Ingo Burgert: Catalogue data in Spring Semester 2021

Name Prof. Dr. Ingo Burgert
FieldWood Materials Science
Address
Institut für Baustoffe (IfB)
ETH Zürich, HIF E 87.1
Laura-Hezner-Weg 7
8093 Zürich
SWITZERLAND
Telephone+41 44 633 77 73
E-mailiburgert@ethz.ch
DepartmentCivil, Environmental and Geomatic Engineering
RelationshipFull Professor

NumberTitleECTSHoursLecturers
101-0604-02LIntroduction to Materials5 credits4GR. J. Flatt, U. Angst, I. Burgert, F. Wittel
AbstractIn this introductory lecture, students gain basic knowledge on building materials like cement, concrete, metals, glass, wood, polymers, and bitumen, their manufacturing and processing, important properties and their application. Fundamental mechanical, thermal and optical properties are discussed and experimental ways for measuring, as well as numerical methods for predicting them, are depicted.
ObjectiveStudents become acquainted with the spectrum of building materials and their characteristic properties. They will learn about the most important mechanical properties, as well as factors affecting durability. In particular, structures and properties of mineral binders, cement, concrete, bitumen and asphalt, wood, metals, glass, and polymers are presented. Students learn about the fundamental behavior of materials, experimental measurement of characteristic properties, as well as means for their numerical prediction and optimization.
Content-Fundamental behavior of building materials: mechanical, thermal and optical properties; strength and fracture; material testing and parameter identification; porosity and moisture transport;
-Mineral binders: production and hydration
-Concrete: Mechanics and rheology, durability, freezing, shrinkage, and carbonation.
-Metals: Introduction and physical properties, alloying and iron-carbon alloys, processing and applications in civil engineering.
-Corrosion: Atmospheric corrosion and durability of steel-reinforced concrete.
-Wood: Structure and chemism, mechanical properties, wood protection, and wood materials.
-Glass: Introduction on glass and physical properties, processing and applications in civil engineering.
-Polymers: Foundations, properties, and processing, applications in civil engineering.
-Asphalt and bitumen.
-Material modeling: Basics of material modeling, micro-mechanics and case studies for building materials.
Lecture notesAll lecture materials are distributed on the moodle page of the course.
LiteratureAshby/Jones: Engineering Materials I and II
Ashby: Materials Selection in Mechanical Design
101-0678-00LWood Physics & Wood Materials3 credits2GI. Burgert, T. Zimmermann
AbstractFundamental relationships between structure and properties of wood and wood based materials are conveyed. Based on the hierarchical structure of wood, aspects of nanostructural characterization and micromechanical analysis will be covered. In view of material developments, concepts for the assembly of advanced wood materials and cellulose-based materials will be demonstrated.
ObjectiveAt a global scale wood is one of the most important building materials. Knowledge of significant physical properties of wood, wood based materials and advanced wood materials as well as the relationship between structure and properties are conveyed. This knowledge is fundamental for an appropriate use of wood and wood based materials as well as for a further improvement of the reliability of wood and for establishing new fields of application.
ContentThe following topics are covered:
Hierarchical structure of wood and assembly of wood-based products
Physical properties (density, wood moisture, swelling and shrinkage)
Mechanical properties at different length scales
Nanostructural characterization
Materials from nanocellulose
Wood modification and durability
Wood polymer composites
Wood hybrid materials
Wood surfaces
Functional wood materials
Lecture notesHandouts will be sent to the students by e-mail prior to each lecture.
LiteratureNiemz, P.: Physik des Holzes und der Holzwerkstoffe, DRW Verlag 1993
Bodig, J.; Jayne, B.A.: Mechanics of wod and wood composites. Krieger, Malabar, Florida 1993
Dunky,M.; Niemz, P.: Holzwerkstoffe und Leime. Springer, Berlin 2002
Wagenführ,A.; Scholz,F.:Taschenbuch der Holztechnik (Kapitel 1.4 und 2, P.Niemz), Hanser Verlag 2008
101-0679-00LNon-Destructive Test Methods and Health Monitoring Restricted registration - show details
Number of participants limited to 8.
3 credits2PI. Burgert, U. Angst
AbstractMethods for the non-destructive characterization and testing of wood and reinforced concrete are presented in introductory lectures. Afterwards selected experiments such as measurement of humidity, ultrasound, hardness and porosity are performed by the students. Some parameters that influence materials properties are tested. A written report with results and discussion has to be prepared at the en
ObjectiveImportant non-destructive test methods shall be learnt. These methods that are based on the same physical principles (e.g. resistance measurement, ultrasound, hardness) are used for wood and concrete in a comparative way. The course shall the address the fundamentals for condition assessment of structures in wood and reinforced concrete.
ContentDetailed knowledge of the microscopic structure of concrete and wood.
Knowledge of non-destructive test methods for concrete and wood (humidity, ultrasound, hardness, etc.).
Problems in calibration of measuring instruments, influence of disturbing parameters (e.g. temperature).
Basics of condition assessment of wood and reinforced concrete structures, assessment of deterioration processes (corrosion).
Writing of reports for condition assessment.
Possibilities of restoration of structures.
Lecture notesA manuscript of the course will be available. Additionally reprints or more specific literature will be indicated.
LiteratureWerkstoff Holz:
Niemz, P.; Sander, D.: Prozessmesstechnik in der Holzindustrie. Leipzig 1990
Tagungsbände Fachtagungen zur zerstörungsfreien Werkstoffprüfung
Bucur, V.: Characterization and Imaging of Wood. Springer 2003
Bucur, V.: Acoustics of Wood. Springer 2006
Vollenschar (Hrsg): Wendehorst Baustoffkunde. 26. Auflage. Teubner 2004
Hasenstab, A.: Integritätsprüfung mit zerstörungsfreien Ultraschallechoverfahren.
Diss. TU Berlin 2005
Unger, A.: Schniewind, A.P.; Unger, W.: Conservation of wood artifacts.
Springer 2001

Werkstoff Beton
D. Bürcheler: Der elektrische Widerstand von zementösen Werkstoffen. Diss. ETHZ 11876 (1996)