A. Rastogi, Fluor Daniel India Private Ltd., New Delhi, India
Green hydrogen (H2) has been in the news often lately and is the trendiest clean energy source globally. Many countries are focusing on renewable energy sources and green H2 in a bid to cut carbon emissions worldwide to meet net zero by 2050. Presently, few green H2 plants are in operation or are at the pre-commercial phase with limited electrolyzer capacity (typically < 50 MW). Their contribution is less than 1% of the total H2 produced globally—most H2 is produced from unabated fossil fuels, with deleterious effects on the climate. Global H2 production is equivalent to about 3% of global final energy demand with a negligible contribution of green H2. The green H2 sector is at the nascent stage and must ramp up to mass scale production. However, a few barriers, such as high capital and operational expenditures (CAPEX and OPEX) and inefficiencies, must be conquered before mass scale production. This article addresses the challenges involved in the production of green H2 at a large scale.
Green H2 overview. Green H2 is produced by water electrolysis to split water (H2O) into H2 and oxygen (FIG. 1). Electricity from renewable energy sources—such as solar, hydro or wind power—is used in this production method, emitting zero-carbon dioxide (CO2) throughout the entire production process.
Challenges in the mass production of green H2. Hurdles to be overcome include:
Takeaway. Green H2 is a clean renewable fuel that releases no greenhouse gases (GHG). However, its viability is subject to its cost and efficiency. High CAPEX and OPEX cost—including the high cost of renewable energy—make green H2 2–3 times more expensive than H2 produced using other technologies. Also, the present low efficiency of green H2 technology makes it less favorable compared to other fuels and electricity. These factors will further ramp up the scaling of a H2 production facility. In the current scenario, it would be beneficial to use renewable power directly rather than using it (52.5 kWhr) to produce 1 kg of H2, which holds 39.4 kWhr of energy. Presently, green H2 is not yet commercially attractive, but advanced technologies, improved efficiency and decreasing renewable energy prices will definitely make it a commercially viable clean energy source in the future. H2T
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ANUJ RASTOGI is a Mechanical Engineer with Fluor Daniel India Private Ltd. New Delhi and has been with the company for 12 yr. He has more than 18 yr of experience in packaged equipment and holds a B.Eng degree in mechanical engineering. The author can be reached at anuj.rastogi@fluor.com.