- China’s Sinopec has commissioned their 300MW solar to hydrogen project in Kuqa City of Aksu Prefecture, Xinjiang Uygur Autonomous Region.
The mega hydrogen project, spearheaded by Sinopec’s New Star Company, is the largest solar-to-hydrogen project in the world and the first of its kind in China that is equipped with a photovoltaic power generation complex, power transmission and transformation lines, as well as facilities for water electrolysis hydrogen production, hydrogen storage and transportation, and supporting auxiliary production.
Green hydrogen is produced by facilities powered by renewable power sources such as solar and wind energy, minimizing the carbon footprint across the entire production process. The project takes advantage of the wealth of photovoltaic resources in Kuqa (300MW) to achieve 20,000 tons per annum of green hydrogen by using solar power to electrolyze water, along with the capacity to store 210,000 cubic meters of hydrogen and transport 28,000 cubic meters per hour.
As a demonstration project that serves to carve out a new path for green hydrogen refining and provide an exemplary model for green hydrogen production in China, the Project supplies hydrogen to Sinopec’s Tahe Refining & Chemical to remove its fossil fuel-based electricity used for hydrogen production, which is expected to help it reduce 485,000 tons of carbon dioxide emissions annually.
With a focus on hydrogen-powered transportation and green hydrogen refining, Sinopec aims to launch itself to become a new energy powerhouse that pioneers hydrogen production innovation in China, facilitating China and beyond to achieve low-carbon targets in the coming years. With an annual hydrogen production and utilization capacity exceeding 4.5 million tons, Sinopec’s self-developed megawatt-scale PEM electrolysis hydrogen production station has entered operation, and its first hydrogen demonstration project in the Inner Mongolia Autonomous Region, which is expected to produce 30,000 metric tons of hydrogen a year, has been launched in 2023.
Author: Bryan Groenendaal