WEST LAFAYETTE, Ind. - Researchers are proposing a new "hydricity" concept aimed at creating a sustainable economy by not only generating electricity with solar energy but also producing and storing hydrogen from superheated water for round-the-clock power production.
"The proposed hydricity concept represents a potential breakthrough solution for continuous and efficient power generation," said Rakesh Agrawal, Purdue University's Winthrop E. Stone Distinguished Professor in the School of Chemical Engineering, who worked with chemical engineering doctoral student Emre Gençer and other researchers. "The concept provides an exciting opportunity to envision and create a sustainable economy to meet all the human needs including food, chemicals, transportation, heating and electricity."
Hydrogen can be combined with carbon from agricultural biomass to produce fuel, fertilizer and other products.
"If you can borrow carbon from sustainably available biomass you can produce anything: electricity, chemicals, heating, food and fuel," Agrawal said.
Findings are detailed in a research paper appearing this week (Dec. 14) in the online early edition of Proceedings of the National Academy of Sciences.
Hydricity uses solar concentrators to focus sunlight, producing high temperatures and superheating water to operate a series of electricity-generating steam turbines and reactors for splitting water into hydrogen and oxygen. The hydrogen would be stored for use overnight to superheat water and run the steam turbines, or it could be used for other applications, producing zero greenhouse-gas emissions.
"Traditionally electricity production and hydrogen production have been studied in isolation, and what we have done is synergistically integrate these processes while also improving them," Agrawal said.
The PNAS paper was authored by Gençer; former chemical engineering graduate student Dharik S. Mallapragada; Francois Marechal, a professor and chemical process engineer from Ecole Polytechnique Federale de Lausanne in Switzerland; Mohit Tawarmalani, a professor and Allison and Nancy Schleicher Chair of Management at Purdue's Krannert School of Management; and Agrawal.
In superheating, water is heated well beyond its boiling point - in this case from 1,000 to 1,300 degrees Celsius - producing high-temperature steam to run turbines and also to operate solar reactors to split the water into hydrogen and oxygen.
"In the round-the-clock process we produce hydrogen and electricity during daylight, store hydrogen and oxygen, and then when solar energy is not available we use hydrogen to produce electricity using a turbine-based hydrogen-power cycle," Tawarmalani said. "Because we could operate around the clock, the steam turbines run continuously and shutdowns and restarts are not required. Furthermore, our combined process is more efficient than the standalone process that produces electricity and the one that produces and stores hydrogen."
The system has been simulated using models, but there has been no experimental component to the research.
"The overall sun-to-electricity efficiency of the hydricity process, averaged over a 24-hour cycle, is shown to approach 35 percent, which is nearly the efficiency attained by using the best photovoltaic cells along with batteries," Gençer said. "In comparison, our proposed process stores energy thermo-chemically more efficiently than conventional energy-storage systems, the coproduced hydrogen has alternate uses in the transportation-chemical-petrochemical industries, and unlike batteries, the stored energy does not discharge over time and the storage medium does not degrade with repeated uses."
Agrawal said, "The concept combines processes already developed by other researchers while also improving on these existing processes. The daytime and night-time systems would use much of the same equipment, allowing them to segue seamlessly, representing an advantage over other battery-based solar technologies."
Note to Journalists: A copy of the research paper is available from Emil Venere, Purdue News Service, at 765-494-4709, email@example.com.
The research has been funded by the U.S. Department of Energy through the DOE's Center for Direct Catalytic Conversion of Biomass to Biofuels at Purdue's Discovery Park and through a "Solar Economy" project led by Agrawal under the National Science Foundation's Integrative Education and Research Traineeship Program.
Writer: Emil Venere, 765-494-4709, firstname.lastname@example.org
Hydricity: A Sunshine Route to Sustainability
Authors: Emre Gencer1, Dharik S. Mallapragada1, Francois Marechal2, Mohit Tawarmalani3,
Rakesh Agrawal 1*
1 School of Chemical Engineering, Purdue University
2 Industrial Process and Energy Systems Engineering Group, Ecole Polytechnique Federale de Lausanne, EPFL Valais Wallis, CP440, CH-1951 Sion, Switzerland
3 Krannert School of Management, Purdue University, West Lafayette, IN-47907, USA *Correspondence to: email@example.com
We introduce a new paradigm - hydricity - that involves the coproduction of hydrogen and electricity from solar thermal energy and their judicious use to enable a sustainable economy. We identify and implement synergistic integrations while improving each of the two individual processes. When the proposed integrated process is operated in a standalone solely power production mode, the resulting solar water power (SWP) cycle can generate electricity with unprecedented efficiencies of 40-46%. Similarly, in standalone hydrogen mode, pressurized hydrogen is produced at efficiencies approaching ~50%. In the coproduction mode, the coproduced hydrogen is stored for uninterrupted solar power production. When sunlight is unavailable, we envision that the stored hydrogen is used in a turbine-based hydrogen water power (H2WP) cycle with the calculated hydrogen-to-electricity efficiency of 65-70%, which is comparable to the fuel cell efficiencies. The H2WP cycle utilizes much of the same equipment as the SWP cycle reducing capital outlays. The overall sun-to-electricity efficiency of the hydricity process, averaged over a twenty-four hour cycle, is shown to approach ~35%, which is nearly the efficiency attained by using the best multijunction photovoltaic cells along with batteries. In comparison, our proposed process has the following advantages: (a) it stores energy thermo- chemically with a two- to three-fold higher density, (b) coproduced hydrogen has alternate usages in transportation/chemical/petrochemical industries, and (c) unlike batteries, the stored energy does not discharge over time and the storage medium does not degrade with repeated uses.