STORING RENEWABLE ENERGIES IN A SUBSTITUTE OF NATURAL GAS

This paper proposes a way to obtain valuable electric power and valuable fuel starting from renewable variable electric power plus biomass and/or waste products. Biomass/biofuel can be oxyburned using electrolytic oxygen to generate electric power. Gas turbines or internal combustion engines are suitable to such a task, but there is the problem of very high temperatures connected to oxy combustion. In the case of gas turbine the inlet temperature could be controlled by adding steam and/or carbon dioxide, while in the case of internal combustion engines only carbon dioxide could be used. In such a way the exhaust gas continues to be formed by carbon dioxide and steam which can be easily separated by condensation. Carbon dioxide is fed to a Sabatier process together with electrolytic hydrogen to generate a gas with characteristics similar to natural gas. Although electrolytic hydrogen could be used directly both in internal combustion engines and fuel cells, significant problems to hydrogen distribution and on-board storing still exists. Therefore the substitute of natural gas could be a real bridge solution for the short/medium term. A  simulation has been carried out and the resulting efficiencies range from 0.52 to 0.58.

1. [1] Melaina M.W., Antonia O., Penev M. Blending hydrogen into natural gas pipeline networks: a review of key issues. Technical Report NREL/TP-5600-51995. March 2013.

2. [2] Akansu S.O., Dulger Z., Kahranman N., Veziroglu N.T. Internal combustion engines fueled by natural gas-hydrogen mixtures. Int. J. Hydrogen. Energy, 2004;29:1527–39; http://dx.doi.org/10.1016/j.ijhydene.2004.01.018.

3. [3] Roldan C., Spazzafumo G., Zamora J.P. Costa Rica: potential production of renewable methane/ hydrogen mixtures for vehicles. In: Proc. Of HYPOTHESIS IX, San José (Costa Rica); December 2011.

4. [4] Hoekman S.K., Broch A., Robbins C., Purcell R. CO2 recycling by reaction with renewably-generated hydrogen. Int. J. Greenh. Gas Control, 2010;4:44–50; http://dx.doi.org/10.1016/ j.ijggc.2009.09.012.

5. [5] Spazzafumo G. South Patagonia: wind/hydrogen/coal system with reduced CO2 emissions. Int. J. Hydrogen Energy, 2013;38:7599–604; http://dx.doi.org/10.1016/ j.ijhydene.2012.08.152.

6. [6] Buceti G., Capobianco D., Spazzafumo G., Tosti S. Wind & coal to generate a substitute of natural gas by hydro-gasification. In: Book of extended abstracts HYPOTHESIS XI, Toledo (Spain); September 2015. Available on: www.hypothesis.ws.

7. [7] Buceti G., Capobianco D., Spazzafumo G., Tosti S. Wind & coal to generate a substitute of natural gas using electrolytic hydrogen and oxygen. In: Book of

8. extended abstracts HYPOTHESIS XI, Toledo (Spain); September 2015. Available on: www.hypothesis.ws.

9. [8] From solid fuels to substitute natural gas (SNG) using TREMP™”. Availabke on: https://www.netl.doe.gov.

10. [9] Iantovski E., Ph. Mathieu. Highly efficient zero emission CO2-based power plant. In: Third intern. conf. on carbon dioxide removal (ICCDR-3), Boston; 1996.