The subject is part of the Basic Formation module and establishes the basic foundations for the development of spatial vision skills and standardized techniques in Industrial Drawing. To achieve this goal, both traditional and computer tools will be used.



The main objective of this course is to provide the fundamentals of graphic representation systems, computer-aided design, reverse engineering, and 3D printing applied in the field of biomedical engineering.



Students will develop geometric concepts in space and learn to communicate (reading-writing processes) through graphic, precise and universal language. In addition, the fundamentals for capturing and recording geometric information through reverse engineering (3D scanning) will be established and the main rapid prototyping techniques will be analysed.



Among the tools that will be used are: freehand drafting, classic drawing instruments (compass, square and bevel), Computer Aided Design systems, 3D structured light scanners and 3D printers.

The knowledge taught in this subject will be used in the following subjects of the degree:



- Analysis of Mechanical Systems.

- Biomedical Image Processing.

- Biomedical Instrumentation.

- Biomedical Equipment.

- Robotics.

GENERAL COMPETENCES



- G003: Knowledge in basic and technological subjects, which enable to learn new methods and theories, and provide versatility to adapt to new situations.



- G004: Knowledge for the realization of measurements, calculations, assessments, appraisals, expert reports, studies, reports, task planning and other similar work.



TRANSVERS COMPETENCES



- T001: Ability to solve problems with initiative, decision making, creativity and critical reasoning, respecting the principles of universal accessibility and design for all people.



- T009: Capacity for autonomous learning and recognize the need for continuous training.



SPECIFIC COMPETENCES



- M01FB05: Capacity for spatial vision and knowledge of graphic representation techniques, including traditional methods of metric geometry and descriptive geometry, and computer-aided design applications.



LEARNING RESULTS



- RAG7: The graduate will be able to identify the concepts and techniques of the basic and technological subjects of engineering (drawing, computer science, electronics, electricity, mechanics, automation, communication technologies, energy) that enable him/her to learn new methods and theories and provide versatility to adapt to new situations.



- RAG9: The graduate will be able to perform measurements, calculations, valuations, appraisals, appraisals, surveys, studies, reports or similar work in the field of biomedical engineering.



- RAG10: The graduate will be able to interpret the specifications, regulations and mandatory standards in the field of biomedical engineering.



- RAT1: The graduate will be able to solve problems with initiative, decision making, creativity and critical reasoning.



- RAT6: The graduate will be able to acquire new knowledge and skills, recognizing the need for continuing education.

Summarized Program:

- Topic 1. Descriptive Geometry. Introduction to Representation Systems. Methods of Resolution of the Dihedral System. Metric and position problems.

- Topic 2. Industrial Drawing. Basic Standardization and Sizing Principles. Tolerances, Fits and Surface Finishes.

- Topic 3. Elementary Mechanical Functions. Detachable Joining Systems and Metal Structures.

- Topic 4. Applications of Computer-Aided Design in Biomedical Engineering.

- Topic 5. Reverse Engineering & Rapid Prototyping.

Theoretical and practical lectures alternate, maintaining the proportion between theory and practice.



Lectures: Theoretical presentations to convey the basic concepts of the subject, including the formulation of problems and the discussion of their possible solutions.



Classroom and Computer Practices: Resolution of practical exercises for the consolidation and deepening of the conceptual foundations and for the use of auxiliary means in the representation of technical drawings. Competency integration exercises are included.

• Continuous Assessment System
• Final Assessment System
• Tools and qualification percentages:
  • Written test to be taken (%): 50
  • Realization of Practical Work (exercises, cases or problems) (%): 40
  • Individual works (%): 10

The evaluation of the subject will be performed continuously by adding the following items with the following weightings:



- Written Test = Midterm Exam (10%) + Final Exam (40%)

- Practices 40%

- Assignments 10%



Both the Midterm Exam and the Final Exam will be individual and will be performed with traditional drawing tools.



To pass the subject, it is required to have obtained a passing grade (50% of the value) in the Written Test, which can be obtained by adding the marks of both exams (Midterm and Final).



In the case that a student does not exceed the required 50% in the Written Test, the maximum grade that may appear in the ordinary certificate record will be 4.5 out of 10.



RENUNCIATION OF THE CONTINUOUS EVALUATION



The renunciation of the continuous evaluation must be made by submitting a written document, prepared for this purpose, to the Department of Graphic Expression and Engineering Projects Secretary’s office before week 9 as indicated in the UPV/EHU evaluation regulations.



Those students who renounce to the continuous evaluation must accredit the achievement of the knowledge and skills of the entire subject through the Final Written Test (40% of the final grade) and a Complementary Test (60% of the final grade). The Complementary Test may incorporate theoretical developments, practical written or computer-based exercises.



RENUNCIATION OF THE CALL



Failure on attending the Written Test on the date and time of the official examination’s call will automatically imply the resignation of the call.

The evaluation of the subject in the extraordinary call will be performed through the Final Evaluation mechanism, which consists of the following tests carried out individually on the day of the official exam’s call:



- Written Test = Final Exam (50%)

- Complementary Test (50%)



The students who did not renounced to the continuous evaluation in the ordinary call will maintain the score associated with the practices and assignments (50%), so they will not have to attend to the Complementary Test. In any case, if a student wants to evaluate the 100% of the subject, he/she will have to request it by submitting a written document, prepared for this purpose, to the Department of Graphic Expression and Engineering Projects Secretary’s office, at least one month before the official call for the Final Written Test.



To pass the subject, it is required to obtain a passing grade (50% of the value) in the Written Test. If this threshold is not exceeded, the maximum mark that may appear in the extraordinary call’s certificate record by adding the above mechanisms will be 4.5 out of 10.



RENUNCIATION OF THE CALL



Failure on attending the Written Test on the date and time of the official examination’s call will automatically imply the resignation of the call.

Basic bibliography

- Dibujo Técnico. Sistemas de Representación < Zorrilla, E. y Muniozguren, J > Servicio de Publicaciones ETSI-Bilbao

- Dibujo de Ingeniería < Zorrilla, E. y Muniozguren, J > Servicio de Publicaciones ETSI-Bilbao

- Normalización Básica. Dibujo Técnico < Zorrilla, E. y Muniozguren, J > Servicio de Publicaciones ETSI-Bilbao

- Ejercicios Prácticos de Gráficos de Ingeniería < varios autores > Servicio de Publicaciones ETSI-Bilbao

- Ejercicios Prácticos de Ampliación de Gráficos de Ingeniería < varios autores > Servicio de Publicaciones ETSI-Bilbao

- Manual de Normas UNE sobre Dibujo < AENOR >

- Dibujo de Ingeniería Industrial < Urraza, G. y otros > ARTE KOPI S.L.

- Dibujo Industrial < Félez, J. y Martínez, M.L. > Editorial Síntesis

- Sistemas de Representación. Sistema Diédrico (Tomo I) Ediciones TEXGRAF

- Diédrico Directo (Tomos I y II) < Giménez Peris, V. > Tip. Mazuelos S.L.

- Fundamentos de Dibujo en Ingeniería PRENTICE-HALL

- Dibujo y diseño en ingeniería McGraw-Hill

- Dibujo en Ingeniería y Comunicación Gráfica McGraw-Hill

- cadcam < Barry Hawkes > Edit. Paraninfo

- Reverse Engineering. An Industrial Perspective

- Curves and surfaces for Computer Aided Design

- Advance Manufacturing Technologies for Medical Applications

- Wohlers Report. Additive Manufacturing State of Industry

In-depth bibliography

- Geometría Descriptiva. < Leighton Wellman, B. > Editorial Reverté S.A.
- Geometría Constructiva Aplicada a la Técnica. < Hohemberg, F. > Editorial Labor, S.A.
- Geometría Descriptiva Práctica. < Grant Hiran, E.> Ediciones del Castillo, S.A.
- Geometría descriptiva superior y aplicada Edit. Dossat, S.A.
- Ejercicios de geometría descriptiva I (sistema diédrico) ORYMU
- Ejercicios de geometría descriptiva II (acotado y axonométrico) ORYMU
- Dibujo Técnico. < Bachmann, A. y Forberg, R. > Edit. Labor
- Dibujo Industrial. < Chevalier, A. > Grupo Noriega Editores
- Engineering Drawing and Graphic Technology < French, T.E. et all > McGraw-Hill
- Engineering Graphics < F.E. Giesecke, F. E. et all > MacMillan Publishing Company
- Fundamental of Interactive Computer Graphics. < Foley, J.D. and Van Dan, A. > Addison Wesley
- Computational Geometry for Design ad Manufacture. < Faux, I.D. and Pratt, M.J. > Ellis Horwood
- Geometric Modeling. < Mortenson, M.E. > John Wiley & Sons
- Engineering Drawing & Design DELMAR
- CAD/CAM Theory and Practice. < Ibrahim Zeid > McGraw-Hill
- Self-Referenced Hand-Held Range Sensor
- Principles of Computer Automated Fabrication
- Rapid Prototyping System: Fast Track to Product Realization
- Proceedings of the 3rd. European Conference on Rapid Prototyping and Manufacturing, The University of Nothingham.
- Automated Fabrication: Improving Productivity in Manufacturing