Can the Middle East open the door to affordable clean hydrogen?

Image: Ghadir Shaar

A report by the International Renewable Energy Agency (IRENA) has suggested affordable green hydrogen could already be obtainable, based on the record-breaking low prices for solar negotiated in the Middle East.

Solar electricity tariffs of $0.0157, $0.0135 and $0.0104 per kilowatt-hour agreed in Qatar, the United Arab Emirates and Saudi Arabia, respectively, in the last 18 months, would enable renewables-powered hydrogen to be produced for as little as $1.62 per kilogram, according to IRENA's Renewable Power Generation Costs in 2020 report.

The Abu Dhabi-based international body made its calculations – all of which are in U.S. dollars – based on the $0.0104 solar power tariff agreed in Saudi Arabia in April, with green hydrogen generation being modeled at the Dumat al Jandal site in the kingdom which boasts strong solar and wind power resources. With the site already hosting a wind farm, IRENA modeled a hydrogen plant which would also harness solar and be connected to the grid. The report suggested lack of a grid connection would raise the renewable hydrogen cost to $1.74/kg, which still compares favorably to the current $1.45-2.40/kg price of hydrogen production powered by natural gas and equipped with carbon capture and storage (CCS) tech.

Further extrapolating the costs, the study estimated a fall in hydrogen electrolyzer costs, from $750 per kilowatt of capacity to $350, would enable renewable hydrogen production for $1.16/kg. Raising electrolyzer efficiency to 72.5% and extending stack lifetime from 15 to 17.5 on top of that, IRENA said, could take green hydrogen below the prized $1/kg point.

With this year's renewables price report explaining how the three tariffs secured in the Middle East since January 2020 can be regarded as viable without any hidden caveats or subsidy, the authors of the study stated: “low-cost renewable hydrogen may already be in reach.”

The document fleshed out how up to 800 GW of coal-fired power generation capacity worldwide could already be replaced by newly-built renewable energy facilities as solar and wind prices have dipped under the cost of running legacy fossil fuel plants in many markets. That estimate included a $5/MWh cost of integrating renewables into the electric grid and IRENA said, with around 40% of that overpriced capacity – and 37% of actual generation – based in Bulgaria, Germany, India and the United States, decommissioning could save around $32 billion per year in energy costs. Making the switch would also eliminate three gigatons of carbon emissions – 20% of what IRENA estimates is needed to keep global heating to a maximum 1.5 degrees Celsius this century.

The data

The latest edition of the report is based on data from around 20,000 renewables generation facilities worldwide which account for 1.9 TW of generation capacity, and on clean energy auction prices and power purchase agreements which add up to 582 GW of capacity. All the figures in the study exclude any form of subsidy and the authors point out, adding CCS to the world's overpriced coal plants would merely drive up their costs further.

IRENA has estimated all of Bulgaria and Germany‘s coal plants will this year cost electricity bill payers more than new renewables facilities would, based on a European carbon emissions price of €50 per ton. Even without an emissions trading scheme in the U.S. and India, the picture is similar, with 77-91% of American coal plants and 87-91% of Indian facilities also overpriced.

That conclusion is based on an estimated levelized cost of energy (LCOE) for solar power in India this year of $0.033/kWh, down from $0.038 last year; and of $0.031 in the States this year, although the report's authors note the solar module price has picked up between 1% and 9% in the first quarter of this year, thanks to shortages of raw materials such as polysilicon.

With the global LCOE of solar having fallen 7% from 2019 to last year, from $0.061 to $0.057/kWh, India led the world for low-price PV last year, with an average LCOE of $0.038/kWh for utility scale generation, ahead of China, with $0.044, and Spain, with $0.046. The authors noted Turkey also rapidly reduced average solar tariffs, to $0.052 last year, and Australia posted an average $0.057.

That translated into average solar project development costs of $596 per kilowatt installed in India, the world's lowest figure and down 8% from Indian costs in 2019. Solar projects in Vietnam came in to $949/kW and were only $796/kW in Spain last year, the report added. At the other end of the scale, projects in Russia cost $1,889/kW and, in Japan, $1,832, with those two countries exceptional among the 19 markets studied as the cost differences between areas from Canada (at $1,275/kW) down to India, were more evenly distributed.

Auction results posted last year, for projects expected to be commissioned this year and next, prompted IRENA to estimate the global average solar power price will fall to $0.039/kWh this year before rising slightly to $0.04 next year, which would still be a 30% fall on this year's figure and 27% less than the LCOE to be expected from new-build coal plants. With the predictions based on 18.8 GW of renewables capacity expected this year and 26.7 GW due in 2022, the study estimated 74% of the clean energy facilities expected this year and next will be cheaper than new fossil fuel generation sites.

Cheaper

Renewables are already making real headway, of course, with IRENA calculating 45.5 GW of the solar added last year was among the 62% of the 162 GW of clean energy facilities which were installed more cheaply than new-build coal plants.

Digging into the solar statistics, the report said mainstream solar panel costs in December ranged from $0.19 to $0.40 per Watt, for an average price of $0.27, with thin-film products averaging $0.28/W.

Operations and maintenance costs came in at an average of $17.80/kW last year in OECD countries and $9 elsewhere, in a year which also saw non-panel, balance-of-system equipment costs account for 65% of total project expense.

For residential solar arrays, average system prices in the 19 markets studied by IRENA ranged from $658/kW in India to $4,236 in California, for LCOE figures from $0.055/kWh in India to $0.236 in the U.K. For commercial systems, India was again the cheapest place to invest last year, at an average $651/kW, but a business in California would have to find $2,974/kW. Those system costs translated into LCOE numbers ranging between $0.055 in India and $0.19 in Massachusetts.

This article originally appeared on pv-magazine-usa.com, and has been republished with permission by pv magazine (www.pv-magazine.com and www.pv-magazine-usa.com).

The project includes the modification of two transport service stations to supply hydrogen.

Image: Griffith University

Chinese coal miner Baofeng Energy has announced the start of construction of what it claims will be the world’s largest solar-powered hydrogen plant, in the Ningxia Hui autonomous region of northwest China.

The RMB1.4 billion ($199 million) electrolysis project is intended to produce 160 million cubic meters of hydrogen per year plus 80 million cubic meters of oxygen. Baofeng said the use of solar electricity to power the facility would save 254,000 tons of coal consumption annually, leading to a 445,000-ton reduction in carbon emissions.

The project will feature two 10,000m³/hr electrolyzers powered by two 100 MW solar plants plus a 1,000kg/day hydrogenation station and two petrol stations will be converted to also supply natural gas and hydrogen for transport purposes. The solar panels will be installed over wolfberry and alfalfa crops which will generate extra revenue, according to Baofeng.

Work on the project started this month and is slated for completion this year, with hydrogen production to start next year.

Baofeng is also working on a coking co-generation plant to produce three million tons of coal-based coke per year, plus 1.2 billion cubic meters of hydrogen.

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This article originally appeared on pv-magazine-usa.com, and has been republished with permission by pv magazine (www.pv-magazine.com and www.pv-magazine-usa.com).

The project will be the first hydrogen injection experience in a real gas network in Spain with support for small-scale electrical storage, and will be carried out at the Enagás regasification plant in Cartagena.

Image: Enagás

Gas multinational Enagás and Ampere Energy, a Spain-based battery provider, have signed an agreement to begin joint production of hydrogen with solar power and energy stored in batteries.

The two companies will jointly work on several R&D projects to produce renewable hydrogen for self-consumption at the gas plant.

The project they are now planning will be the first hydrogen injection experience into a gas network in Spain, with small-scale storage as a back-up. It will be carried out at the regasification plant that Enagás operates in Cartagena, in the southern province of Murcia.

Ampere Energy has installed its Ampere Energy Square S 6.5 equipment at the Cartagena plant, which will have new storage and intelligent energy management solutions.

The installed equipment will allow Enagás to maximize the energy efficiency of the Cartagena gasification plant and reduce the environmental impact and its electricity bill up to 70%, according to the two companies.

The battery will store energy coming from both the photovoltaic system and the power grid, and will monitor this energy. Through machine learning algorithms and data analysis tools, the system will anticipate the consumption patterns of the plant, predict the available solar resource, and track prices in the electricity market, identifying the moments in which the cost is lower.

“This alliance opens the door to a long-term pact between Ampere Energy and Enagás to undertake joint R&D projects for energy storage and services,” both companies added.

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This article originally appeared on pv-magazine-usa.com, and has been republished with permission by pv magazine (www.pv-magazine.com and www.pv-magazine-usa.com).

The solar-powered hydrogen facility owned by Toshiba in Namie, Fukushima prefecture, Japan.

Image: Toshiba

Japanese conglomerate Toshiba Corporation has announced its Fukushima Hydrogen Energy Research Field (FH2R) project, on which construction began in July 2018, is operational.

The solar-powered 10 MW hydrogen plant in Namie town, Fukushima prefecture, is said to be able to produce 1,200 normal cubic meters (Nm³) of hydrogen per hour.

The intermittent nature of solar generation prompted Toshiba to design the facility to be able to adjust to supply and demand in the grid, the company said.

“Hydrogen produced at FH2R will also be used to power stationary hydrogen fuel cell systems and to provide for … mobility devices, fuel-cell cars and buses and more,” Toshiba added. “The most important challenge in the current stage of testing is to use the hydrogen energy management system to achieve the optimal combination of production and storage of hydrogen and power grid supply-demand balancing adjustments without the use of storage batteries.”

Solar power

The plant is being powered by 20 MW of solar generation capacity as well as grid power. The hydrogen generated is being transported in trailers and hydrogen bundles to users elsewhere in the prefecture as well as the Tokyo metropolitan area and other regions.

In early January, Toshiba commissioned the H2One Station Unit, an energy storage system producing hydrogen at the Toyama City Environment Center in Toyama prefecture. According to the company, that kind of installation can be deployed easily and operated by customers such as factories, harbors, airports and bus depots. A similar facility was deployed at the end of December in Tsuruga City, in the Hokuriku region.

Toshiba’s energy system and solutions business began a demonstration of an holistic hydrogen supply chain for electricity generation in May 2018.

The multinational had announced in February 2016 it would place more emphasis on its energy and storage businesses following an accounting scandal which had prompted a restructure and losses of around $6 billion in 2015.

This article was amended on 10/03/20 to reflect the claimed hourly hydrogen production capacity is measured in normal cubic meters rather than newton meters, as previously reported.

This article originally appeared on pv-magazine-usa.com, and has been republished with permission by pv magazine (www.pv-magazine.com and www.pv-magazine-usa.com).