在压缩点火发动机中使用纳米硼、柴油和生物柴油燃料以及氢气对燃烧特性的影响研究

Q1 Chemical Engineering

International Journal of Thermofluids Pub Date : 2025-05-01 DOI:10.1016/j.ijft.2025.101232

Volkan Sabri Kül, Selahaddin Orhan Akansu, Mehmet Sarıtaş, Happy Sinkala, Sebahattin Ünalan

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引用次数: 0

摘要

压缩点火（柴油）发动机是交通运输中最重要的部件。在环境保护和可持续发展方面，效率是柴油发动机的一个重要因素。因此，利用各种添加剂来提高柴油机的效率是一个重要的研究课题。在此背景下，在目前的研究中，通过在柴油中添加10%的生物柴油、50 ppm的纳米硼（纳米硼的粒径为20纳米）和氢（替代了柴油/B10燃料18%的能耗），创造了8种不同的燃料类型。一台重型柴油发动机使用这8种燃料，在650转/分的恒定发动机转速和200牛米的扭矩下运行。实验结果表明，添加50 ppm纳米硼的柴油热效率最高，热效率值为28.837%。在以标准柴油(D)为燃料进行的实验中，将所得热效率值与D_50ppmB和D_H2燃料进行比较，效率分别提高了1.95%和0.19%。另一方面，与B10_50ppmB、B10_H2、B10、B10_50ppmB_H2和D_50ppmB_H2燃料相比，效率分别降低0.99%、2.66%、2.75%、3.53%和5.38%。在纯柴油中添加50 ppm纳米硼，可使NO排放量提高3.15%。相反，当氢与所有燃料类型一起使用时，观察到NO排放显著减少。例如，使用纯柴油时NO排放值为3.62 g/kWh，使用d-H2混合燃料时NO排放值下降了32.6%，降至2.44 g/kWh。此外，使用B10（90%柴油+ 10%生物柴油）燃料时，NOx排放值为3.60 g/kWh，使用B10_H2燃料时，NOx排放值为2.53 g/kWh，下降了29.72%。本研究最重要的发现是纳米颗粒添加剂提高了热效率并减少了CO排放。在这项研究中，研究了柴油、生物柴油、氢和纳米硼燃料在不同组合下的燃烧。认为这种四元燃料混合物对文献有重要贡献。

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Investigation of the effect of utilisation of nano boron, diesel and biodiesel fuels with together hydrogen in a compression ignition engine on combustion characteristics

Compression ignition (diesel) engines are the most important element of transportation. Efficiency is a vital factor in diesel engines in terms of environmental protection and sustainability. Therefore, increasing the efficiency of diesel engines by using various additives is an important research topic. In this context, 8 different fuel types were created by adding 10 % biodiesel, 50 ppm nanoboron (nanoboron particle size 20 nm) and hydrogen (18 % of the energy consumption of Diesel/B10 fuels was replaced) to diesel fuel in the current study. A heavy-duty diesel engine was operated at a constant engine speed of 650 rpm and a torque of 200 Nm using these eight fuel types. As a result of the experiments, diesel fuel with 50 ppm nanoboron added produced the highest efficiency among all fuel types with a thermal efficiency value of 28.837 %. In the experiments carried out with standard diesel (D) fuel, when the thermal efficiency values obtained were compared with D_50ppmB and D_H2 fuels, an efficiency increase of 1.95 % and 0.19 % was achieved, respectively. On the other hand, when compared with B10_50ppmB, B10_H2, B10, B10_50ppmB_H2 and D_50ppmB_H2 fuels, an efficiency decrease of 0.99 %, 2.66 %, 2.75 %, 3.53 % and 5.38 % was attained, respectively. 50 ppm nano boron addition to pure diesel increased the NO emission rate by 3.15 %. On the contrary, a significant decrease was observed in NO emission when hydrogen was used with all fuel types. For example, the NO emission value, which was 3.62 g/kWh in the use of pure diesel, decreased by 32.6 % and dropped to 2.44 g/kWh in the d-H2 mixture. In addition, it was observed that the NOx emission value, which was 3.60 g/kWh when B10 (90 % diesel + 10 % biodiesel) fuel was used, decreased by 29.72 % to 2.53 g/kWh when B10_H2 fuel was used. The most important findings of this study are that the nanoparticle additive increased thermal efficiency and reduced CO emissions. In this study, the combustion of diesel, biodiesel, hydrogen and nanoboron fuels in various combinations was investigated. It is thought that this quaternary fuel mixture significantly contributed to the literature.

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