1. General information
Course:
STRENGTH OF MATERIALS
Code:
56310
Type:
CORE COURSE
ECTS credits:
6
Degree:
415 - UNDERGRADUATE DEGREE PROGRAMME IN ELECTRICAL ENGINEERING
Academic year:
2023-24
Center:
303 - E.DE INGENIERÍA INDUSTRIAL Y AEROESPOACIAL DE TOLEDO
Group(s):
40
Year:
2
Duration:
First semester
Main language:
Spanish
Second language:
English
Use of additional languages:
English Friendly:
Y
Web site:
https://campusvirtual.uclm.es/
Bilingual:
N
Lecturer:
SERGIO HORTA MUÑOZ
- Group(s):
40
Building/Office
Department
Phone number
Email
Office hours
Sabatini / Despacho 1.05
MECÁNICA ADA. E ING. PROYECTOS
926052830
Sergio.Horta@uclm.es
In person: timetable will be published at the beginning of the semester.
Online: permanently on the Virtual Campus (Moodle Platform), Teams and at the email address Sergio.Horta@uclm.es. The tutorial schedule will be published at the address: https://www.uclm.es/toledo/eiia/informacion_academica/
Lecturer:
JOSÉ MARÍA REVERTE PALOMINO
- Group(s):
40
Building/Office
Department
Phone number
Email
Office hours
MECÁNICA ADA. E ING. PROYECTOS
JoseMaria.Reverte@uclm.es
Lecturer:
MARIA DEL CARMEN SERNA MORENO
- Group(s):
40
Building/Office
Department
Phone number
Email
Office hours
Sabatini / Despacho 1.05
MECÁNICA ADA. E ING. PROYECTOS
926052569
mariacarmen.serna@uclm.es
In person: timetable will be published at the beginning of the semester.
Online: permanently on the Virtual Campus (Moodle Platform), Teams and at the email address mariacarmen.serna@uclm.es. The tutorial schedule will be published at the address: https://www.uclm.es/toledo/eiia/informacion_academica/
2. Pre-Requisites
The student must have acquired the knowledge taught in the subjects of mathematics and physics.
3. Justification in the curriculum, relation to other subjects and to the profession
This subject provides the student with the skills to carry out the professional activity of Industrial Technical Engineer related to the fundamental concepts of structural calculation.
4. Degree competences achieved in this course
| Course competences | |
|---|---|
| Code | Description |
| 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 |
| CEC08 | Knowledge and use of the principles of the resistance of materials. |
| CG03 | Knowledge of basic and technological subjects to facilitate learning of new methods and theories, and provide versatility to adapt to new situations. |
| CG04 | Ability to solve problems with initiative, decision-making, creativity, critical reasoning and to communicate and transmit knowledge, skills and abilities in the field of industrial engineering. |
| CT02 | Knowledge and application of information and communication technology. |
| CT03 | Ability to communicate correctly in both spoken and written form. |
5. Objectives or Learning Outcomes
| Course learning outcomes | |
|---|---|
| Description | |
| Ability to dimension simple structural elements | |
| Ability to calculate the stress distribution in a cross-section. | |
| Knowledge of when a real solid can be studied by means of two simplifications, geometric and materia | |
| Acquisition of manual techniques for calculating displacements and forces in structural elements. | |
| Study of one-dimensional solids (bars and beams) made of a material that behaves in the elastic range. | |
| Additional outcomes | |
| Not established. |
6. Units / Contents
-
Unit 1: Calculation of structures formed by one-dimensional elements. Structures of joint nodes and rigid nodes.
-
Unit 2: Calculation of reactions and internal forces in statically determinate (isostatic) structures.
-
Unit 3: Methods for computing rotations and displacements. Strains and Euler-Bernoulli Beam equation.
-
Unit 4: Calculation of reactions and internal forces in statically indeterminate structures.
-
Unit 5: Normal and shear stresses in bending. Combination of internal forces.
-
Unit 6: Torsion.
-
Unit 7: Buckling. Euler's theory.
7. Activities, Units/Modules and Methodology
| Training Activity | Methodology | Related Competences (only degrees before RD 822/2021) | ECTS | Hours | As | Com | Description | |
| Class Attendance (theory) [ON-SITE] | Combination of methods | CB02 CB03 CB04 CB05 CEC08 CG03 CG04 | 1.36 | 34 | N | N | Development of theoretical contents in classroom, using the participatory lecture method. Group tutorials, direct teacher-student interaction. Resolution of exercises and problems in the classroom in a participatory way. | |
| Problem solving and/or case studies [ON-SITE] | Problem solving and exercises | CB02 CB03 CB04 CB05 CEC08 CG03 CG04 CT02 CT03 | 0.28 | 7 | N | N | Resolution of exercises and problems in the classroom in a participatory way. | |
| Class Attendance (practical) [ON-SITE] | Practical or hands-on activities | CB02 CB03 CB04 CB05 CEC08 CG03 CG04 CT02 CT03 | 0.6 | 15 | Y | N | Laboratory practices and/or in the computer room, with the use of specific software for calculating structures. | |
| Formative Assessment [ON-SITE] | Assessment tests | CB02 CB03 CB04 CB05 CEC08 CG03 CG04 CT03 | 0.16 | 4 | Y | Y | Follow-up and final tests. | |
| Study and Exam Preparation [OFF-SITE] | Self-study | CB02 CB03 CB04 CB05 CEC08 CG03 CG04 CT02 CT03 | 3.6 | 90 | N | N | Personal study of theory and problems. Resolution and delivery of theoretical-practical work in groups. | |
| 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).
8. Evaluation criteria and Grading System
| Evaluation System | Continuous assessment | Non-continuous evaluation * | Description |
| Laboratory sessions | 15.00% | 15.00% | C: Test to monitor the student's learning. Recoverable. NC: exam related to the practical sessons, taken on the day of the final exam. |
| Projects | 15.00% | 15.00% | C: Theoretical-practical exercises to be solved in groups. Recoverable. NC: Delivery of the theoretical-practical exercises on the day of the final exam. |
| Final test | 70.00% | 70.00% | C: final test that will consist of theoretical questions and/or problems. Recoverable. NC: final test that will consist of theoretical questions and/or problems. The minimum grade for this part to be compensable will be 4 points (out of 10) |
| Total: | 100.00% | 100.00% |
According to art. 4 of the UCLM Student Evaluation Regulations, it must be provided to students who cannot regularly attend face-to-face training activities the passing of the subject, having the right (art. 12.2) to be globally graded, in 2 annual calls per subject , an ordinary and an extraordinary one (evaluating 100% of the competences).
Evaluation criteria for the final exam:
-
Continuous assessment:Final exam (E): Test that will consist of theoretical questions and/or problems. To pass the subject it will be necessary to obtain a minimum grade of 4 in the final test (70%)
Work (P): Theoretical-practical exercises to be solved individually and/or in a group (15%)
Laboratory practices (L): Test that will consist of theoretical questions and/or problems. It will be held on a date associated with laboratory practices (15%)
It will be considered that the student has passed the subject if, being E >= 4 and calculating the final grade as Final Grade = E*0.7+ P*0.15 + L*0.15, the Final Grade is greater than or equal to 5. In case of that E < 4, the final grade cannot be higher than 4. -
Non-continuous evaluation:A Single Test (ST) will be carried out that will consist of theoretical questions and/or problems that will include the competencies evaluated in the Final Exam and in the Laboratory Practices (70% + 15%).
To assess the competencies evaluated in the Project (15%), either the student will be asked to submit assignments or an additional test with theoretical-practical questions and/or exercises to be solved in computer room.
The Final Grade of the subject will be obtained as NF=0.85*ST+0.15*P, being necessary a Final Grade greater than or equal to 5 to pass the subject.
Specifications for the resit/retake exam:
A Single Test (ST) will be carried out that will consist of theoretical questions and/or problems that will include the competencies evaluated in the Final Exam and in the Laboratory Practices (70% + 15%).
To assess the skills evaluated in the Project(15%): The student who requests it will keep the grade obtained in the Work of the ordinary call. The student who chooses not to keep the grade obtained in the Work in the ordinary call, will either be asked to submit work or an additional test with theoretical-practical questions and/or exercises will be carried out on the same day of the Single Test. Solve in the computer room.
The Final Grade of the subject will be obtained as NF=0.85*ST+0.15*P, being necessary a Final Grade greater than or equal to 5 to pass the subject.
To assess the skills evaluated in the Project(15%): The student who requests it will keep the grade obtained in the Work of the ordinary call. The student who chooses not to keep the grade obtained in the Work in the ordinary call, will either be asked to submit work or an additional test with theoretical-practical questions and/or exercises will be carried out on the same day of the Single Test. Solve in the computer room.
The Final Grade of the subject will be obtained as NF=0.85*ST+0.15*P, being necessary a Final Grade greater than or equal to 5 to pass the subject.
Specifications for the second resit / retake exam:
A Single Test (ST) will be carried out that will consist of theoretical questions and/or problems that will include the competencies evaluated in the Final Exam and in the Laboratory Practices (70% + 15%).
To assess the competencies evaluated in the Project (15%): The student who requests it will keep the grade obtained in the Work of the ordinary call of the last academic year that he has completed. The student who chooses not to keep the grade obtained in the Work in the ordinary call, will either be asked to submit work or an additional test with theoretical-practical questions and/or exercises will be carried out on the same day of the Single Test. Solve in the computer room.
The Final Grade of the subject will be obtained as NF=0.85*ST+0.15*P, being necessary a Final Grade greater than or equal to 5 to pass the subject.
To assess the competencies evaluated in the Project (15%): The student who requests it will keep the grade obtained in the Work of the ordinary call of the last academic year that he has completed. The student who chooses not to keep the grade obtained in the Work in the ordinary call, will either be asked to submit work or an additional test with theoretical-practical questions and/or exercises will be carried out on the same day of the Single Test. Solve in the computer room.
The Final Grade of the subject will be obtained as NF=0.85*ST+0.15*P, being necessary a Final Grade greater than or equal to 5 to pass the subject.
9. Assignments, course calendar and important dates
| Not related to the syllabus/contents | |
|---|---|
| Hours | hours |
| Class Attendance (theory) [PRESENCIAL][Combination of methods] | 34 |
| Problem solving and/or case studies [PRESENCIAL][Problem solving and exercises] | 7 |
| Class Attendance (practical) [PRESENCIAL][Practical or hands-on activities] | 15 |
| Formative Assessment [PRESENCIAL][Assessment tests] | 4 |
| Study and Exam Preparation [AUTÓNOMA][Self-study] | 90 |
| Global activity | |
|---|---|
| Activities | hours |
10. Bibliography and Sources
