Ammonia Uniformity to Predict NOx Reduction Efficiency in an SCR System

The automotive industry has been restricted by several regulations to reduce nitrogen oxide emissions from diesel engines. To adhere to the emission regulation, advanced engine technology aims to control oxygen access, compression, and ignition engine, while achieving both reduced fuel consumption a...

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Bibliographic Details
Published inInternational journal of automotive technology Vol. 20; no. 2; pp. 313 - 325
Main Authors Wardana, Muhammad Khristamto Aditya, Shahariar, G. M. Hasan, Oh, Kwangchul, Lim, Ocktaeck
Format Journal Article
LanguageEnglish
Published Seoul The Korean Society of Automotive Engineers 01.04.2019
Springer Nature B.V
한국자동차공학회
Subjects
Algorithms
Ammonia
Automobiles
Automotive electronics
Automotive Engineering
Clustering
Contingency
Control equipment
Diesel engines
Electronic control
Emission standards
Energy consumption
Engineering
Microprocessors
Parallel processing
Partitioning
Performance enhancement
Priority scheduling
Processors
Scheduling
자동차공학
Wall impingement
Emission
uniformity
Diesel engine
NH
Selective catalytic reduction
Urea Water Solution (UWS)
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Summary:The automotive industry has been restricted by several regulations to reduce nitrogen oxide emissions from diesel engines. To adhere to the emission regulation, advanced engine technology aims to control oxygen access, compression, and ignition engine, while achieving both reduced fuel consumption and lowering unburnt HC, CO 2 , and CO levels. However, it is difficult to meet the NOx limits of the European standard (EURO VI) and American standard (US TIER 2 BIN 5). Selective catalytic reduction (SCR) with ammonia (NH 3 ) has been successfully employed to remove NOx from diesel engines. However, uniform ammonia distribution is usually difficult to achieve. Therefore, a study on ammonia uniformity to predict NOx reduction efficiency in SCR systems is needed. The engine utilized in the experiment was turned on for a few minutes to obtain the desired temperature and airflow, and the simulation was performed using a commercial code of STAR-CCM+. This study was performed at engine operating conditions of 1500 rpm, 2000 rpm, and 3000 rpm; simulation was performed with a fixed pressure and velocity, as in the experiment, thus creating a similar turbulent swirl flow in the SCR system. Numerical results were validated using experimental results of ammonia concentration distribution.
ISSN:1229-9138
1976-3832
DOI:10.1007/s12239-019-0031-x