Experimental assessment and optimization of the performance of a biodiesel engine using response surface methodology

IF 4.6 3区 工程技术 Q2 ENERGY & FUELS Energy, Sustainability and Society Pub Date : 2024-06-05 DOI:10.1186/s13705-024-00447-2
Prasheet Mishra, Taraprasad Mohapatra, Sudhansu S. Sahoo, Biranchi N. Padhi, Nimay Chandra Giri, Ahmed Emara, Kareem M. AboRas
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Abstract

Background

Biodiesel is a renewable and ecofriendly fuel for internal combustion engines. However, fuel standards need to be adapted for efficiency and commercial use. This paper deals with a novel process of its production using a purification step that counters the high costs of production and experimental analysis using multiresponse optimization.

Methods

Soybean oil was chosen as a biodiesel of 5%, 10%, and 15% blend with common diesel fuel and is experimentally tested in a variable compression ratio compression ignition engine. The biodiesel is blended with common diesel fuel to run the engine without any modification in its setup, which also solves most of the operational problems. The functional relationship between the input parameters and the performance characteristics of the engine is evaluated by statistical response surface methodology using the Box–Behnken design model, which generates a design of experiment resulting in an optimum experimental run that reduces the overall cost of the experimental investigation. Uncertainty analysis is done to minimize the gap between the results considering the errors of each piece of equipment. Validation of the results is also carried out.

Results

The analysis of variance is used to measure the acceptability of the model and the competency of the model to predict output performance. The optimum value of input parameters which are obtained are 4.5 kg for the load, the compression ratio of 18, and B05 for the fuel blend, which results in maximum performance of brake power of 3 kW, minimum fuel consumption and emissions of CO and NOx, which are 0.39 kg/kWh, 0.01%, and 50 ppm.

Conclusions

Cost analysis reveals that biodiesel produced from the novel process of transesterification is reasonable as compared with the conventional process. It is also environmentally more sustainable, which cannot be ignored. This technique can be used in future research for cost-effective production fields such as combustion parameters and biofuels produced from waste, which need to be explored.

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利用响应面方法对生物柴油发动机的性能进行实验评估和优化
背景生物柴油是一种用于内燃机的可再生环保燃料。然而,为了提高效率和商业用途,需要调整燃料标准。本文论述了一种新的生物柴油生产工艺,该工艺采用了一个纯化步骤,以抵消高昂的生产成本,并使用多反应优化进行了实验分析。方法选择大豆油作为生物柴油,与普通柴油混合 5%、10% 和 15%,并在可变压缩比压燃发动机中进行了实验测试。生物柴油与普通柴油混合后,发动机运行时无需对设置进行任何改动,这也解决了大部分运行问题。输入参数与发动机性能特征之间的函数关系是通过统计响应面方法进行评估的,该方法使用 Box-Behnken 设计模型,可生成最佳实验运行的实验设计,从而降低实验研究的总体成本。考虑到每个设备的误差,进行了不确定性分析,以尽量缩小结果之间的差距。结果方差分析用于衡量模型的可接受性和模型预测输出性能的能力。得出的最佳输入参数值为:负载 4.5 千克、压缩比 18、混合燃料 B05,从而获得了 3 千瓦的最大制动功率、最低燃料消耗以及 0.39 千克/千瓦时、0.01% 和 50 ppm 的一氧化碳和氮氧化物排放量。它在环境方面的可持续性也不容忽视。这项技术可用于未来研究的成本效益生产领域,如燃烧参数和从废物中生产生物燃料,这些领域都有待探索。
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来源期刊
Energy, Sustainability and Society
Energy, Sustainability and Society Energy-Energy Engineering and Power Technology
CiteScore
9.60
自引率
4.10%
发文量
45
审稿时长
13 weeks
期刊介绍: Energy, Sustainability and Society is a peer-reviewed open access journal published under the brand SpringerOpen. It covers topics ranging from scientific research to innovative approaches for technology implementation to analysis of economic, social and environmental impacts of sustainable energy systems.
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