Carlos Alberto Romero Piedrahita, Mauricio Monroy Jaramillo, Juan David Ramírez Alzate
{"title":"Test bench development and implementation for experimental determination of mechanical losses in single cylinder internal combustion engines","authors":"Carlos Alberto Romero Piedrahita, Mauricio Monroy Jaramillo, Juan David Ramírez Alzate","doi":"10.21303/2461-4262.2023.002847","DOIUrl":null,"url":null,"abstract":"As mechanical efficiency has great relevance in the alternative engine performance, the authors research in the development of testing facilities to characterize the sources of engine mechanical losses. The present paper deals with the realization of a hardware platform to conduct experimental studies in small combustion engines to experimentally characterize the mechanical losses of a single-cylinder internal combustion engine by means of the indicated diagram and motoring methods. The system was completed by means of an electrical motor-generator coupled to a single-cylinder air-cooled spark ignition engine, a self-developed electronic hardware control, and a PC-based instrumentation and data acquisition system. Specifications of load-motoring-starting system, including the description of the proprietary electronic load regulation system, are detailed. Also, the instrumentation system of in-cylinder and intake pressures; Temperatures of intake air, exhaust gases, lubricant oil, and engine block; effective torque and crankshaft position are described, including the signal acquisition system. The methodologies for indicated diagram and motoring method are described, mentioning the required measurements to apply each method and the engine load-temperature considerations when an engine is tested in fired or motored conditions. The platform was used to study the mechanical losses of the engine under motored and fired conditions under a wide range of rotational speeds and throttle openings, allowing to draw conclusions about the operating features of the developed test bench in itself, and also about the mechanical losses of the engine tested. Initially, samples of cylinder pressure, torque, intake pressure as function of crank angle and indicate diagram were obtained, showing similar waveforms present in related literature. Then, variations of the aforementioned temperatures against rotation speed and throttle opening and results for the mechanical losses determined by indicated diagram and motoring methods are shown. Finally, two empirical correlations are proposed to estimate the mechanical losses. In the future the hardware platform will be utilized to investigate in-cylinder engine parameters, detailed thermal and mechanical engine performance","PeriodicalId":11804,"journal":{"name":"EUREKA: Physics and Engineering","volume":null,"pages":null},"PeriodicalIF":0.0000,"publicationDate":"2023-11-30","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"EUREKA: Physics and Engineering","FirstCategoryId":"1085","ListUrlMain":"https://doi.org/10.21303/2461-4262.2023.002847","RegionNum":0,"RegionCategory":null,"ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"Q3","JCRName":"Engineering","Score":null,"Total":0}
引用次数: 0
Abstract
As mechanical efficiency has great relevance in the alternative engine performance, the authors research in the development of testing facilities to characterize the sources of engine mechanical losses. The present paper deals with the realization of a hardware platform to conduct experimental studies in small combustion engines to experimentally characterize the mechanical losses of a single-cylinder internal combustion engine by means of the indicated diagram and motoring methods. The system was completed by means of an electrical motor-generator coupled to a single-cylinder air-cooled spark ignition engine, a self-developed electronic hardware control, and a PC-based instrumentation and data acquisition system. Specifications of load-motoring-starting system, including the description of the proprietary electronic load regulation system, are detailed. Also, the instrumentation system of in-cylinder and intake pressures; Temperatures of intake air, exhaust gases, lubricant oil, and engine block; effective torque and crankshaft position are described, including the signal acquisition system. The methodologies for indicated diagram and motoring method are described, mentioning the required measurements to apply each method and the engine load-temperature considerations when an engine is tested in fired or motored conditions. The platform was used to study the mechanical losses of the engine under motored and fired conditions under a wide range of rotational speeds and throttle openings, allowing to draw conclusions about the operating features of the developed test bench in itself, and also about the mechanical losses of the engine tested. Initially, samples of cylinder pressure, torque, intake pressure as function of crank angle and indicate diagram were obtained, showing similar waveforms present in related literature. Then, variations of the aforementioned temperatures against rotation speed and throttle opening and results for the mechanical losses determined by indicated diagram and motoring methods are shown. Finally, two empirical correlations are proposed to estimate the mechanical losses. In the future the hardware platform will be utilized to investigate in-cylinder engine parameters, detailed thermal and mechanical engine performance
由于机械效率与替代发动机的性能密切相关,作者研究开发了测试设备,以确定发动机机械损失的来源。本文论述了在小型内燃机中进行实验研究的硬件平台的实现情况,以通过指示图和发动机方法对单缸内燃机的机械损耗进行实验表征。该系统由一个与单缸风冷火花点火发动机耦合的电动发电机、一个自主开发的电子硬件控制装置以及一个基于 PC 的仪器和数据采集系统组成。详细介绍了负载电机启动系统的规格,包括专有电子负载调节系统的说明。此外,还介绍了缸内压力和进气压力;进气、废气、润滑油和发动机缸体的温度;有效扭矩和曲轴位置的仪表系统,包括信号采集系统。介绍了指示图和发动机方法,提到了应用每种方法所需的测量值,以及发动机在点火或点火条件下进行测试时对发动机负荷-温度的考虑。该平台用于研究发动机在各种转速和节气门开度条件下,在起动和点火条件下的机械损耗,从而得出关于所开发测试台本身的运行特征以及所测试发动机机械损耗的结论。首先,获得了气缸压力、扭矩、进气压力与曲柄角度的函数关系样本和指示图,显示了相关文献中的类似波形。然后,显示了上述温度随转速和节气门开度的变化,以及通过指示图和驾驶方法确定的机械损失结果。最后,提出了两个经验相关系数来估算机械损耗。未来将利用该硬件平台研究发动机缸内参数、发动机的详细热性能和机械性能。