Identifying Data 2019/20
Subject (*) Advanced manufacturing techniques Code 730G04075
Study programme
Grao en enxeñaría en Tecnoloxías Industriais
Descriptors Cycle Period Year Type Credits
Graduate 2nd four-month period
Fourth Optional 6
Language
Spanish
Teaching method Face-to-face
Prerequisites
Department Enxeñaría Naval e Industrial
Coordinador
Nicolas Costa, Gines
E-mail
gines.nicolas@udc.es
Lecturers
Amado Paz, José Manuel
Nicolas Costa, Gines
Ramil Rego, Alberto
Yañez Casal, Armando Jose
E-mail
jose.amado.paz@udc.es
gines.nicolas@udc.es
alberto.ramil@udc.es
armando.yanez@udc.es
Web
General description O obxectivo desta materia é facer unha breve introdución aos fundamentos da tecnoloxía láser e as súas principais aplicacións na industria, incidindo especialmente nas aplicacións dispoñibles no noso laboratorio.
A orientación da docencia ten un alto contido práctico e de inicio á investigación que se desenvolve mediante un traballo tutelado.
Contingency plan

Study programme competencies
Code Study programme competences
B5 CB5 Que os estudantes desenvolvan aquelas habilidades de aprendizaxe necesarias para emprenderen estudos posteriores cun alto grao de autonomía
B7 B5 Ser capaz de realizar unha análise crítica, avaliación e síntese de ideas novas e complexas
B9 B8 Adquirir unha formación metodolóxica que garanta o desenvolvemento de proxectos de investigación (de carácter cuantitativo e/ou cualitativo) cunha finalidade estratéxica e que contribúan a situarnos na vangarda do coñecemento

Learning aims
Learning outcomes Study programme competences
Knowledge of the fundamentals and technological aspects of new fabrication processes Knowledge of the laser Analysis, critical evaluation and synthesis of the mentioned technologies B5
B7
B9

Contents
Topic Sub-topic
Manufacturing processes with high energy density beams Laser technology (fundamentals, systems, applications, security)
Materials processing with other techniques
Additive manufacturing processes Laser cladding
3D printing
Micromanufacturing Laser ablation
X-ray lithography
Focused ion beam
Monitoring techniques and process control Review of the different techniques of interferometry, holography, speckle and scattering
Applications to the measurements of displacements, form defects, superficial characterization and velocimetry
Analytical and characterization techniques based on laser spectroscopy: laser induced fluorescence, laser induced plasma spectroscopy

Planning
Methodologies / tests Competencies Ordinary class hours Student’s personal work hours Total hours
Guest lecture / keynote speech B5 B7 B9 21 42 63
Laboratory practice B5 B7 14 28 42
Supervised projects B5 B7 B9 7 35 42
 
Personalized attention 3 0 3
 
(*)The information in the planning table is for guidance only and does not take into account the heterogeneity of the students.

Methodologies
Methodologies Description
Guest lecture / keynote speech Theoretical lessons
Laboratory practice Session of laboratory practices of each of the thematic blocks
Supervised projects Realization of a bibliographic, theoretical, numerical and/or practical work

Personalized attention
Methodologies
Supervised projects
Guest lecture / keynote speech
Laboratory practice
Description
Doubts resolution of the theory and practical works. A supervisor will be assigned to each student.

Assessment
Methodologies Competencies Description Qualification
Supervised projects B5 B7 B9 A memory of work will be presented and defended in front of professors and students of the course. 100
 
Assessment comments
<p> It is required to attend 75% of the lectures and all the laboratory practices. </p>

Sources of information
Basic James Brown (1998). Advanced machining technology Handbook. New York: McGraw-Hill
Pere Molera (1989). Electromecanizado. Electroerosión y mecanizado electroquímico. Barcelona: Marcombo
Toru Yoshizawa (ed) (2009). Handbook of optical metrology : principles and applications. CRC Press (Boca Raton)
William M. Steen, Jyotirmoy Mazumder (2010). Laser material processing. Springer
Leonard R. Migliore (1996). Laser materials processing. Marcel Dekker
Demtröder, Wolfgang (1996). Laser spectroscopy basic concepts and instrumentation. Berlin: Springer
J. Paulo Davim (ed) (2008). Machining-Fundamentals and recent advances. London: Springer-Verlag
J. Paulo Davim, Mark J. Jackson (ed) (2009). Nano and micromachining. John Wiley & Sons

Complementary D.A. Cremers y L.J. Radziemski (2006). Handbook of Laser-induced Breakdown Spectroscopy. Chichester: Wiley
Telle, Helmet H. (2007). Laser chemistry: spectroscopy, dynamics and applications . West Sussex, John Wiley &amp; Sons
Peter Hering, Jan Peter Lay, Sandra Stry (2004). Laser in environmental and life sciences: modern analytical methods. Springer
P. Schaaf (ed) (2010). Laser processing of materials. Springer
J.P. Singh y S.N. Thakur (2006). Laser-induced Breakdown Spectroscopy. Amsterdam: Elsevier Science BV
Maximilian Lackner (ed) (2008). Lasers in chemistry. Wiley-VCH
John Dowden (ed.) (2009). The theory of laser materials processing. Springer


Recommendations
Subjects that it is recommended to have taken before

Subjects that are recommended to be taken simultaneously

Subjects that continue the syllabus

Other comments

Débese de facer un uso sustentable dos recursos e a prevención de impactos negativos sobre o medio natural



(*)The teaching guide is the document in which the URV publishes the information about all its courses. It is a public document and cannot be modified. Only in exceptional cases can it be revised by the competent agent or duly revised so that it is in line with current legislation.