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Instrumentation I

Code: LACI21014     Sigla: I1

Áreas Científicas
Classificação Área Científica
OFICIAL Instrumentação e Me

Ocorrência: 2022/2023 - 1S

Ativa? Yes
Página Web: portal.ips.pt/ests/pt/ucurr_geral.ficha_uc_view?pv_ocorrencia_id=555458
Unidade Responsável: Departamento de Sistemas e Informática
Curso/CE Responsável:

Ciclos de Estudo/Cursos

Sigla Nº de Estudantes Plano de Estudos Anos Curriculares Créditos UCN Créditos ECTS Horas de Contacto Horas Totais
EACI 19 Plano de Estudos 14 2 - 6 75 162

Docência - Responsabilidades

Docente Responsabilidade
José Miguel Costa Dias Pereira

Docência - Horas

Theorethical and Practical : 3,00
Practical and Laboratory: 2,00
Type Docente Turmas Horas
Theorethical and Practical Totais 1 3,00
José Miguel Costa Dias Pereira 3,00
Practical and Laboratory Totais 1 2,00
José Miguel Costa Dias Pereira 2,00

Língua de trabalho

Portuguese

Objetivos

To make the students of the 2nd year of the Degree in Automation Engineering Control and Instrumentation of EST Setúbal learn the fundamental principles of measurement and have the capacity to understand the operation of the most used sensors in the measurement of position, displacement, speed, deformation, pressure and level.

Resultados de aprendizagem e competências

On successful completion of the curricular unit, student will be able to
• Understand the functioning of automatic control systems and specify the function of each of its components.
• Contextualizing the role of instrumentation in an automatic control a system;
• Describe the operation of the main components of a measuring instrument: transducer, signal conditioning circuit, indicators and recorders;
• Specify measuring instruments according to their characteristics;
• Understand the principles of transducers used to measure position, deformation, velocity, acceleration, force and pressure;
• Design instrumentation systems;
• Assemble experiences with the aim of measuring physical quantities and calibrate transducers;
• Interpret and analyze treat experimental results considering the characteristics of the measuring instruments.

Modo de trabalho

Presencial

Pré-requisitos (conhecimentos prévios) e co-requisitos (conhecimentos simultâneos)

Frequency and passing in this course assumes that students have basic knowledge of electrotechnology and electronics.
(Omitted issues respect the legal legislation in force and the internal rules and regulations of the management bodies of ESTSetúbal / IPS).

Programa

1. Instrumentation and measurement units and systems
International System of Units (SI)
Concept of sensor, transducer and actuator
Static and dynamic characteristics of a measuring sensor
Normalized signals of current and pressure
Measurement errors: linearity, hysteresis, offset and gain.
2. Measuring transducers of physical quantities
Position, speed and acceleration (potentiometer, LVDT, LVDC, accelerometer and solve)
Force (extensometers, Hooke's law, Young's modulus and piezo resistors)
Magnetic Field (Hall Effect)
Optics (photoresistance, photodiode and phototransistor)
Tachometer generator and digital tachometer
Encoder (incremental and absolute)
3. Signal conditioning circuits
Wheatstone Bridge (b.C. and Co.)
Wheatstone bridge equilibrium condition (c.c. and c.a.)
Amplification and attenuation
Instrumentation Amplifiers
Transmitters (measurement chain)
Converters (voltage-current)
4. Pressure measurement
Pressure setting
Pressure units and conversions
Absolute, relative and differential pressure
Static, dynamic and total pressure
Barometers, pressure gauges, pressure switches
Liquid and Bourdon column manometer
Manometers of diaphragm (deformation of a membrane)
Load cells (ring and recessed)
Protection of pressure sensors: diaphragm, siphon, sealing
Calibration (dead weight scale)
Specification, selection and installation of pressure sensors
5. Level Measurement
Measurement methods:
Communicating vessel level
Floats and torsion level measurement
Hydrostatic pressure
Resistance
Capacity
Ultra sounds
RADAR
Radioactivity
Gravimetric
Measurement of net interfaces level
Density measurement (constant level)
Specification, selection and installation of level sensors
6. Pneumatic instrumentation
Nozzle system
Pneumatic relay or amplifier
Balance of forces and transmitters
P / I and I / P Converters
PID controller (principle of operation)
Compressors

Bibliografia Obrigatória

Dias Pereira; Theoretical Notes, D.Pereira, 2016
Dias Pereira; Problems Guide, D.Pereira, 2017
Dias Pereira; Laboratory Guide, D.Pereira, 2017

Bibliografia Complementar

daily Reley McConnel; Engineering Measurements, Wiley
William C. Dunn; Fundamental of Industrial Measurements and Process Control, McGraw-Hill
Bela Liptak; Instrument Engineers' Handbook, CRC Press
Douglas M. Considine; Process/Industrial Measurements and Control Handbook, McGraw-Hill

Métodos de ensino e atividades de aprendizagem

The teaching method is based on the presentation of the subject by the teacher, in the resolution of problems and in the accomplishment of laboratory works, that cover the totality of the programmatic contents of the curricular unit.

Tipo de avaliação

Distributed evaluation with final exam

Componentes de Avaliação

Designation Peso (%)
Teste 70,00
Exame 0,00
Participação presencial 10,00
Trabalho escrito 20,00
Total: 100,00

Componentes de Ocupação

Designation Tempo (Horas)
Estudo autónomo 86,00
Frequência das aulas 75,00
Total: 161,00

Obtenção de frequência

The minimum grade in continuous assessment by tests is 8 values ​​in any of the tests.
In situations where the faculty considers it necessary, final grades higher than 16 may be defended in oral exams. If the student does not attend these oral exams, his final classification will be 16 values.

(In the evaluation by final exam or tests, questions related to the laboratory component of the UC are foreseen)
Once approved in continuous assessment, the student will only be able to improve the grade during the appeal period. Attendance and approval in the laboratory component (execution of all work, delivery of results and reports) is mandatory for approval in the UC.

Rules for conducting tests:
• When requested, it is mandatory to present an identification document during the tests.
• Only written tests in EST Setúbal test/exam notebooks are accepted.
• Leaving the room can only take place 30 minutes after the start of the test/exam and implies the final delivery of the test, and the delay in entry cannot, under any circumstances, exceed 15 minutes.
• During the tests, calculators with graphic or alphanumeric capabilities may only be used if the teacher authorizes it.
• During the tests, the handling or display of cell phones (which must be turned off) and other electronic equipment is not allowed, and the use of any of this type of equipment is a reason for cancellation of the test.

Fórmula de cálculo da classificação final

The final grade is calculated according to the following formula:
NF=0.7*EF+0.2*LAB+0.1*DSA;
EF- average classification of the 2 tests or the classification in the final exam;

LAB- laboratory classification (minimum 10 values);

DSA- Classroom performance (includes lab).

In the case of assessment by exam, the grade of the EF component corresponds to the classification obtained in this test, and, as mentioned, the attendance and approval in the laboratory component is mandatory for approval in the UC.

Improved final distributed ranking
The student can improve his final grade obtained by continuous assessment by taking the exam
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