Performance and emissions characteristics of a lean-burn marine natural gas engine with the addition of hydrogen-rich reformate

The exhaust gas-fuel reforming technique known as reformed exhaust gas recirculation (REGR) can generate on-board hydrogen-rich gas mixture (i.e., reformate) by catalytic reforming of the exhaust gas and fuel added into the reformer and then recirculate the reformate into the engine cylinder, which can realize the combination of hydrogen-rich lean combustion and exhaust gas recirculation. The REGR technique can be employed to achieve efficient and stable lean-burn combustion for the marine engine fueled with natural gas (i.e., marine NG engine) and it is considered as an effective way to meet the stringent ship emissions regulations. In the present study, an experimental investigation into the effects of reformate addition ratio (R-re) and excess air ratio (lambda) on the combustion and emissions characteristics of a marine NG engine under various loads was conducted, and the potential of applying the REGR technique in a marine NG engine to achieve low emissions (i.e., International Maritime Organization Tier III emissions legislations for international ships) was discussed. The results indicate that the addition of the hydrogenrich reformate gases can extend lean-burn limit. For a given lambda, the flame development duration and rapid combustion duration decrease with the increase of R-re, and the combustion efficiency is improved. The brake specific NOx emissions first increase and then decrease with the increase of R-re due to the competition between the combustion phase and total heat release value. The brake specific THC emissions decline with the increase of R-re while the reverse holds for the brake specific CO emissions, and the behavior tends to be obvious under large lambda. It is demonstrated that the combination of REGR and the leanburn combustion strategy can improve the trade-off relationship between the NOx emissions and brake specific fuel consumption of the marine NG engine to meet the IMO Tier III NOx emissions legislations and maintain relatively low brake specific fuel consumption. (C) 2019 Hydrogen Energy Publications LLC. Published by Elsevier Ltd. All rights reserved.