Virtual sensor for air mass flow measurement in an SI engine: Application of distributed lumped modelling in prediction of air mass flow into the cylinder of SI combustion engines

After undergoing an extensive study about engine air mass flow measurement approaches as well as engine modelling for air mass flow prediction, a major problem found to exist is that engineers have still not found a suitable technique to accurately measure the air mass flow entering the cylinder of...

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Main Author: Filippou, Sotirios
Other Authors: Qi, Hong Sheng
Language:en
Published: University of Bradford 2019
Subjects:
Online Access:http://hdl.handle.net/10454/17450
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spelling ndltd-BRADFORD-oai-bradscholars.brad.ac.uk-10454-174502021-11-24T05:01:15Z Virtual sensor for air mass flow measurement in an SI engine: Application of distributed lumped modelling in prediction of air mass flow into the cylinder of SI combustion engines Filippou, Sotirios Qi, Hong Sheng Ebrahimi, Kambiz M. Engine air mass flow D-L modelling Transient engine testing After undergoing an extensive study about engine air mass flow measurement approaches as well as engine modelling for air mass flow prediction, a major problem found to exist is that engineers have still not found a suitable technique to accurately measure the air mass flow entering the cylinder of an internal combustion engine. The engine air mass flow is the most important parameter needed during engine development so the fuel control can be accurately calibrated and as a result increase performance and reduce emission output of an engine. The current methods used to determine the air mass flow lead to inaccuracies due to the large amount of mathematical assumptions and also sensor errors and as a result the mapping and calibration process of a new engine family takes approximately 2 years due to extensive modelling and testing required overcoming the above drawbacks. To improve this, the distributed lumped modelling technique (D-L) of the inlet manifold was chosen, where the intake system is separated into very small sections which are distributed continuously throughout the volume of the intake until entering the cylinder. This technique is validated against a CFD model of the engine’s intake system and real engine data as well as a 1D engine model. 2019-11-14T13:29:52Z 2019-11-14T13:29:52Z 2018 Thesis doctoral PhD http://hdl.handle.net/10454/17450 en <a rel="license" href="http://creativecommons.org/licenses/by-nc-nd/3.0/"><img alt="Creative Commons License" style="border-width:0" src="http://i.creativecommons.org/l/by-nc-nd/3.0/88x31.png" /></a><br />The University of Bradford theses are licenced under a <a rel="license" href="http://creativecommons.org/licenses/by-nc-nd/3.0/">Creative Commons Licence</a>. University of Bradford University of Bradford Faculty of Engineering and Informatics
collection NDLTD
language en
sources NDLTD
topic Engine air mass flow
D-L modelling
Transient engine testing
spellingShingle Engine air mass flow
D-L modelling
Transient engine testing
Filippou, Sotirios
Virtual sensor for air mass flow measurement in an SI engine: Application of distributed lumped modelling in prediction of air mass flow into the cylinder of SI combustion engines
description After undergoing an extensive study about engine air mass flow measurement approaches as well as engine modelling for air mass flow prediction, a major problem found to exist is that engineers have still not found a suitable technique to accurately measure the air mass flow entering the cylinder of an internal combustion engine. The engine air mass flow is the most important parameter needed during engine development so the fuel control can be accurately calibrated and as a result increase performance and reduce emission output of an engine. The current methods used to determine the air mass flow lead to inaccuracies due to the large amount of mathematical assumptions and also sensor errors and as a result the mapping and calibration process of a new engine family takes approximately 2 years due to extensive modelling and testing required overcoming the above drawbacks. To improve this, the distributed lumped modelling technique (D-L) of the inlet manifold was chosen, where the intake system is separated into very small sections which are distributed continuously throughout the volume of the intake until entering the cylinder. This technique is validated against a CFD model of the engine’s intake system and real engine data as well as a 1D engine model.
author2 Qi, Hong Sheng
author_facet Qi, Hong Sheng
Filippou, Sotirios
author Filippou, Sotirios
author_sort Filippou, Sotirios
title Virtual sensor for air mass flow measurement in an SI engine: Application of distributed lumped modelling in prediction of air mass flow into the cylinder of SI combustion engines
title_short Virtual sensor for air mass flow measurement in an SI engine: Application of distributed lumped modelling in prediction of air mass flow into the cylinder of SI combustion engines
title_full Virtual sensor for air mass flow measurement in an SI engine: Application of distributed lumped modelling in prediction of air mass flow into the cylinder of SI combustion engines
title_fullStr Virtual sensor for air mass flow measurement in an SI engine: Application of distributed lumped modelling in prediction of air mass flow into the cylinder of SI combustion engines
title_full_unstemmed Virtual sensor for air mass flow measurement in an SI engine: Application of distributed lumped modelling in prediction of air mass flow into the cylinder of SI combustion engines
title_sort virtual sensor for air mass flow measurement in an si engine: application of distributed lumped modelling in prediction of air mass flow into the cylinder of si combustion engines
publisher University of Bradford
publishDate 2019
url http://hdl.handle.net/10454/17450
work_keys_str_mv AT filippousotirios virtualsensorforairmassflowmeasurementinansiengineapplicationofdistributedlumpedmodellinginpredictionofairmassflowintothecylinderofsicombustionengines
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