Laserfiche WebLink
Y.Ando et aL lZmergy 30(2005)2206-2218 2213 <br /> —Qat t9A�.014431 <br /> , 0.8 ----oss2 91t. <br /> —mt�al pe af.S <br /> 0.6 ,y <br /> Phar a in <br /> 0.4 w E <br /> g Ph ase 11 <br /> 0.0 <br /> x •0.2 Plies e 1 <br /> -60 .30 0 30 60 90 <br /> C"nk Angle(dq.ATDCI <br /> Fig. 10.Comparison of ennwtedve bew release se6edules for dithrem fuels at 100%WOT,1.0 air exoeas repo,hfflT timing, <br /> engine speed-2000 ming.'s—compmssion ratio,"AIDC(Atter Top Dead Center)••crank angle, <br /> As shown in Fig. 6, even in the stable range, combustion efficiency is less than 93%. This can be <br /> ascribed to the following reason.Quenching distances from a wall for hydrogen and methane arc shown <br /> in Pig.9[2].It is obvious that methane doesn't burn near a wall.Furthermore it is believed that existence <br /> of diluents makes quenching distance of methane longer than hydrogen. <br /> In general,the addition of hydrogen to gaseous filet showed little improvements of combustion on the <br /> fuel-rich side,but great improvements on fuel-lean side[3]. <br /> 3.2.2. Neat release <br /> Normalized cumulative heat release profiles of the stoichiometric mixtures of each fuel gas at WOT, <br /> minimum advance for best torque(MBT),2000 min-1 are shown in Fig. 10 Values are normalized with <br /> respect to the input energy,so that values less than one at the end of combustion correspond to unburned <br /> components and heat loss to wall. Ignition timings for each fuel gas are also noted in Fig. 10. <br /> Combustion can be divided into three phases: Phase I(the flame development phase=ignition delay), <br /> Phase II(the flame propagation phase),and Phase III(the!lame extinguishment phase)[4].Dashed lines <br /> identify each phase. <br /> Gradient of Phase II denotes combustion speed,therefore steeper gradient means higher combustion <br /> speed.By comparing gradients for each gas,it can be seen that the quickest combustion was combustion <br /> of Gas 2. This fact is contradictory to what we expect from CP. This reason may be attributed to <br /> differences in the compression ratio.Generally,increase of compresdOn ratio makes combustion speed <br /> faster,owing to increases in temperature and turbulence,and resulting in reduction of residual gas.In the <br /> case of Gas 2,compkasion ratio was greatest as 11.9,and the results of Fig. 10 indicate that increasing t <br /> compression ratios can improve the combustion of Phase II. <br /> In Phase III,compared with the sudden termination in the burning of Gas 2,combustion of Das 1 was <br /> longer and burned well.It is believed that this is due to the affect of wide flammable range of hydrogen. <br /> In LPhase I, long ignition delay of Gas 2 is very remarkable.Fig. 11 compares the cases at the same [ <br /> ignition advance.Ignition delay for Gas 2 is obviously long.This is caused by the following reasons.The <br /> transfer of spark energy to the fuel components is decreased by the presence of diluents,and combustible <br />