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Course info
KKE / EENA
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Course description
Department/Unit / Abbreviation
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KKE
/
EENA
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Academic Year
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2023/2024
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Academic Year
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2023/2024
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Title
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Environmental Engineering
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Form of course completion
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Pre-Exam Credit
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Form of course completion
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Pre-Exam Credit
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Accredited / Credits
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Yes,
2
Cred.
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Type of completion
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Combined
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Type of completion
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Combined
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Time requirements
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Lecture
1
[Hours/Week]
Tutorial
1
[Hours/Week]
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Course credit prior to examination
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No
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Course credit prior to examination
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No
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Automatic acceptance of credit before examination
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Yes in the case of a previous evaluation 4 nebo nic.
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Included in study average
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YES
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Language of instruction
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English
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Occ/max
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|
|
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Automatic acceptance of credit before examination
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Yes in the case of a previous evaluation 4 nebo nic.
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Summer semester
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0 / -
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0 / -
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0 / -
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Included in study average
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YES
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Winter semester
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0 / -
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0 / -
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0 / -
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Repeated registration
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NO
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Repeated registration
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NO
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Timetable
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Yes
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Semester taught
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Winter semester
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Semester taught
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Winter semester
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Minimum (B + C) students
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10
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Optional course |
Yes
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Optional course
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Yes
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Language of instruction
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English
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Internship duration
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0
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No. of hours of on-premise lessons |
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Evaluation scale |
1|2|3|4 |
Periodicity |
každý rok
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Periodicita upřesnění |
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Fundamental theoretical course |
No
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Fundamental course |
No
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Fundamental theoretical course |
No
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Evaluation scale |
1|2|3|4 |
Substituted course
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KKE/PTTA
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Preclusive courses
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N/A
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Prerequisite courses
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N/A
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Informally recommended courses
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N/A
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Courses depending on this Course
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N/A
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Histogram of students' grades over the years:
Graphic PNG
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XLS
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Course objectives:
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1. Provide theory of diffusion in environment.
2. Provide theory of atmospheric boundary layer.
3. Acquire abilities to perform physical and numerical modelling of the environmental flows.
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Requirements on student
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Continuous assessment: fulfilment of test requirements
Final assessment: oral examination
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Content
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Type of classes - LECTURES
1 Methods of describing fluid motion, Euler and Lagrange approaches, application in situations typical in environmental aerodynamics.
2 Equations of fluid flow, specific mathematical models, basic properties of those models.
3 Hydrodynamic instability of laminar shear flows, transition to turbulence.
4 Turbulence, definition, properties, properties of fully developed turbulent flows in environmental aerodynamics, methods of mathematical modelling those flows.
5 Scalar transport in laminar and turbulent flows, phenomenology and mathematical modelling.
6 Seepage in porous media, physical models, mathematical description of the physical process.
7 Atmospheric boundary layer, basic properties, characteristic parameters.
8 Rayleigh-Bénard convection as a fundamental mechanism of atmospheric dynamical behaviour. Aspects related to deterministic chaos.
9 Climate and weather, typical dynamical behaviour of atmosphere on various time-scales.
10 Two-phase flow, thermodynamic of wet air.
11 Water flow in rivers and reservoirs, interaction of such flows.
Type of classes - LABORATORY
1 Velocity evaluation in an experimental facility using a selected experimental method.
2 Turbulence measurement within a turbulent boundary layer (PIV, LDA, HW).
3 Visualisation of flow around a building (PIV).
4 Visualisation of inhomogeneity in water vessel (EIT).
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Activities
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Fields of study
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Guarantors and lecturers
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Guarantors:
Prof. Ing. Václav Uruba, CSc. (100%),
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Lecturer:
Doc. RNDr. Daniel Duda, Ph.D. (20%),
Prof. Ing. Václav Uruba, CSc. (80%),
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Tutorial lecturer:
Doc. RNDr. Daniel Duda, Ph.D. (80%),
Prof. Ing. Václav Uruba, CSc. (20%),
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Literature
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Basic:
Kundu P., Cohen I. Fluid mechanics. 2010.
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Basic:
Xuhui Lee. Fundamentals of Boundary-Layer Meteorology. 2018. ISBN 978-3-319-60851-8.
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Recommended:
Hermann Schlichting, Klaus Gersten. Boundary layer theory. 2016.
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On-line library catalogues
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Time requirements
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All forms of study
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Activities
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Time requirements for activity [h]
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Preparation for an examination (30-60)
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60
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Contact hours
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56
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Preparation for comprehensive test (10-40)
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40
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Total
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156
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Prerequisites
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Knowledge - students are expected to possess the following knowledge before the course commences to finish it successfully: |
Fundamentals of mechanics, thermodynamics and fluid mechanics. |
Skills - students are expected to possess the following skills before the course commences to finish it successfully: |
Ability of individual work and collaboration in a group. |
Competences - students are expected to possess the following competences before the course commences to finish it successfully: |
N/A |
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Learning outcomes
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Knowledge - knowledge resulting from the course: |
Knowledge of atmospheric boundary layer flow and diffusion processes. |
Knowledge of the flow in water channels. |
Skills - skills resulting from the course: |
Ability to define the physical and mathematical models of the environmental flows. |
Competences - competences resulting from the course: |
N/A |
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Assessment methods
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Knowledge - knowledge achieved by taking this course are verified by the following means: |
Seminar work |
Skills - skills achieved by taking this course are verified by the following means: |
Seminar work |
Competences - competence achieved by taking this course are verified by the following means: |
Test |
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Teaching methods
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Knowledge - the following training methods are used to achieve the required knowledge: |
Lecture |
Skills - the following training methods are used to achieve the required skills: |
Practicum |
Competences - the following training methods are used to achieve the required competences: |
Seminar |
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