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Air conditioning

Code: LTE31128     Sigla: CL

Áreas Científicas
Classificação Área Científica
OFICIAL Termodinâmca Aplicada

Ocorrência: 2023/2024 - 1S Ícone  do Teams

Ativa? Yes
Unidade Responsável: Departamento de Engenharia Mecânica
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
LTE 29 Plano de Estudos 3 - 6 75 162

Docência - Responsabilidades

Docente Responsabilidade
Miguel Borges Lança

Docência - Horas

Theorethical and Practical : 3,00
Practical and Laboratory: 2,00
Type Docente Turmas Horas
Theorethical and Practical Totais 1 3,00
Miguel Borges Lança 3,00
Practical and Laboratory Totais 2 4,00
Miguel Borges Lança 4,00

Língua de trabalho

Portuguese

Objetivos

Keep in mind and know how to consult the legislation, related to energy systems for air conditioning in buildings. Know the comfort conditions and the parameters that influence them. Identify the various types of HVAC systems, analyze their specificities and applications. Calculate the fundamental elements of an installation and choose the main air conditioning equipment. Know the fundamentals of maintenance, operation and commissioning of equipments.

Resultados de aprendizagem e competências

At the end of the course, students should be able to:
- identify the limits of the conditions of human comfort;
- find in the legislation the information they need regarding requirements for air conditioning equipment and systems, as well as the functions to be performed by each of the various recognised technicians;
- choosing and substantiating a choice of equipment or system for an installation;
- know how the systems and equipment operate;
- Design the main elements of a system.

Modo de trabalho

Presencial

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

As a prerequisite, it is recommended that the Students have successfully completed the disciplines of the scientific areas of Mathematics and Applied Thermodynamics of previous years, namely: Matemática I e II, Termodinâmica, Mecânica dos Fluidos, Aquecimento e Energia Térmica Renovável, Transmissão de Calor e Massa, Manutenção e Máquinas Elétricas.

Programa

1. Introduction to thermal comfort and the need for air conditioning
Conditions of thermal comfort.
Portuguese Legislation and Standards.
Estimated Predicted Mean Vote (PVM) and PPD (Predicted Percentage Dissastisfied).
Indoor Air Quality.
Properties of moist air, considering it as a mixture of perfect gases.
Classification and typology of terminal air conditioning systems.
Classification and typology of thermal production systems.
Typical process of design.

2. Psychometric diagram, Humid Air processes
Properties of ideal gas mixtures.
Heating/ Cooling.
Cooling with Dehumidification.
Humidification.
Evaporative cooling.
Heating with dehumidification.
Sensitive and latent recovery.
Latent heat and sensitive heat.
Sensitive Heat Factor.

3. Air conditioning systems
Definition of Air Conditioning System.
Classification and typology of air conditioning systems .
Different types of central and terminal systems.
Heating with thermal production through boiler.
Operation of a refrigeration installation.
COP and EER.
Cold storage fluids.
Air conditioning by circulation of refrigerant.
Split and multisplit direct expansion units.
Autonomous Conditioning Units.
Air conditioning by water circulation.

4. Centralized thermal production equipment
Chilled water producer groups (chillers): centralised production units. Selection and operating parameters. Units with partial and total heat recovery. Refrigeration circuit of the units mentioned. Variation of the efficiency of the units with the temperature regime. Compact air conditioning units. Energy recovery systems. Accumulation systems.

5. Terminal air conditioning equipment
Air Handling Units (AHU): main modules and their characteristics. Speed of passage in the batteries and loss of charge in the units. Direct expansion coverage units (roof-tops). Terminal units: convectors, fan coil units, cooled ceilings and induction units.
Single and double duct systems. VAV systems. Fan coil systems. Two and four tube systems. VRF system.
Systems with cooled ceilings and induction units.
New air flows in an installation. Outdoor air quality and indoor air quality conditions. Method of ventilation rate and air quality. Sensory evaluation.


6. Aerobic and hydraulic networks
Typical hydraulic networks of interconnection between terminal units and chillers. Networks with direct and inverse return. Regulating valves. Interconnection with cooling towers and AHU. The equilibrium of the water flow of the primary circuit with the secondary circuit. Association of chillers in series and in parallel. Typical speeds in water networks.
Interaction between the network, pump and chiller. Some of the possible problems due to poor balance of a piping network.
Typology of most used pipeline networks.
Design of aerobic pipe networks.
Typical speeds in air pipe networks.
Some of the possible problems due to poor balance of an aerobic network.

7. Methods for Defining Systems
Attribute weighting and function weighting.

Bibliografia Obrigatória

Luís Roriz; Climatização, Concepção, instalação e condução de sistemas, Edições Orion, 2006
Luis Roriz; Climatização em Edifícios – Envolvente e Comportamento Térmico, Edções Orion
ASHRAE; ASHRAE Handbook – Fundamentals (SI)
ASHRAE ; ASHRAE HandBook, Systems and Equipments, 2012
Norma; ISO 7730
Norma; EN 15251
Norma; ASHRAE 55
Norma; EN 13779
Norma; EN 779
Norma; ISO 16890
Norma; ASHRAE 62.1

Bibliografia Complementar

Luiz Roriz, Fernando Lourenço; Sistemas Hidráulicos - Aquecimento Ambiente e Águas Sanitárias

Métodos de ensino e atividades de aprendizagem

TP class of the participatory expositive type. Some TP classes will be used for discussion of real cases. In the laboratory classes there will be follow-up work, thematic work and the realization of laboratory reports.

Tipo de avaliação

Distributed evaluation with final exam

Componentes de Avaliação

Designation Peso (%)
Teste 65,00
Trabalho laboratorial 35,00
Total: 100,00

Componentes de Ocupação

Designation Tempo (Horas)
Frequência das aulas 75,00
Total: 75,00

Obtenção de frequência

Not aplicable

Fórmula de cálculo da classificação final

CF = 0,4 x MNT + 0,3 x TR + 0,25 LAB + 0,05 x ASS


CF = Final Classification

MNT - 2 test grade average

TR - Group or individual work with presentation

LAB - Average grade of laboratory tests

ASS - Note of attendance

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