The role of hydrogen for future internal combustion engines

Desantes JM Molina S Novella R , et al. Comparative global warming impact and NOx emissions of conventional and hydrogen automotive propulsion systems. Energy Convers Manag 2020; 221: 113137.

Reitz RD Ogawa H Payri R , et al. IJER editorial: the future of the internal combustion engine. Int J Engine Res 2020; 21(1): 3–10.

Kansu S Kahraman N Ceper B . Experimental study on a spark ignition engine fuelled by methane-hydrogen mixtures. Int J Hydrogen Energy 2007; 32(17): 4279–4284.

Sohret Y Gurbuz HA . Comparison of gasoline, liquid petroleum gas, and hydrogen utilization in a spark ignition engine in terms of environmental and economic indicators. J Energy Resour Technol 2021; 143(5): 052301.

Huang Z Liu B Zeng K , et al. Experimental study on engine performance and emissions for an engine fueled with natural gas-hydrogen mixtures. Energy Fuels 2006; 20(5): 2131–2136.

Catapano F Di Iorio S Sementa P Vaglieco BM . Analysis of energy efficiency of methane and hydrogen-methane blends in a PFI/DI SI research engine. Energy 2016; 117: 378–387.

Prasad RK Agarwal AK . Development and comparative experimental investigations of laser plasma and spark plasma ignited hydrogen enriched compressed natural gas fueled engine. Energy 2021; 216: 119282.

Li G Yu X Jin Z , et al. Study on effects of split injection proportion on hydrogen mixture distribution, combustion and emissions of a gasoline/hydrogen SI engine with split hydrogen direct injection under lean burn condition. Fuel 2020; 270: 117488.

Sarikoc S . Effect of H2 addition to methanol-gasoline blend on an SI engine at various lambda values and engine loads: a case of performance, combustion, and emission characteristics. Fuel 2021; 297: 120732.

Desantes JM Novella R Pla B , et al. Impact of fuel cell range extender powertrain design on greenhouse gases and NOx emissions in automotive applications. Appl Energy 2021; 302: 117526.

Simon JM . Heavy duty hydrogen ICE: Production realisation by 2025 and system operation efficiency assessment in Powertrain Systems for Net-Zero Transport. London: CRC Press, 2021.

Klepatz K Konradt S Tempelhagen R Rottengruber H . Systemvergleich CO2-freier Nutzfahrzeugantriebe [System comparison CO2-free commercial vehicle drives]. In: Berns K, Dressler K Kalmar R Stephan N Teutsch R Thul M . (eds) Commercial vehicle technology 2020/2021. Wiesbaden: Springer Vieweg. DOI: 10.1007/978-3-658-29717-6_13

Cantuarias-Villessuzanne C Weinberger B Roses L , et al. Social cost-benefit analysis of hydrogen mobility in Europe. Int J Hydrogen Energy 2016; 41(42): 19304–19311.

Frrankl S Gleis S Karmann S , et al. Investigation of ammonia and hydrogen as CO2-free fuels for heavy duty engines using a high pressure dual fuel combustion process. Int J Engine Res 2021; 22(10): 3196–3208.

Heid B Martens C Orthofer A . How hydrogen combustion engines can contribute to zero emissions. McKinsey report, 25 June 2021. McKinsey & Company. https://www.mckinsey.com

Koch D Eßer E Kureti S , et al. H2-DeNOx-Katalysator für H2-Verbrennungsmotoren. MTZ Motortech Z 2020; 81: 32–39.

Stepien Z . A comprehensive overview of hydrogen-fueled internal combustion engines: achievements and future challenges. Energies 2021; 14: 6504.

Beduneau JL Kawahara N Nakayama T , et al. Laser-induced radical generation and evolution to a self-sustaining flame. Combust Flame 2009; 156: 642–656.

Zheng J Liu X Xu P , et al. Development of high-pressure gaseous hydrogen storage technologies. Int J Hydrogen Energy 2012; 37: 1048–1057.

Schmitz N Burger J Ströfer E , et al. From methanol to the oxygenated diesel fuel poly(oxymethylene) dimethyl ether: an assessment of the production costs. Fuel 2016; 185: 67–72.

Oh SH Han JG Kim JM . Long-term stability of hydrogen nanobubble fuel. Fuel 2015; 158: 399–404.

Sun Y Xie G Peng Y , et al. Stability theories of nanobubbles at solid–liquid interface: a review. Colloids Surf A: Physicochem Eng Aspects 2016; 495: 176–186.

Ohgaki K Khanh NQ Joden Y , et al. Physicochemical approach to nanobubble solutions. Chem Eng Sci 2010; 65(3): 1296–1300.

Dharamshi K Pal A Agarwal AK . Comparative investigations of flame kernel development in a laser ignited hydrogen–air mixture and methane–air mixture. Int J Hydrogen Energy 2013; 38(25): 10648–10653.

Verhelst S . Recent progress in the use of hydrogen as a fuel for internal combustion engines. Int J Hydrogen Energy 2014; 39: 1071–1085.

White CM Steeper RR Lutz AE . The hydrogen-fueled internal combustion engine: a technical review. Int J Hydrogen Energy 2006; 31: 1292–1305

D’Errico G Onorati A Ellgas S . 1D thermo-fluid dynamic modelling of an S.I. Single-cylinder H2 engine with cryogenic port injection. Int J Hydrogen Energy 2008; 33(20): 5829–5841.

BMW. BMW hydrogen engine reaches top level efficiency. Munich, Germany: BMW, 2009

Salazar VM Kaiser SA Halter F . Optimizing precision and accuracy of quantitative PLIF of acetone as a Tracer for hydrogen fuel. SAE Int J Fuels Lubr 2009; 2: 737–761.

Kaiser S White C . PIV and PLIF to evaluate mixture formation in a direct-injection hydrogen-fuelled engine. SAE Int J Engines 2009; 1: 657–668.

Wallner T Scarcelli R Nande AM , et al. Assessment of multiple injection strategies in a direct-injection hydrogen research engine. SAE Int J Engines 2009; 2: 1701–1709.

Scarcelli R Wallner T Salazar VM , et al. Modeling and experiments on mixture formation in a hydrogen direct-injection research engine. SAE Int J Engines 2010; 2: 530–541.

Scarcelli R Wallner T Matthias N , et al. Mixture formation in direct injection hydrogen engines: CFD and optical analysis of single- and multi-hole nozzles. SAE Int J Engines 2011; 2: 2361–2375

Matthias NS Wallner T Scarcelli R . A hydrogen direct injection engine concept that exceeds U.S. DOE light-duty efficiency targets. SAE Int J Engines 2012; 5: 838–849

Wallner T Matthias NS Scarcelli R , et al. A Evaluation of the efficiency and the drive cycle emissions for a hydrogen direct-injection engine. J Automob Eng 2013; 227: 99–109.

Iafrate N Matrat M Zaccardi JM . Numerical investigations on hydrogen-enhanced combustion in ultra-lean gasoline spark-ignition engines. Int J Engine Res 2021; 22(2): 375–389.

Varde KS . Combustion characteristics of small spark ignition engines using hydrogen supplemented fuel mixtures. SAE paper 810921, 1981.

Bae C Kim J . Alternative fuels for internal combustion engines. Proc Combust Inst 2017; 36: 3389–3413.

Verhelst S Wallner T . Hydrogen-fueled internal combustion engines. Prog Energy Combust Sci 2009; 35: 490–527.

Li H Karim GA . Knock in spark ignition hydrogen engines. Int J Hydrogen Energy 2004; 29: 859–865.

Szwaja S Bhandary KR Naber JD . Comparisons of hydrogen and gasoline combustion knock in a spark ignition engine. Int J Hydrogen Energy 2007; 32: 5076–5087.

Kawahara N Tomita E . Visualization of auto-ignition and pressure wave during knocking in a hydrogen spark-ignition engine. Int J Hydrogen Energy 2009; 34: 3156–3163.

Chen Y Raine R . Engine knock in an SI engine with hydrogen supplementation under stoichiometric and lean conditions. SAE Int J Engines 2014; 7(2): 595–605.

Hoffmann G Dober G Piock WF Doradoux L Meissonnier G Cardon C , et al. BorgWarner’s injection system solutions for natural gas and hydrogen. In: Proceedings of 30th Aachen Colloquium Sustainable Mobility 2021. https://www.aachener-kolloquium.de/

Duffour F Walter B Ternel C , et al. Potential and challenges of the hydrogen internal combustion engine from experimental and numerical investigation. Plenary lecture at SIA Powertrain & Power Electronics Digital Edition 2021. Springer

Hasse C . Scale-resolving simulations in engine combustion process design based on a systematic approach for model development. Int J Engine Res 2016; 17: 44–62.

Peters N . Multiscale combustion and turbulence. Proc Combust Inst 2009; 32(1): 1–25.

Wen X Zirwes T Scholtissek A , et al. Flame structure analysis and composition space modeling of thermodiffusively unstable premixed hydrogen flame | Part I: atmospheric pressure. Combust Flame 2022; 111815. https://doi.org/10.1016/j.combustflame.2021.111815

Wen X Zirwes T Scholtissek A , et al. Flame structure analysis and composition space modeling of thermodiffusively unstable premixed hydrogen flame | Part II: elevated pressure. Combust Flame 2022, 111808. https://doi.org/10.1016/j.combustflame.2021.111808

Lee S Kim G Bae C . Behavior of hydrogen hollow-cone spray depending on the ambient pressure. Int J Hydrogen Energy 2021; 46: 4538–4554.

Lee S Kim G Bae C . Lean combustion of stratified hydrogen in a constant volume chamber. Fuel 2021; 301: 121045.

Roy MK Kawahara N Tomita E , et al. High-pressure hydrogen jet and combustion characteristics in a direct-injection hydrogen engine. SAE technical paper 2011-01-2003, 2011.

Shudo T Oba S . Mixture distribution measurement using laser induced breakdown spectroscopy in hydrogen direct injection stratified charge. Int J Hydrogen Energy 2009; 34: 2488–2493.

Schefer RW Kulatilaka WD Patterson BD , et al. Visible emission of hydrogen flames. Combust Flame 2009; 156: 1234–1241.

Lee S Kim G Bae C . Effect of injection and ignition timing on a hydrogen-lean stratified charge combustion engine. Int J Engine Res. Epub ahead of print 21 August 2021. DOI:10.1177/14680874211034682

Prasad RK Jain S Verma G , et al. Laser ignition and flame kernel characterization of HCNG in a constant volume combustion chamber. Fuel 2017; 190: 318–327.

Prasad RK Agarwal AK . Experimental evaluation of laser ignited hydrogen-enriched compressed natural gas-fueled supercharged engine. Fuel 2021; 289: 119788.

Verhelst S Maesschalck P Rombaut N , et al. Increasing the power output of hydrogen internal combustion engines by means of supercharging and exhaust gas recirculation. Int J Hydrogen Energy 2009; 34(10): 4406–4412.

Natkin R Tang X Boyer B , et al. Hydrogen IC engine boosting performance and NOx study. SAE technical paper 2003-01-0631, 2003.

Kim J Rajoo S . A numerical study on turbocharging system for PFI-SI type hydrogen combustion engine. SAE technical paper 2021-24-0094, 2021.

Nguyen D Choi Y Park C , et al. Effect of supercharger system on power enhancement of hydrogen-fueled spark-ignition engine under low-load condition. Int J Hydrogen Energy 2021; 46(9): 6928–6936.

Taghavifar H Nemati A Salvador FJ , et al. 1D energy, exergy, and performance assessment of turbocharged diesel/hydrogen RCCI engine at different levels of diesel, hydrogen, compressor pressure ratio, and combustion duration. Int J Hydrogen Energy 2021; 46(42): 22180–22194.

Gürbüz H Akçay IH . Evaluating the effects of boosting intake-air pressure on the performance and environmental-economic indicators in a hydrogen-fueled SI engine. Int J Hydrogen Energy 2021; 46(56): 28801–28810.

Savva PG Costa CN . Hydrogen lean-DeNOx as an alternative to the ammonia and hydrocarbon selective catalytic reduction (SCR). Catal Rev Sci Eng 2011; 53(2): 91–151.

Alghamdi NM Restrepo Cano J Anjum DH , et al. Hydrogen selective catalytic reduction of nitrogen oxide on pt- and pd-based catalysts for lean-burn automobile applications. SAE technical paper 2020-01-2173, 2020.

Borchers M Keller K Lott P Deutschmann O . Selective catalytic reduction of NOx with H2 for cleaning exhausts of hydrogen engines: impact of H2O, O2, and NO/H2 Ratio. Ind Eng Chem Res 2021; 60(18): 6613–6626.

Liu Z Li J Woo SI . Recent advances in the selective catalytic reduction of NOx by hydrogen in the presence of oxygen. Energy Environ Sci 2012; 10: 8799–8814.