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151-0251-00L 4 Credits MSC D-ITET , D-MAVT

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Principles, Efficiency Optimization and Future Applications of IC Engines

Lecturers & Examiners: PD Dr. Yuri Wright, Dr. Patrik Soltic

Note: previous course title until HS20 "IC-Engines: Principles, Thermodynamic Optimization and Future Applications".

VVZ CR n/a

Last Updated: 2026-02-05 15:48:12

Abstract

Future Relevance of IC engines for transportation and Power-on-Demand. Characteristic performance parameters, operating maps and duty cycles. Thermodynamic cycles and energetic optimization. In-cylinder flows, convective and radiative heat transfer, combustion modes, boosting and simulation methods. Hybrid powertrains, decentralized power/heat cogeneration and use of renewable/e-fuels.

Objective

The students get familiar with operating characteristics and efficiency maximization methods of IC engines for propulsion and decentralized electricity (and heat) generation. To this end, they learn about simulation methods and related experimental techniques for performance assessment in a combination of lectures and exercises.

Content

This lecture aims at introducing the students to the working principles and efficiency optimization methods for Internal Combustion (IC) engines which are expected to continue to play a very important role in transportation (long-haul heavy duty, marine) and decentralized combined heat and power generation. Following an overview of different applications and powertrains, the course will focus on the following topics: First, a generic overview of the history of IC-Engines is given, and the basic dimensions and specific engine-relevant terminology are introduced. Next, operating maps for different duty cycles are discussed, highlighting the benefits of individual powertrain configurations for different usage scenarios. The high-pressure thermodynamic process and combustion-induced heat release are analyzed in detail and the design of the combustion processes is discussed in view of further optimization of the energy conversion efficiency. The concept of boosting, its challenges and potential are also presented. In addition, flow field characteristics, convective and radiative heat transfer and combustion modes (Otto, Diesel and “multi-mode” cycles) will be discussed along with possible simulation methods. The course consists of lectures combined with exercises. In addition, several invited guest talks will be held by representatives from Swiss industrial companies active in this field. Provided the pandemic measures allow, visits to different engine test facilities are further envisioned.

Resources

Literature

J. Heywood, Internal Combustion Engine Fundamentals, McGraw-Hill

General Information

Language: English
Levels: MSC
Frequency: Yearly recurring

Examination

Type: session examination
Mode: oral 30 minutes

Course Components

Type	Title	Time & Place	Hours
lecture	Principles, Efficiency Optimization and Future Applications of IC Engines	Tue 10:15-12:00 (ML F 34)	2 h weekly
exercise	Principles, Efficiency Optimization and Future Applications of IC Engines	Tue 12:15-13:00 (ML F 34)	1 h weekly

Offered In

Mechanical Engineering Master
- Core Courses
  - Energy, Flows and Processes (The courses listed in this category “Core Courses” are recommended. Alternative courses can be chosen in agreement with the tutor.)
Energy Science and Technology Master
- Electives (These courses are particularly recommended, other ETH-courses from the field of Energy Science and Technology at large may be chosen in accordance with your tutor.)
  - Energy Flows and Processes