240EQ212 - Fundamentals of Combustion and Fire Dynamics

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Coordinating unit: Teaching unit: Academic year: Degree: ECTS credits: 2018 295 - EEBE - Barcelona East School of Engineering 713 - EQ - Department of Chemical Engineering MASTER'S DEGREE IN CHEMICAL ENGINEERING (Syllabus 2012). (Teaching unit Optional) MASTER'S DEGREE IN CHEMICAL ENGINEERING (Syllabus 2012). (Teaching unit Optional) 4,5 Teaching languages: Catalan Teaching staff Coordinator: Others: EULALIA PLANAS CUCHI EULALIA PLANAS CUCHI - ELSA PASTOR FERRER Opening hours Timetable: Request your attention time directly to the professor via e-mail Prior skills Fundamentals of chemistry, thermodynamics, mass energy and momentum transfer, ordinary differential equations, numerical calculation. Requirements To have completed the courses relevant to the matters mentioned in the prior skills. Degree competences to which the subject contributes Specific: 3. Apply knowledge of mathematics, physics, chemistry, biology and other natural sciences, obtained through study, experience, and practice, critical reasoning to establish economically viable solutions to technical problems. 4. Conceptualize engineering models; apply innovative methods in problem solving and applications suitable for the design, simulation, optimization and control of processes and systems. 5. Design, build and implement methods, processes and equipment for the supply and management of waste solids, liquids and gases in industries, capable of assessing their impacts and risks. Generical: 1. Ability to apply the scientific method and the principles of engineering and economics, to formulate and solve complex problems in processes, equipment, facilities and services, in which the material changes its composition, state or energy content, characteristic of chemical industry and other related sectors which include the pharmaceutical, biotechnology, materials, energy, food or environmental. 2. Integrate knowledge and handle complexity, making judgments and decisions, from incomplete or limited information, including reflections on the social and ethical responsibilities of professional practice. Teaching methodology Lectures of theory and problems, participatory problem seminars, work on case studies, seminars Learning objectives of the subject 1 / 6

The course aims to provide students with the knowledge to interpret and analyze the problems related to fires. At the end of the course the student should be able to: OE1. Apply the basic laws governing the phenomenon of combustion and fire OE2. Using mathematical models to identify and characterize the different types of fires OE3. Using at basic level tools and software to simulate fire behaviour OE4. List the various fire protection systems OE5. Describe the basics of fire investigation Study load Total learning time: 112h 30m Hours large group: 40h 30m 36.00% Hours medium group: 0h 0.00% Hours small group: 0h 0.00% Guided activities: 0h 0.00% Self study: 72h 64.00% 2 / 6

Content INTRODUCTION. FUNDAMENTAL ASPECTS OF COMBUSTION Learning time: 24h Theory classes: 5h Practical classes: 3h Self study : 16h The science of fire and combustion. Fuel types and their classification. Physic chemistry of combustion in a fire. Chemical reactions. Heat of combustion. Flame Temperature. Combustion products. Control Volume. The Reynolds theorem. Matter, energy and momentum conservation laws. OE1 FIRE DYNAMICS Learning time: 32h Theory classes: 8h Practical classes: 3h Self study : 21h Pre-mixed flames: reaction rate, ignition, flame speed, quenching, flammability limits. Diffusion flames: laminar and turbulent jet fires, flames of natural fires. Types of fires. Spontaneous ignition, ignition of liquids, ignition of solids. Flame spread phenomena. Fire spread models. Fire propagation on different media. Burning rate of liquid fuels, burning rate of solid fuels, burning rate in complex materials. OE2 3 / 6

FIRE MODELLING Learning time: 40h Theory classes: 9h Practical classes: 8h Self study : 23h Phases of fires in enclosures. Fluid dynamics. Heat transfer. Fuel behaviour. Zone modelling and conservation equations. Correlations. Flashover. CFD modelling: mathematical equations, turbulence, combustion, radiation, soot production, pyrolysis. Current simulation tools., A2, A3 OE3 FIRE PROTECTION Learning time: 8h 30m Theory classes: 1h 30m Practical classes: 1h Self study : 6h Introduction to fire protection. Basic description of the different methods of passive and active protection. Reference to regulations OE4 FIRE INVESTIGATION Learning time: 8h Theory classes: 1h Practical classes: 1h Self study : 6h Methods for carrying out the investigation of a fire. Sources of ignition. Traces of a fire. Professions involved. OE5 4 / 6

Planning of activities A1-RESOLUTION OF EXERCISES Hours: 36h Self study: 36h Deliver one or different exercises to be solved regularly and individually at home Statement of the exercise, notes from class, slides and bibliography of reference Detailed resolution of the exercise OE1, OE2, OE3, OE4, OE5 A2-PRACTICES Hours: 2h 30m Laboratory classes: 2h 30m Realization of the practices in the lab or in a computer lab Guideline of the practice. Notes from class. Slides. Example solved. Needed program Previous report before carrying out the practice. Report with the resolution of the problem proposed in the practice OE1, OE3 A3-SIMULATION OF A CASE WITH FDS Hours: 10h Self study: 10h Resolution in group and with the help of the FDS program in a case set Statement of the case to be solved. Notes from class. Slides. FDS program Report with a pre-defined formal structure in which the resolution of the case is showned and analyse the results obtained OE3 A4-RESOLUTION IN A PRACTICAL CASE Hours: 10h Self study: 10h 5 / 6

240EQ212 - Fundamentals of Combustion and Fire Dynamics Resolution in group of a set case related to the investigation of a real fire Statement of the case to be solved. Notes from class. Slides Report with a formal pre-defined structure in which the resolution of the case is showned and the results obtained are analysed OE5 Qualification system Final Mark: FM = 0.5 NEF + 0.2 NEP + 0.1 NAC + 0.1 NT + 0.1 NP Where, NEF: Final examination mark NEP: Partial examination mark NAC: Average mark of the problems delivered NT: Average mark of the team-working job of solving a case NP: Mark of the practicals Regulations for carrying out activities tests can be made using all available bibliographic material: lecture notes, reference books, collection of problems, etc Bibliography 6 / 6

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