It is advisable that the student have knowledge of mathematics, physics, chemistry, and Materials Science as well as basic knowledge of manufacturing acquired in previous courses.
Material Science is a mandatory subject in Mechanical Engineering, Degree. The concepts developed in this subject are related with Material Science, Manufacturing Systems and Management and they will be used later in electives subjects such as Advanced Materials
Course competences | |
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Code | Description |
A01 | To understand and have knowledge in an area of study that moves on from the general education attained at secondary level and usually found at a level that, while supported in advanced text books, also includes some aspects that include knowledge found at the cutting edge of the field of study. |
A02 | To know how to apply knowledge to work or vocation in a professional manner and possess the competences that are usually demonstrated by the formulation and defence of arguments and the resolution of problems in the field of study. |
A03 | To have the capability to gather and interpret relevant data (normally within the area of study) to make judgements that include a reflection on themes of a social, scientific or ethical nature. |
A04 | To be able to transmit information, ideas, problems and solutions to a specialized audience. |
A05 | To have developed the learning skills necessary to undertake subsequent studies with a greater degree of autonomy. |
A06 | Command of a second foreign language at B1 level of the Common European Framework of Refence for Languages. |
A08 | Appropriate level of oral and written communication. |
A12 | Knowledge of basic materials and technologies that assist the learning of new methods and theories and enable versatility to adapt to new situations. |
A13 | Ability to take the initiative to solve problems, take decisions, creativity, critical reasoning and ability to communicate and transmit knowledge, skills and abilities in Mechanical Engineering. |
A14 | Knowledge to undertake measurements, calculations, evaluations, appraisals, studies, give expert opinions, reports, work plans and similar tasks. |
A15 | Ability to work to specifications and comply with obligatory rules and regulations. |
C03 | Knowledge of the fundamentals of science, technology and chemistry of materials. Understanding of the relation between the microstructure, synthesis, processing and properties of materials. |
CB01 | Prove that they have acquired and understood knowledge in a subject area that derives from general secondary education and is appropriate to a level based on advanced course books, and includes updated and cutting-edge aspects of their field of knowledge. |
CB02 | Apply their knowledge to their job or vocation in a professional manner and show that they have the competences to construct and justify arguments and solve problems within their subject area. |
CB03 | Be able to gather and process relevant information (usually within their subject area) to give opinions, including reflections on relevant social, scientific or ethical issues. |
CB04 | Transmit information, ideas, problems and solutions for both specialist and non-specialist audiences. |
CB05 | Have developed the necessary learning abilities to carry on studying autonomously |
D07 | Knowledge and ability in the application of materials engineering. |
Course learning outcomes | |
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Description | |
Distinguish the most common techniques of processing materials and recognize the effects of processing on the structure and processing of the material | |
Distinguish the different thermal treatments of metals | |
Communicate the importance of knowing and predicting the behaviour of a material when it is in use | |
Know the different techniques for inspecting parts and detecting defects using non-destructive tests | |
Know the techniques for joining parts through soldering and adhesives | |
Know the basic resources for the improvement of materials through the engineering of surfaces | |
Additional outcomes | |
Not established. |
Training Activity | Methodology | Related Competences (only degrees before RD 822/2021) | ECTS | Hours | As | Com | Description | |
Class Attendance (theory) [ON-SITE] | Lectures | A04 A08 A12 C03 D07 | 0.8 | 20 | N | N | ||
Individual tutoring sessions [ON-SITE] | Combination of methods | A08 A12 A13 A14 C03 CB01 CB02 CB03 CB04 CB05 D07 | 0.32 | 8 | N | N | ||
Problem solving and/or case studies [ON-SITE] | Problem solving and exercises | A12 A13 A14 C03 CB01 CB02 CB03 CB04 CB05 D07 | 0.8 | 20 | Y | Y | ||
Study and Exam Preparation [OFF-SITE] | Self-study | C03 D07 | 3.6 | 90 | N | N | ||
Final test [ON-SITE] | Assessment tests | A08 A13 A14 C03 D07 | 0.16 | 4 | Y | Y | ||
Laboratory practice or sessions [ON-SITE] | Practical or hands-on activities | A08 A12 A13 A14 C03 CB01 CB02 CB03 CB04 CB05 D07 | 0.32 | 8 | Y | Y | ||
Total: | 6 | 150 | ||||||
Total credits of in-class work: 2.4 | Total class time hours: 60 | |||||||
Total credits of out of class work: 3.6 | Total hours of out of class work: 90 |
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 |
Laboratory sessions | 22.00% | 22.00% | Compulsory to pass the subject. |
Assessment of problem solving and/or case studies | 8.00% | 8.00% | Using the Moodle platform, the instructor will conduct individual tests about course contents. No Recoverable. |
Final test | 70.00% | 70.00% | The final exam may include problems and questions about theoretical concepts. Minimum grade to pass the subject: 5 points out of 10. |
Total: | 100.00% | 100.00% |
Not related to the syllabus/contents | |
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Hours | hours |
Individual tutoring sessions [PRESENCIAL][Combination of methods] | 8 |
Study and Exam Preparation [AUTÓNOMA][Self-study] | 90 |
Final test [PRESENCIAL][Assessment tests] | 4 |
Laboratory practice or sessions [PRESENCIAL][Practical or hands-on activities] | 8 |
Unit 1 (de 6): Introduction to Materials Engineering and Technology | |
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Activities | Hours |
Class Attendance (theory) [PRESENCIAL][Lectures] | 1 |
Unit 2 (de 6): Manufacturing Processes | |
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Activities | Hours |
Class Attendance (theory) [PRESENCIAL][Lectures] | 7 |
Problem solving and/or case studies [PRESENCIAL][Problem solving and exercises] | 5 |
Unit 3 (de 6): Thermal treatments | |
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Activities | Hours |
Class Attendance (theory) [PRESENCIAL][Lectures] | 5 |
Problem solving and/or case studies [PRESENCIAL][Problem solving and exercises] | 10 |
Unit 4 (de 6): Welding metallurgy | |
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Activities | Hours |
Class Attendance (theory) [PRESENCIAL][Lectures] | 1 |
Unit 5 (de 6): In service behaviour of materials | |
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Activities | Hours |
Class Attendance (theory) [PRESENCIAL][Lectures] | 5 |
Problem solving and/or case studies [PRESENCIAL][Problem solving and exercises] | 5 |
Unit 6 (de 6): Inspection of materials. Non destructive testing | |
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Activities | Hours |
Class Attendance (theory) [PRESENCIAL][Lectures] | 1 |
Global activity | |
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Activities | hours |
Author(s) | Title | Book/Journal | Citv | Publishing house | ISBN | Year | Description | Link | Catálogo biblioteca |
---|---|---|---|---|---|---|---|---|---|
A.J. VÁZQUEZ, J.J. DE DAMBORENEA. | Ciencia e Ingeniería de la superficie de los materiales metálicos | CSIC | 2001 | ||||||
BLACK, J. TEMPLE. | DeGarmo's materials and processes in manufacturing | Wiley | 2008 | ||||||
E. OTERO | Corrosión y degradación de materiales | Síntesis | 1997 | ||||||
E.P. DEGARMO | Materiales y procesos de fabricación | Reverté | 1994 | ||||||
G. Rodríguez, G. Herranz | Apuntes de la asignatura | 2012 | plataforma moodle | https://campusvirtual.uclm.es/ | |||||
I.M. HUTCHINGS | Tribology, Friction and Wear of Engineering Materials | Edward Arnold | 1992 | ||||||
J. M. Montes Martos, F. Gómez Cuevas y J. Cintas Físico | CIENCIA E INGENIERÍA DE LOS MATERIALES | Paraninfo | 978-88428330176 | 2014 | |||||
J. R. DAVIS | SURFACE ENGINEERING FOR CORROSION AND WEAR RESISTANCE | ASM INTERNATIONAL | 978-0871707000 | 2001 | Corrosión, desgaste | ||||
Jose Antonio Puértolas, Ricardo Ríos, Miguel Castro | Tecnología de los Materiales en Ingeniería | Síntesis | 978-84-9077-387-1 | 2016 | |||||
M.K. GROOVER | Fundamentos de Manufactura Moderna | Prentice-Hall | 1997 | ||||||
Massachusetts Institute of Technology | MIT OpenCourseWare | 2012 | http://ocw.mit.edu/courses/materials-science-and-engineering/ | ||||||
R.M. GERMAN | Powder Metallurgy Science | Princeton NJ | 1994 | ||||||
RANDALL M. GERMAN & ANIMESH BOSE | INJECTION MOLDING OF METALS AND CERAMICS | METAL POWDER INDUSTRIES FEDERATION | 978-1878954619 | 1997 | |||||
S. KALPAKJIAN, S. SCHMID | Manufactura, Ingeniería y Tecnología | Pearson Hall. | 2001 | ||||||
Universidad de Liverpool. | Programa MATTER, Materials Teaching Educational Resources | http://www.matter.org.uk/default.htm | |||||||
W.D. CALLISTER | Introducción a la Ciencia e Ingeniería de los Materiales | Reverté | 2004 |