Guillaume Habert: Katalogdaten im Herbstsemester 2021 |
Name | Herr Prof. Dr. Guillaume Habert |
Lehrgebiet | Nachhaltiges Bauen |
Adresse | Inst. Bau-&Infrastrukturmanagement ETH Zürich, HIL F 28.1 Stefano-Franscini-Platz 5 8093 Zürich SWITZERLAND |
Telefon | +41 44 633 05 60 |
habert@ibi.baug.ethz.ch | |
Departement | Bau, Umwelt und Geomatik |
Beziehung | Ordentlicher Professor |
Nummer | Titel | ECTS | Umfang | Dozierende | |
---|---|---|---|---|---|
101-0527-10L | Materials and Constructions | 3 KP | 2G | G. Habert, D. Sanz Pont | |
Kurzbeschreibung | Building materials with a special focus on regenerative materials: earth, bio-based and reuse. Sourcing, properties and performance, building envelope integration and detailing, sustainable building construction | ||||
Lernziel | Special focus on regenerative materials: earth, bio-based and reuse The students will acquire knowledge in the following fields: Fundamentals of material performance Introduction to durability problems of building facades Materials for the building envelope: - Overview of structural materials and systems: concrete, steel, wood and bamboo, earth - Insulating materials (bio-based vs conventional) - Air barrier, vapour barrier and sealants - Interior finishing Assessment of materials and components behaviour and performance Solutions for energy retrofitting of (historical) buildings Aspects of sustainability and durability | ||||
Inhalt | Introduction Sustainable cement and concrete Earth construction Visit Steel and bamboo Timber construction Building physic and conventional insulation Bio-based insulation Finishing Reuse | ||||
101-0577-00L | An Introduction to Sustainable Development in the Built Environment | 3 KP | 2G | G. Habert, D. Kaushal | |
Kurzbeschreibung | In 2015, the UN Conference in Paris shaped future world objectives to tackle climate change. in 2016, other political bodies made these changes more difficult to predict. What does it mean for the built environment? This course provides an introduction to the notion of sustainable development when applied to our built environment | ||||
Lernziel | At the end of the semester, the students have an understanding of the term of sustainable development, its history, the current political and scientific discourses and its relevance for our built environment. In order to address current challenges of climate change mitigation and resource depletion, students will learn a holistic approach of sustainable development. Ecological, economical and social constraints will be presented and students will learn about methods for argumentation and tools for assessment (i.e. life cycle assessment). For this purpose an overview of sustainable development is presented with an introduction to the history of sustainability and its today definition as well as the role of cities, urbanisation and material resources (i.e. energy, construction material) in social economic and environmetal aspects. The course aims to promote an integral view and understanding of sustainability and describing different spheres (social/cultural, ecological, economical, and institutional) that influence our built environment. Students will acquire critical knowledge and understand the role of involved stakeholders, their motivations and constraints, learn how to evaluate challenges, identify deficits and define strategies to promote a more sustainable construction. After the course students should be able to define the relevance of specific local, regional or territorial aspects to achieve coherent and applicable solutions toward sustainable development. The course offers an environmental, socio-economic and socio-technical perspective focussing on buildings, cities and their transition to resilience with sustainable development. Students will learn on theory and application of current scientific pathways towards sustainable development. | ||||
Inhalt | The following topics give an overview of the themes that are to be worked on during the lecture. - Overview on the history and emergence of sustainable development - Overview on the current understanding and definition of sustainable development Methods - Method 1: Life cycle assessment (planning, construction, operation/use, deconstruction) - Method 2: Life Cycle Costing - Method 3: Labels and certification Main issues: - Operation energy at building, urban and national scale - Mobility and density questions - Embodied energy for developing and developed world - Synthesis: Transition to sustainable development | ||||
Skript | All relevant information will be online available before the lectures. For each lecture slides of the lecture will be provided. | ||||
Literatur | A list of the basic literature will be offered on a specific online platform, that could be used by all students attending the lectures. | ||||
101-0608-00L | Design-Integrated Life Cycle Assessment | 3 KP | 2G | G. Habert | |
Kurzbeschreibung | Currently, Life Cycle Assessment (LCA) is applied as an ex-post design evaluation of buildings, but rarely used to improve the building during the design process. The aim of this course is to apply LCA during the design of buildings by means of a digital, parametric tool. The necessary fundamentals of the LCA method will be taught following a lecture on demands approach. | ||||
Lernziel | The course will follow two main objectives and a third optional objective, depending on the design projects the students’ choose. At the end of the course, the students will: 1. Know the methodology of LCA 2. Be able to apply LCA in the design process to assess and improve the environmental performance of their projects 3. Be able to use the parametric LCA tool and link it to additional performance assessment tools for a holistic optimisation | ||||
Inhalt | The course will be structured into two parts, each making up about half of the semester. Part I: Exercises with lectures on demand The first six individual courses will follow the “lectures on demand” approach. Small “hands-on” exercises focusing on one specific aspect will be given out and the necessary background knowledge will be provided in the form of short input lectures when questions arise. The following topics will be discussed during the first part: 1) LCA basic introduction 2) System boundaries, functional unit, end of life 3) Carbon budget and LCA benchmarks 4) BIM-LCA, available calculation tools and databases 5) Integrated analysis of environmental and cost assessment 6) Bio-based carbon storage Part II: Project-based learning In the second part, the students will work on their individual project in groups of three. For the design task, the students will bring their own project and work on improving it. The projects can be chosen depending on the students background and range from buildings to infrastructure projects. Intermediate presentations will ensure the continuous work and make sure all groups are on the same level and learn from each other. During this part, the following hands-on tutorials will be given: 1) Introduction to Rhinoceros 6 and 7 2) Introduction to grasshopper 3) Integrated assessment tools (ladybug tools) 4) Introduction to in-house grasshopper plugin for LCA analysis | ||||
Skript | As the course follows a lecture on demand approach, the lecture slides will be provided after each course. | ||||
Literatur | A list of the basic literature will be offered on a specific online platform, that could be used by all students attending the lectures. | ||||
Voraussetzungen / Besonderes | Prerequisite: Sustainable construction (101-0577-00L). Otherwise a special permisson by the lecturer is required. The students are expected to work out of class as well. The course time will be used by the teachers to answer project-specific questions. The lecture series will be conducted in English and is aimed at students of master's programs, particularly the departments ARCH, BAUG, ITET, MAVT, MTEC and UWIS. No lecture will be given during Seminar week. |