A Mid-Infrared Laser Absorption Sensor for Gas Temperature and Carbon Monoxide Mole Fraction Measurements at 15 kHz in Engine-Out Gasoline Vehicle Exhaust

IF 1.1 Q3 TRANSPORTATION SCIENCE & TECHNOLOGY
Joshua W. Stiborek, Ryan J. Tancin, Nathan J. Kempema, J. Szente, Michael J. Loos, C. Goldenstein
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引用次数: 1

Abstract

Quantifying exhaust gas composition and temperature in vehicles with internal combustion engines (ICEs) is crucial to understanding and reducing emissions during transient engine operation. This is particularly important before the catalytic converter system lights off (i.e., during cold start). Most commercially available gas analyzers and temperature sensors are far too slow to measure these quantities on the timescale of individual cylinder-firing events, thus faster sensors are needed. A two-color mid-infrared (MIR) laser absorption spectroscopy (LAS) sensor for gas temperature and carbon monoxide (CO) mole fraction was developed and applied to address this technology gap. Two quantum cascade lasers (QCLs) were fiber coupled into one single-mode fiber to facilitate optical access in the test vehicle exhaust. The QCLs were time-multiplexed in order to scan across two CO absorption transitions near 2013 and 2060 cm–1 at 15 kHz. This enabled in situ measurements of temperature and CO mole fraction to be acquired at 15 kHz in the engine-out exhaust of a research vehicle (modified production vehicle) with an 8-cylinder gasoline ICE. Three different vehicle tests were characterized with the LAS sensor as follows: (1) cold start with engine idle, (2) warm start with a drive cycle on a chassis dynamometer, and (3) hot start with a drive cycle on a chassis dynamometer. The measurements obtained from the LAS sensor had a time resolution that was three orders of magnitude faster than that of thermocouple and gas analyzer data acquired at the Ford vehicle emissions research laboratory (VERL) in Dearborn, Michigan. This enabled the LAS sensor to resolve high-speed engine dynamics and exhaust gas transients, which the conventional instrumentation could not, thereby providing valuable insight into the evolution of ICE emissions during transient engine operation.
中红外激光吸收传感器在15 kHz时测量发动机熄火汽油车尾气中的气体温度和一氧化碳摩尔分数
量化内燃机车辆的废气成分和温度对于了解和减少发动机瞬态运行时的排放至关重要。在催化转化器系统熄灯之前(即冷启动期间),这一点尤为重要。大多数商用气体分析仪和温度传感器都太慢,无法在单个气缸燃烧事件的时间尺度上测量这些量,因此需要更快的传感器。为了解决这一技术空白,开发了一种用于测量气体温度和一氧化碳摩尔分数的双色中红外(MIR)激光吸收光谱(LAS)传感器。两个量子级联激光器(qcl)光纤耦合成一个单模光纤,以方便在测试车辆尾气中的光接入。qcl进行了时间复用,以便在2013和2060 cm-1附近的两个CO吸收跃迁中扫描,频率为15 kHz。这使得使用8缸汽油内燃机的研究车辆(改装的生产车辆)的发动机排气在15 kHz时获得温度和CO摩尔分数的现场测量成为可能。利用LAS传感器进行了三种不同的车辆试验:(1)发动机怠速冷启动,(2)在底盘测功机上进行热启动,(3)在底盘测功机上进行热启动。从LAS传感器获得的测量结果的时间分辨率比在密歇根州迪尔伯恩的福特汽车排放研究实验室(VERL)获得的热电偶和气体分析仪数据快三个数量级。这使得LAS传感器能够解决高速发动机动力学和废气瞬态问题,这是传统仪器无法做到的,从而为发动机瞬态运行期间内燃机排放的演变提供了有价值的见解。
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来源期刊
SAE International Journal of Engines
SAE International Journal of Engines TRANSPORTATION SCIENCE & TECHNOLOGY-
CiteScore
2.70
自引率
8.30%
发文量
38
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