Rigid Body Mechanics, Solid Mechanics, Science and Technology of Civil Engineering Materials, Strength of Materials
Course competences | |
---|---|
Code | Description |
AFC2 | Understanding and mastering the laws of thermomechanics of continuous media and the ability to apply them in engineering fields such as fluid mechanics, mechanics of materials, structural theory, etc. |
CB06 | Possess and understand knowledge that provides a basis or opportunity to be original in the development and / or application of ideas, often in a research context. |
CB07 | Apply the achieved knowledge and ability to solve problems in new or unfamiliar environments within broader (or multidisciplinary) contexts related to the area of study |
CB09 | Know how to communicate the conclusions and their supported knowledge and ultimate reasons to specialized and non-specialized audiences in a clear and unambiguous way |
CB10 | Have the learning skills which allow to continue studying in a self-directed or autonomous way |
G05 | Knowledge of the Civil Engineering profession and the activities that can be carried out in the field of civil engineering. |
G07 | Knowledge to apply technical and managerial skills in R&D&I activities in the field of civil engineering. |
G25 | Ability to identify, measure, enunciate, analyse, diagnose and scientifically and technically describe a civil engineering problem |
G27 | Ability to communicate in a second language. |
Course learning outcomes | |
---|---|
Description | |
Students use computer programs that simulate the mechanical behavior of materials and structures in static and dynamic regimes. | |
Students understand the behavior of materials, structural elements and structures through constitutive models. They apply these models to specific cases and use them to predict mechanical phenomena. | |
Additional outcomes | |
Description | |
Measure the mechanical properties of construction materials in Civil engineering |
Training Activity | Methodology | Related Competences (only degrees before RD 822/2021) | ECTS | Hours | As | Com | Description | |
Class Attendance (theory) [ON-SITE] | Lectures | AFC2 CB06 CB07 CB09 CB10 G05 G07 G25 G27 | 1.9 | 47.5 | Y | N | ||
Class Attendance (practical) [ON-SITE] | Project/Problem Based Learning (PBL) | AFC2 CB06 CB07 CB09 CB10 G05 G07 G25 G27 | 0.3 | 7.5 | Y | N | ||
Practicum and practical activities report writing or preparation [OFF-SITE] | Cooperative / Collaborative Learning | AFC2 CB06 CB07 CB09 CB10 G05 G07 G25 G27 | 0.5 | 12.5 | Y | Y | ||
Laboratory practice or sessions [ON-SITE] | Combination of methods | AFC2 CB06 CB07 CB09 CB10 G05 G07 G25 G27 | 0.3 | 7.5 | Y | Y | ||
Study and Exam Preparation [OFF-SITE] | Combination of methods | AFC2 CB06 CB07 CB09 CB10 G05 G07 G25 G27 | 5.8 | 145 | Y | N | ||
Progress test [ON-SITE] | Assessment tests | AFC2 CB06 CB07 CB09 CB10 G05 G07 G25 G27 | 0.2 | 5 | Y | N | ||
Total: | 9 | 225 | ||||||
Total credits of in-class work: 2.7 | Total class time hours: 67.5 | |||||||
Total credits of out of class work: 6.3 | Total hours of out of class work: 157.5 |
As: Assessable training activity Com: Training activity of compulsory overcoming (It will be essential to overcome both continuous and non-continuous assessment).
Evaluation System | Continuous assessment | Non-continuous evaluation * | Description |
Practicum and practical activities reports assessment | 16.80% | 16.80% | |
Theoretical exam | 50.00% | 83.20% | |
Assessment of active participation | 16.60% | 0.00% | |
Assessment of problem solving and/or case studies | 16.60% | 0.00% | |
Total: | 100.00% | 100.00% |
Not related to the syllabus/contents | |
---|---|
Hours | hours |
Unit 1 (de 3): Termoelasticity, elasticity and linear viscoelasticity | |
---|---|
Activities | Hours |
Class Attendance (theory) [PRESENCIAL][Lectures] | 15 |
Class Attendance (practical) [PRESENCIAL][Project/Problem Based Learning (PBL)] | 2.5 |
Practicum and practical activities report writing or preparation [AUTÓNOMA][Cooperative / Collaborative Learning] | 4 |
Laboratory practice or sessions [PRESENCIAL][Combination of methods] | 2.5 |
Study and Exam Preparation [AUTÓNOMA][Combination of methods] | 47.5 |
Progress test [PRESENCIAL][Assessment tests] | 1.5 |
Group 20: | |
Initial date: 28-09-2020 | End date: 18-12-2020 |
Unit 2 (de 3): Plasticity and viscoplasticity | |
---|---|
Activities | Hours |
Class Attendance (theory) [PRESENCIAL][Lectures] | 15 |
Class Attendance (practical) [PRESENCIAL][Project/Problem Based Learning (PBL)] | 2.5 |
Practicum and practical activities report writing or preparation [AUTÓNOMA][Cooperative / Collaborative Learning] | 4.5 |
Laboratory practice or sessions [PRESENCIAL][Combination of methods] | 2.5 |
Study and Exam Preparation [AUTÓNOMA][Combination of methods] | 47.5 |
Progress test [PRESENCIAL][Assessment tests] | 2 |
Group 20: | |
Initial date: 29/10/2018 | End date: 23/11/2018 |
Unit 3 (de 3): Fracture Mechanics | |
---|---|
Activities | Hours |
Class Attendance (theory) [PRESENCIAL][Lectures] | 17.5 |
Class Attendance (practical) [PRESENCIAL][Project/Problem Based Learning (PBL)] | 2.5 |
Practicum and practical activities report writing or preparation [AUTÓNOMA][Cooperative / Collaborative Learning] | 4 |
Laboratory practice or sessions [PRESENCIAL][Combination of methods] | 2.5 |
Study and Exam Preparation [AUTÓNOMA][Combination of methods] | 50 |
Progress test [PRESENCIAL][Assessment tests] | 1.5 |
Group 20: | |
Initial date: 27/11/2018 | End date: 21/12/2018 |
Global activity | |
---|---|
Activities | hours |
Author(s) | Title | Book/Journal | Citv | Publishing house | ISBN | Year | Description | Link | Catálogo biblioteca |
---|---|---|---|---|---|---|---|---|---|
Basar, Yavuz | Nonlinear continuum mechanics of solids: fundamental mathema | Springer | 3-540-66601-X | 2000 | |||||
Chadwick, Peter | Continuum mechanics: concise theory and problems | Dover | 0-486-40180-4 | 1999 | |||||
Chandrasekharaiah, D. S. | Continuum mechanics | Academic Press | 0-12-167880-6 | 0 | |||||
Chaves, E.W.V. | Mecánica del medio continuo: (conceptos básicos) | CIMNE | 978-84-96736-38-2 | 2007 | |||||
Chaves, E.W.V. | Mécanica del medio continuo: modelos constitutivos / Eduardo | CIMNE | 978-84-96736-68-9 | 2009 | |||||
Chaves, E.W.V. | Notes on Continuum Mechanics | Springer/CIMNE | 978-94-007-5985-5 | 2013 | |||||
Chaves, E.W.V. | Solving Problems by means of Continuum Mechanics | https://previa.uclm.es/profesorado/evieira/ftp/apuntes/mmc_problems.pdf | |||||||
Christensen, R.M. | Theory of Viscoelasticity | Dover | 0-486-42880-X | 1982 | |||||
Chung, T. J. | General continuum mechanics | Cambridge University Press | 978-0-521-87406-9 | 2007 | |||||
Gurtin, Morton E. | An introduction to continuum mechanics | Academic Press | 0-12-309750-9 | 1981 | |||||
Haupt, Peter | Continuum mechanics and theory of materials | Springer | 3-540-66114-X | 2000 | |||||
Holzapfel, Gerhard A. | Nonlinear solid mechanics: a continuum approach for engineer | John Wiley & Sons | 0-471-82319-8 | 2000 | |||||
J. Chakrabarty | Theory of Plasticity | Elsevier | 978-0-7506-6638-2 | 2006 | |||||
Malvern, Lawrence E. | Introduction to the mechanics of a continuous medium | Prentice-Hall | 0-13-487603-2 | 1969 | |||||
Mauel Elices | Mecanica de la fractura | ETSI de Caminos, UPM | 9788474931976 | 1993 | |||||
Norman E. Dowling | Mechanical behavior of materials. Engineering Methods for deformation, fracture and fatigue | Prentice Hall | 0-13-905720-X | 1999 | |||||
Ogden, R.W. | non-linear elastic deformation | Dover | 1984 | ||||||
Oliver, X; Agelet de Saracíbar, C. | Mecánica de medios continuos para ingenieros | CIMNE | 84-8301-412-2 | 2000 | |||||
Sanchez Galvez, Vicente | Curso de comportamiento plástico de materiales | Universidad Politécnica de Madrid, Departamento de | 84-7493-261-0 | 1999 |