An overview of hydrogen fuel for vehicular application

Silva, Antônio Henrique da Fonseca Thomé da Monteiro; Carvalho, Leonardo de Oliveira; Melo, Tadeu Cavalcante Cordeiro de; Frank, Maria Helena Troise; Reis, Paulo Fernando Isabel dos; Villalobos, Pedro Ricchini

doi:10.4271/2008-36-0322

Cited by 1 publication

(1 citation statement)

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“…In Ref. [43], fraction of hydrogen by volume ranging around 20% proved to decrease the engine-out emission levels by about 20%. In the present work, a general reduction of bsTHC and THC engine-out emission ranging around 25% was registered.…”

Section: Flg 2 Average Combustion and Performance Parameters For An mentioning

confidence: 97%

Effects of H2 Addition to Compressed Natural Gas Blends on Cycle-to-Cycle and Cylinder-to-Cylinder Combustion Variation in a Spark-Ignition Engine

Baratta

D’Ambrosio

Misul

et al. 2014

Journal of Engineering for Gas Turbines and Power

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An experimental investigation and a burning-rate analysis have been performed on a production 1.4 liter compressed natural gas (CNG) engine fueled with methane-hydrogen blends. The engine features a pent-roof combustion chamber, four valves per cylinder, and a centrally located sparkplug. The experimental tests have been carried out in order to quantify the cycle-to-cycle and the cylinder-to-cylinder combustion variation. Therefore, the engine has been equipped with four dedicated piezoelectric pressure transducers placed on each cylinder and located by the spark plug. At each test point, in-cylinder pressure, fuel consumption, induced air mass flow rate, pressure, and temperature at different locations on the engine intake and exhaust systems as well as "engine-out" pollutant emissions have been measured. The signals related to engine operation have been acquired by means of a National Instruments PXI-DAQ system and software developed in house. The acquired data have then been processed through a combustion diagnostic tool resulting from the integration of an original multizone thermodynamic model with a computer-aided design (CAD) procedure for the evaluation of the burned-gas front geometiy. The diagnostic tool allows the burning velocities to be computed. The tests have been performed over a wide range of engine speeds, loads, and relative air-fuel ratios (up to the lean operation limit (WL)). For stoichiometric operation, the addition of hydrogen to CNG has produced a brake-specific fuel combustion (bsfc) reduction ranging between 2% and 7% and a brake-specific total unburned hydrocarbons (bsTHCs) decrease up to 40%. These benefits have appeared to be even higher for lean mixtures. Hydrogen has shown to significantly enhance the combustion process, thus leading to a sensibly lower cycle-to-cycle variability. Hydrogen addition has generally resulted in extended operation up to relative air-to-fuel ratio (RAFR) = J.8. Still, the LOL consistently varies depending on the considered cylinder.

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Section: Flg 2 Average Combustion and Performance Parameters For An mentioning

confidence: 97%