Autumn Semester 2020 takes place in a mixed form of online and classroom teaching.
Please read the published information on the individual courses carefully.

Konstantinos Boulouchos: Catalogue data in Spring Semester 2015

Name Prof. Dr. Konstantinos Boulouchos
FieldAerothermochemie und Verbrennungssysteme
Address
Institut für Energietechnik (eh.)
ETH Zürich, ML J 39
Sonneggstrasse 3
8092 Zürich
SWITZERLAND
Telephone+41 44 632 56 48
E-mailboulouchos@lav.mavt.ethz.ch
DepartmentMechanical and Process Engineering
RelationshipFull Professor

NumberTitleECTSHoursLecturers
151-0052-00LThermodynamics II Information 4 credits2V + 2UK. Boulouchos, D. Poulikakos
AbstractIntroduction to the Thermodynamics of reactive systems and to the fundamentals of heat transfer.
ObjectiveIntroduction to the theory and to the bases of the technical thermodynamics. Main focus: Chemical thermodynamics and heat transfer
Content1st and 2nd law of thermodynamics for chemically reactive systems, chemical exergy, fuel cells and kinetic gas theory.
General mechanisms of heat transfer. Introduction to heat conductivity. Stationary 1-D and 2-D heat conduction. Instationary conduction. Convection. Forced convection - flow around and through bodies. Natural convection. Evaporation (boiling) and condensation. Heat radiation. Combined heat transfer.
Lecture notesSlides and lecture notes in German.
LiteratureF.P. Incropera, D.P. DeWitt, T.L. Bergman, and A.S. Lavine, Fundamentals of Heat and Mass Transfer, John Wiley & Sons, 6th edition, 2006.

M.J. Moran, H.N. Shapiro, Fundamentals of Engineering Thermodynamics, John Wiley & Sons, 2007.
151-0254-00LIC-Engines and Propulsion Systems II4 credits2V + 1UK. Boulouchos, P. Dimopoulos Eggenschwiler
AbstractTurbulent flowfield in IC engines. Ignition, premixed flame propagation, knock in homogeneous charge, external ignition engines (otto). Compression-ignition diesel engines, incl. mixture formation and HCCI concepts. Direct ignition. Pollutant formation mechanism (NOx, particulates, unburned hydrocarbons) and their minimization. Catalytic exhaust aftertreatment methods for all pollutant categories.
ObjectiveThe students get a further insight in the internal combustion engine by means of the topics mentioned in the abstract. This knowledge is applied in several calculation exercises and lab exercises at the engine test bench. The students additionally get an introduction in exhaust gas aftertreatment systems.
Lecture notesHandouts are in German and English.
LiteratureJ.B. Heywood, Internal Combustion Engine Fundamentals, McGraw-Hill Mechanical Engineering
Prerequisites / NoticeBy request lectured in English.

This course is a natural extension of the course 'IC-Engines and Propulsion Systems I' (151-0251-00L). The content of that lecture is assumed known.
Basic knowledge of thermodynamics and combustion is required.
It is beneficial to have attended the course 'Combustion and Reactive Processes in Energy and Materials Technology' (151-0293-00L).
151-0262-00LDiagnostics in Experimental Combustion Research4 credits3GK. Herrmann, K. Boulouchos, P. Obrecht, B. Schneider
AbstractThe course is an introduction with regard to different measurement techniques and diagnostical methods. After a first part of measurement technique fundamentals, the acquisition of important key parameter by sensors will be presented. The second major part of the course deals with non-intrusive optical (laser-)measurement techniques.
ObjectiveOverview about measurement techniques in general and specific optical methods used in experimental combustion research.
ContentPart I – fundamentals: experiment, measuring chain, signal- and data acquisition, processing and analysis.
Part II – measurement technique: principles (capacitive, inductive, magnetic, et al.), acquisition of different key parameter (velocity, force, pressure, temperature, tension, et al.) with probes and sensors.
Part III – optical measurement technique: fundamentals optics, sensors (CCD, CMOS, photodiode, et al.), optical techniques (scattered light, Shadow-imaging, Schlieren, et al.), in particular non-intrusive flow measurement (LDA/PDA, PIV), chemiluminescence & spectroscopic techniques (laser-induced fluorescence LIF; Raman, CARS, et al.), and other laser diagnostical methods (LII, Pyrometry, et al.).
Lecture notesHandout slides
Prerequisites / NoticeEnglish or German (based on request)
151-1053-00LThermo- and Fluid Dynamics Information 0 credits2KP. Jenny, R. S. Abhari, K. Boulouchos, P. Koumoutsakos, C. Müller, H. G. Park, D. Poulikakos, H.‑M. Prasser, T. Rösgen, A. Steinfeld
AbstractCurrent advanced research activities in the areas of thermo- and fluid dynamics are presented and discussed, mostly by external speakers.

The talks are public and open also for interested students.
ObjectiveKnowledge of advanced research in the areas of thermo- and fluid dynamics
ContentCurrent advanced research activities in the areas of thermo- and fluid dynamics are presented and discussed, mostly by external speakers.