Code: | EM0031 | Acronym: | ASI |
Keywords | |
---|---|
Classification | Keyword |
OFICIAL | Automation |
Active? | Yes |
Web Page: | http://moodle.fe.up.pt/view?EM0031 |
Responsible unit: | Automation, Instrumentation and Control Section |
Course/CS Responsible: | Master in Mechanical Engineering |
Acronym | No. of Students | Study Plan | Curricular Years | Credits UCN | Credits ECTS | Contact hours | Total Time |
---|---|---|---|---|---|---|---|
MIEM | 169 | Syllabus since 2006/2007 | 3 | - | 6 | 58,5 | 162 |
This course aims to give an overview on the potentialities of logic control systems and technologies that are related to industrial automation. A special attention to safety issues will be given. This course acts as an introduction to logic controllers, which is especially suitable for Mechanical Engineering students. By the end of the semester, students should be acquainted with technical and scientific concepts that are essential on the development of studies regarding the use of logic control systems in industrial automation. Students should bear in mind all the essential safety measures.
global knowledge of the capabilities of logic control systems and associated technologies in the context of industrial automation.
- Ability to analyze a logic control system integrated in machine
- ability to propose a wired or programmed logic control solution
-recognize the basic requirements of a security system in automatic machines and risk assessment
1. Introduction to industrial automation and safety 2. Continuous and discrete quantities. Quantities and all-or-nothing variables. Boolean algebra 3. Combinational circuits: simplification, description and use of logic functions. 4. The most common binary codes. Unipolar and bipolar codes. A/D and D/A conversion 5. Bistable memories (set reset). Related technologies. 6. Timer: opening and closing delay. Impulse timers. Applications 7. Counters: up counters, down counters and up/down counters. Applications 8. Sequential systems: time diagrams and state diagrams. Summary methods 9. Grafcet (Graphe Fonctionnel de Commande, Etapes Transitions) and hierarchical approach to Grafcet 10. Programming and use of programmable logic controllers (PLCs) - I/O interfaces. Intern organisation. Operation. Variable initiation. Programming languages and programming techniques. Arithmetic instructions and numerical manipulation. Grafcet’s translation in PLCs’ programs. 11. Safety. Main concepts, terminology, normalization, risk management. Devices
This course is divided into two parts: theoretical-practical classes and practical classes. Theoretical-practical classes will cover course’s program (with audiovisual support and simple examples will be given) and be based on critical practice of the themes that have been taught. Subjects held in classes will be selected from dozens of problems that students should solve. However, problem solutions’ won’t be held in classes, but professors will be available to help on that matter. Laboratory classes are intended to increase the contact with technology and tests. If necessary short presentations will be held, in order to contextualize what have been taught in classes. Practical assignments are based on the development of combinational circuits, timers, counters and their application on sequential circuits. The project and circuit development resources include software of logic circuits simulation, integrated circuits, electro mechanics, programmed PLCs in contacts language, functional blocks and Grafcet.
Designation | Weight (%) |
---|---|
Exame | 75,00 |
Participação presencial | 0,00 |
Prova oral | 25,00 |
Total: | 100,00 |
Designation | Time (hours) |
---|---|
Estudo autónomo | 83,50 |
Frequência das aulas | 58,50 |
Trabalho laboratorial | 20,00 |
Total: | 162,00 |
According to General Evaluation Rules of FEUP
Final mark will be based on two written exams (WE1 and WE2) and one assignment (ASN). These components will be assessed from 0 to 20 and they will worth as follows: WE1- an individual written exam in the middle of the semester- 35% of the final mark WE2- an individual written exam at the end of the second semester- 40% of the final mark ASN- an individual laboratory assignment in the last week of the course (exceptions will have to be justified– each student will perform his/her assignment in the laboratory class) – 25% of the final mark. It is not allowed to consult books or notes on the written exams (WE1, WE2), while each exam worth is previously set. The assignment assessment (ASN) will be based on the observation on whether the objectives of the assignment have been reached or not. It will also be based on students’ dexterity with laboratory resources and their ability to answer question that can possibly be asked. Important notes: - Students must achieve a minimum grade of 7 out of 20 in WE1 and WE2. Even if students achieve a grade of 9, 5 out of 20 on WE1, but don’t achieve 7 out of 20 on WE1 and WE2, they will earn a grade of 9 out of 20. - If students miss one of the written exams, they will earn a 0 out of 20. - If students don’t accomplish the laboratory assignment, they will earn a 0 out of 20. - Students can only attend to final exams (WE1, WE2) and to the laboratory assignment if they attend to classes (except students with a special status – according to General Evaluation Rules of FEUP) - Students who failed can repeat one written exam (only one) o Recurso. - The laboratory assignment can only be repeated in exceptional cases
As described in Special Evaluation
Students granted with a special status will be assessed as ordinary students. Exams always comprise two parts: a practical- theoretical (75% of the final mark) one and a laboratory assignment (25% of the final mark). The practical- theoretical exam can either be written or oral, depending on professors’ decision.
Students who successfully complete this course can improve their final mark by repeating one (only one) of the written exams in Recurso, or they can be assessed later instead.