated photovoltaic (CPV). In Russia, particularly in research facilities and Arctic experimental stations, it has been utilized experimentally. When combined with dual-axis trackers, CPV provides the benefit of increased output in restricted areas, which is especially useful for off-grid applications or specialized setups in extreme conditions.

Solar Tracker Market in Russia by Installation Type is divided into Ground-Mounted and Rooftop-Mounted. The majority of projects in Russia's solar tracker market are ground-mounted installations, especially in utility-scale solar farms in the southern regions, such as Astrakhan, Stavropol, and Kalmykia. These areas have big stretches of underutilized, comparatively level land that is perfect for installing single-axis tracker systems. Ground-mounted systems are preferred for their ease of installation, maintenance accessibility, and ability to maximize sun exposure through the use of various tracker configurations. These systems are essential for advancing Russia's goals for renewable energy connected to the grid, particularly under initiatives such as the Renewable Energy Development Program (REDP). Ground-mounted trackers are becoming more prevalent in remote or off-grid hybrid systems in Siberia and the Far East, where they assist in lowering dependence on expensive diesel fuel for electricity production. In contrast, rooftop-mounted solar tracker setups are still uncommon in Russia, mostly because of financial and technological barriers. The majority of city rooftops are either not designed for dynamic tracking systems from an architectural standpoint or do not have the structural strength to handle the extra weight and motion that tracker installations need. Since rooftop trackers have higher installation and maintenance costs, and Russia has fluctuating solar conditions across many heavily populated areas, fixed-tilt rooftop PV is a more viable option for residential and commercial buildings. Nonetheless, there are specialized uses for rooftop trackers, notably in government pilot projects, research centers, and industrial complexes, where maximizing solar energy production is a top priority. Tailored dual-axis rooftop trackers have been utilized to efficiently collect little seasonal sunlight in northern or Arctic research stations.

Considered in this report
• Historic Year: 2019
• Base year: 2024
• Estimated year: 2025
• Forecast year: 2030

Aspects covered in this report
• Solar Tracker Market with its value and forecast along with its segments
• Various drivers and challenges
• On-going trends and developments
• Top profiled companies
• Strategic recommendation

By Technology
• Solar Photovoltaic (PV)
• Concentrated Solar Power (CSP)
• Concentrated Photovoltaic (CPV)

By Installation Type
• Ground-Mounted
• Rooftop-Mounted Show more