Design Of An Exhaust Gas Energy Recovery System For Internal Combustion Engines

Design of an Exhaust Gas Energy Recovery System for Internal Combustion Engines

Author : Abdallah Ali

Publisher :

Page : 121 pages

File Size : 46,66 MB

Release : 2016

Category :

ISBN :

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Book Description

The current research paper presents the experimental findings following exhaust runner heat exchanger tests as well as a realistic theoretical proof of concept for steam turbocharging by using said results. A preliminary heat analysis was completed in order to first assess the magnitude of recoverable energy from the spent exhaust gases. Through experimentation, actual heat absorbed by the water was successfully obtained and was higher than predicted. The proof of concept was then completed by inputting the experimental engine parameters into a turbocharged Otto cycle combined to a Rankine cycle using experimental figures for the heat input stages of the assessment. The theory ultimately resulted in peak improvements of 7.446% in engine thermal efficiency and an interesting reduction in brake specific fuel consumption of 6.930% near 2500 RPM. Furthermore, through the use of steam turbocharging, brake engine power can theoretically be improved by 35.00%, resulting in a 13.73% increase in the current experimental engine’s power density. The test engine was mounted onto a hydraulic engine dyno and a baseline of its power and torque output was recorded for final confirmation that the heat recuperated via this energy recovery system was not being negated elsewhere in the combined cycle. Finally, a preliminary steam turbine was designed and the optimal system configuration was presented for future use. The obtained results clearly demonstrate that steam turbocharging is a novel energy recovery system with great potential.



Exhaust System Energy Management of Internal Combustion Engines

Author : M. Anusha Wijewardane

Publisher :

Page : pages

File Size : 46,52 MB

Release : 2012

Category :

ISBN :

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Book Description

Today, the investigation of fuel economy improvements in internal combustion engines (ICEs) has become the most significant research interest among the automobile manufacturers and researchers. The scarcity of natural resources, progressively increasing oil prices, carbon dioxide taxation and stringent emission regulations all make fuel economy research relevant and compelling. The enhancement of engine performance solely using incylinder techniques is proving increasingly difficult and as a consequence the concept of exhaust energy recovery has emerged as an area of considerable interest. Three main energy recovery systems have been identified that are at various stages of investigation. Vapour power bottoming cycles and turbo-compounding devices have already been applied in commercially available marine engines and automobiles. Although the fuel economy benefits are substantial, system design implications have limited their adaptation due to the additional components and the complexity of the resulting system. In this context, thermo-electric (TE) generation systems, though still in their infancy for vehicle applications have been identified as attractive, promising and solid state candidates of low complexity. The performance of these devices is limited to the relative infancy of materials investigations and module architectures. There is great potential to be explored. The initial modelling work reported in this study shows that with current materials and construction technology, thermo-electric devices could be produced to displace the alternator of the light duty vehicles, providing the fuel economy benefits of 3.9%-4.7% for passenger cars and 7.4% for passenger buses. More efficient thermo-electric materials could increase the fuel economy significantly resulting in a substantially improved business case. The dynamic behaviour of the thermo-electric generator (TEG) applied in both, main exhaust gas stream and exhaust gas recirculation (EGR) path of light duty and heavy duty engines were studied through a series of experimental and modelling programs. The analyses of the thermo-electric generation systems have highlighted the need for advanced heat exchanger design as well as the improved materials to enhance the performance of these systems. These research requirements led to the need for a systems evaluation technique typified by hardware-in-the-loop (HIL) testing method to evaluate heat exchange and materials options. HIL methods have been used during this study to estimate both the output power and the exhaust back pressure created by the device. The work has established the feasibility of a new approach to heat exchange devices for thermo-electric systems. Based on design projections and the predicted performance of new materials, the potential to match the performance of established heat recovery methods has been demonstrated.



Automotive Exhaust Emissions and Energy Recovery

Author : Apostolos Pesiridis

Publisher : Nova Science Pub Incorporated

Page : 269 pages

File Size : 31,92 MB

Release : 2014-01-01

Category : Science

ISBN : 9781633214934

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Book Description

Concerns for fuel economy and reduced emissions have turned the attention of automotive internal combustion engine manufacturers to the exhaust system and towards technological system development to account for the significant levels of potential energy that can be recovered. The present volume on Automotive Exhaust Emissions and Energy Recovery for both gasoline and diesel engines is therefore both timely and appropriate. Whereas diesel engines have been predominantly turbocharged, only a relatively small percentage of gasoline engines are similarly equipped, which has led to significant efforts by engine manufacturers in recent years to downsize and down-speed these engines. On the other hand, the relative focus in diesel engine development in terms of emissions and exhaust energy recovery has shifted toward devices other than the turbocharger for enhanced energy recovery and emissions control technologies in order to allow the diesel engines of the future to keep up with the dual-demand for very low emissions and increasing levels of fuel economy. The book focuses on the exhaust system and the technologies and methods used to reduce emissions and increase fuel economy by capitalising on the exhaust gas energy availability (either in the form of gas kinetic energy or as waste heat extracted from the exhaust gas). It is projected that in the short to medium term, advances in exhaust emissions and energy recovery technologies will lead the way in internal combustion engine development and pave the way towards increasing levels of engine hybridisation until fully electric vehicle technology can claim a level of maturity and corresponding market shares to turn the bulk of this focus away from the internal combustion engine. This book is aimed at engine research professionals in the industry and academia, but also towards students of powertrain engineering. The collection of articles in this book reviews the fundamentals of relevance, recent exhaust system technologies, details recent or on-going projects and uncovers future research directions and potentials.







On the Improvement of Combustion Engines with Waste Heat Recovery Systems in Mobile Applications

Author : Thomas Matousek

Publisher : Logos Verlag Berlin GmbH

Page : 132 pages

File Size : 18,44 MB

Release : 2019-08-10

Category : Science

ISBN : 3832549560

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Book Description

This dissertation deals with the experimental and simulative investigation of waste heat recovery from combustion engine exhaust gas in passenger car applications. The focus of the investigations lies on the thermodynamic cycle according to Rankine. The boundary conditions of combustion engines and the limitations of an automobile cause new operating conditions and system operating parameters for Rankine-systems, which will be discussed within this work. The system operating parameters were judged based on their potential to improve the efficiency of a running system, by setting the optimal values for each individual situation. Alternative circuit variants were investigated alongside of the basic configuration, which allowed additional heat input into the system and thereby increase the power output of the Rankine-system. Another operative influence on a waste heat recovery system that was analyzed was the importance of engine operating parameters. This on one hand lays groundwork and on the other hand displays the potentials of different system combinations. The knowledge gained during stationary operation is transferred to dynamic operation in the following. Cold start was chosen as the most important variant of dynamic operation. Results from measurements at starting temperatures down to -10C are presented. These include the first published measurements of temperature and power output for such scenarios. The basics of the behavior of a Rankine-system in cold start are extended by the impact of system operating parameters and circuit configurations. Possible synergies through different kinds of connection from the condenser to the coolant system were investigated as a completing facet of the holistic system view. The target of these investigations was to identify potentials for improvements in the cold start of the automobile by utilizing the heat that is available at the condenser.



Exhaust Gas-Thermic Fluid Heat Recovery Unit For Diesel Generator Set

Author : Jignesh R. Mehta

Publisher : LAP Lambert Academic Publishing

Page : 76 pages

File Size : 21,47 MB

Release : 2014-07-22

Category :

ISBN : 9783659576782

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Book Description

Energy conservation is equivalent to energy generation and transmission at 100% efficiency. Combined heat and power (CHP) is an important concept as fuel is used to generate two different forms of energy simultaneously. This book reports a project done at a bottle-cap manufacturing company, where a diesel generating set is employed as backup source of electrical energy. The possibility of using heat from exhaust gases to heat thermic fluid is explored. The design process for the heat recovery heat exchanger and other components is presented. The hot thermic fluid can be used for process heating for making the bottle-caps. It is estimated that around 50 kW heat can be recovered using a shell and tube heat exchanger for the 125 KVA diesel generator set. The payback period is around 480 days. This work thus demonstrates feasibility of such CHP system for process industries. It would also help people in the trade to design such system and also evaluate them.





Organic Rankine Cycle Technology for Heat Recovery

Author : Enhua Wang

Publisher : BoD – Books on Demand

Page : 202 pages

File Size : 16,54 MB

Release : 2018-11-07

Category : Science

ISBN : 1789843472

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Book Description

This book on organic Rankine cycle technology presents nine chapters on research activities covering the wide range of current issues on the organic Rankine cycle. The first section deals with working fluid selection and component design. The second section is related to dynamic modeling, starting from internal combustion engines to industrial power plants. The third section discusses industrial applications of waste heat recovery, including internal combustion engines, LNG, and waste water. A comprehensive analysis of the technology and application of organic Rankine cycle systems is beyond the aim of the book. However, the content of this volume can be useful for scientists and students to broaden their knowledge of technologies and applications of organic Rankine cycle systems.



Advances in Internal Combustion Engine Research

Author : Dhananjay Kumar Srivastava

Publisher : Springer

Page : 346 pages

File Size : 45,91 MB

Release : 2017-11-29

Category : Technology & Engineering

ISBN : 9811075751

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Book Description

This book discusses all aspects of advanced engine technologies, and describes the role of alternative fuels and solution-based modeling studies in meeting the increasingly higher standards of the automotive industry. By promoting research into more efficient and environment-friendly combustion technologies, it helps enable researchers to develop higher-power engines with lower fuel consumption, emissions, and noise levels. Over the course of 12 chapters, it covers research in areas such as homogeneous charge compression ignition (HCCI) combustion and control strategies, the use of alternative fuels and additives in combination with new combustion technology and novel approaches to recover the pumping loss in the spark ignition engine. The book will serve as a valuable resource for academic researchers and professional automotive engineers alike.