At Trinasolar Spain Systems, we are developers, owners, and operators of energy assets in the Spanish country, contributing to accelerating the challenge of net-zero emissions.
Our main goals are not only to develop our projects but also to create synergies with the people, take care of them, and be the partner you’ve always wanted to change the vision of renewable energies.
Our team is constantly growing, being a fundamental part of the core of the activity in Europe and being a reference for our units in Europe.
We truly believe in a green future and our objective is to contribute, bearing in mind the difficulty, to reduce emissions, preserve natural and local resources, boost the economy, and help to create a sustainable environment.
About our activity, we are present in the full lifetime cycle of renewables systems, since the very first step, the origination of the projects, going through the construction and operation and maintenance of assets, always going ahead with the values of the company
Local: Boosting economic growth of rural and industrial areas, preserving the local culture and landscape characteristics.
Supply: Enhance electric supply in areas with poor connection or high demand.
Environment: Reach Net Zero Emission, reducing usage of fossil fuels and collaborating with public and private entities to ensure the maintenance of the different ecosystems.
Preservation: Clean and secure electricity to maintain the wellness of our ecosystems, allowing the ground to regenerate from past activities, securing and enhancing the fauna.
At Trina Solar Spain Systems, we are always concerned about market evolution, looking for best solutions and innovative systems.
The fast grow of PV systems in Spain demands the development of BESS and Hybridised projects, giving us the challenge of being a leader in batteries’ sector.
We also didn’t leave aside the opportunity of the fast growth Hydrogen market. At Trina Spain we recently signed a co-development with Arbro to develop a Green Hydrogen Project in Huelva which will be operating in 2027 with an estimated annual production of 20,000 tons of green hydrogen
9,868 Megawatt Hours of renewable energy supplied per year (est)
4,820 homes powered per year
3,750 tonnes of carbon emissions saved
Equivalent to 84,466 miles of electrical car charge per day (est)
10,857 Megawatt Hours of renewable energy supplied per year (est)
5,303 homes powered per year
4,125 tonnes of carbon emissions saved
Equivalent to 92,932 miles of electrical car charge per day (est)
8,150 Megawatt Hours of renewable energy supplied per year (est)
3,981 homes powered per year
3,097 tonnes of carbon emissions saved
Equivalent to 69,760 miles of electrical car charge per day (est)
10,119 Megawatt Hours of renewable energy supplied per year (est)
4,943 homes powered per year
3,845 tonnes of carbon emissions saved
Equivalent to 86,621 miles of electrical car charge per day (est)
10,027 Megawatt Hours of renewable energy supplied per year (est)
4,898 homes powered per year
3,810 tonnes of carbon emissions saved
Equivalent to 85,832 miles of electrical car charge per day (est)
Solar panels convert sunlight into electricity using photovoltaic (PV) cells.
Yes, solar panels can still generate electricity during cloudy or rainy days, though at reduced efficiency. They rely on direct and diffuse sunlight, so they can produce energy even in less-than-ideal weather conditions.
Most solar panels have a lifespan of 25 to 30 years. Their efficiency may decrease slightly over time, but they typically remain effective for many years.
Most solar panels have a lifespan of 25 to 30 years. Their efficiency may decrease slightly over time, but they typically remain effective for many years.
Wind turbines do produce noise, which mainly comes from the rotating blades and mechanical components. However, modern turbines are designed to minimize noise, and the sound is usually comparable to that of a refrigerator or air conditioning unit from a distance.
Key factors include wind speed and consistency, local regulations and zoning, turbine size and type, and potential impacts on wildlife and the environment. Site assessment and expert consultation are essential.
Battery storage systems store electrical energy for later use. They charge during periods of excess electricity generation (e.g., sunny or windy days) and discharge when demand is high or renewable generation is low, helping to balance the energy supply.
Common types of batteries used in energy storage include lithium-ion, lead-acid, and flow batteries. Lithium-ion batteries are the most popular due to their high energy density, long life, and efficiency.
