Duration
26h Th, 26h Pr, 2d FW
Number of credits
| Master in architectural engineering (ir.) (120 ECTS) | 5 crédits | |||
| Master in civil engineering (120 ECTS) | 5 crédits | |||
| Master in geology and mining engineering (120 ECTS) | 5 crédits |
Lecturer
Language(s) of instruction
English language
Organisation and examination
Teaching in the first semester, review in January
Schedule
Units courses prerequisite and corequisite
Prerequisite or corequisite units are presented within each program
Learning unit contents
Water and energy are vital components of a living city. Virtually all human and economic activities in urban environments rely on water and energy supply. In this course, the students will get acquainted to fundamentals of water and energy production, transport and distribution in urbanized areas. They will also be made familiar to topical challenges facing the water and energy sectors (e.g., leakage detection) and the interplay between water and energy in urban areas will be highlighted (cooling water, energy consumption for water sanitation, hydropower ...). Finally, the main concepts underpinning the design and sizing of urban drainage systems will be introduced, as well as current developments in urban flood risk management.
The classes cover the following topics:
- fundamentals of water production, transport and supply
- water storage in reservoirs
- sewage and urban drainage systems
- urban flood risk analysis and management
- ...
Learning outcomes of the learning unit
At the end of this course, the students will be able to
- understand the concepts underlying the design and sizing of water transport and supply systems;
- make a preliminary hydraulic design of a water service reservoir, considering water demand scenarios and the energy consumption of pumping systems;
- make a preliminary hydraulic design of a large-scale water harvesting system, accounting for various hydrometeorological scenarios and the influence of water pricing;
- understand the components of an integrated flood risk analysis, as well as evaluate urban flood risk based on flood hazard and vulnerability data;
- ...
Prerequisite knowledge and skills
- basic understanding of pressurized and open-channel flow computation (uniform flow, friction formulae)
- basic experience in using a computation software (such as Matlab)
Planned learning activities and teaching methods
The classes are divided in theoretical lectures and compulsory exercise sessions.
The compulsory exercise sessions include:
- exercises on the hydraulic sizing of a service reservoir;
- a small project on the design and sizing of a large-scale rainwater harvesting system;
- a small project related to urban flood risk modelling;
- ...
Mode of delivery (face-to-face ; distance-learning)
The course consists in face-to-face classes divided in theoretical lectures and compulsory exercise sessions. In the latter, the students are requested to submit a short report at the end of each session or a more comprehensive report after several sessions.
Recommended or required readings
The following reports provide a topical and valuable complement to the classes:
Assessment methods and criteria
A written exam takes place in January and in September. The reports of the practical assignments are also evaluated.
The practical assignments constitute an important part of the course and are compulsory. Students who fail to submit in due time the expected reports on the assignments will not be allowed to take the exam.
No partial exemption is granted.
Work placement(s)
Organizational remarks
The course is taught in English.
Lectures take place on Friday morning during the first semester.
Contacts
Pierre Dewallef: p.dewallef@ulg.ac.be
Benjamin Dewals: b.dewals@ulg.ac.be