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31006 - Environmental Technical Physics

Academic Year 2022/2023

                
                        Docente:
                        Massimo Garai
                    
                        Credits:
                        6
                    
                        SSD:
                        ING-IND/11
                    
                        Language:
                        Italian
                    
                        Teaching Mode:
                        Traditional lectures
                        
                            Campus:
                            Bologna
                        
                            Corso:
                            First cycle degree programme (L) in
                            Architecture-Engineering (cod. 5695)

                            Teaching resources on Virtuale
                        
                                    Course Timetable
                                
from Sep 16, 2022 to Dec 19, 2022

Learning outcomes

At the end of the course the student has the knowledge and tools to design buildings considering the aspects relating to comfort, energy saving and the environment.

Course contents

THERMODYNAMICS

1.1 Introduction.
Introduction to Thermodynamics. System of units.
Principle zero of Thermodynamics. Thermometry.

1.2 First and second principle.
First principle of Thermodynamics for closed systems.
Second principle of Thermodynamics for closed systems:
statement by Kelvin-Planck, Clausius and their equiv ale nce.
The Carnot machine.
Irreversibility of natural phenomena.
Entropy and lost work. Thermodynamic temperature.

1.3 Open systems.
Mass balance for open systems.
Energy balance for open systems.
Practical examples.
Pressure drop. The chimney formula.

1.4 Pure substances, diagrams and cycles.
p-v-T surface for pure substances. The Gibbs rule.
Saturated vapours. Thermodynamic diagrams.
Rankine cycle. Basic refrigeration cycle. Heat pumps.

1.5 Air and vapour mixtures.
Description of air and vapour mixtures. Psychrometric transformations.
Basics of environmental control.
Measurement of relative humidity.

2. HEAT TRANSFER

2.1 Conduction.
Fourier law. Fourier equation.
Steady state solutions: plane layer, cylindric layer.
Critical radius.
Electric analogy and its limits.
Measurement of thermal conductivity.
Materials for the thermal insulation.

2.2 Convection.
Coefficient of convection.
Dimensional analysis and similarity.
Forced, natural and mixed convection.
Cooling by natural convection.
Dynamic and thermal boundary layer.

2.3 Radiation.
Basic definitions. Black and grey bodies.
Laws of Stefan-Boltzmann, Planck, Wien, Lambert, Kirchhoff.
Energy exchange between surfaces.
Solar radiation.

2.4 Combined heat transfer.
Global coefficient of heat transfer.
Heat exchangers.

2.5 Hygrometry
Water vapour balance in building stuctures.
Risk of condensation in building structures.
Glaser diagram.

Readings/Bibliography

Y.A. Çengel, Termodinamica e Trasmissione del calore, McGraw-Hill, Milano, 5^a ed. (2022). (mandatory reading)

S. Lazzari, B. Pulvirenti, E. Rossi di Schio, Esercizi risolti di termodinamica, moto dei fluidi e termocinetica, Esculapio, Bologna (2004). (suggested for additional exercises)

V. Corrado, E. Fabrizio, Applicazioni di termofisica dell'edificio e climatizzazione, Ed. CLUT, Torino (2005). (suggested for additional exercises)

A. Magrini, L. Magnani, La progettazione degli impianti di climatizzazione negli edifici, Ed. EPC Libri, Roma, 2a ed. (2010). (suggested as a further reading on HVAC services)

Teaching methods

During the lessons all the contents of the course will be treated. The lessons will be complemented by numerical exercises, solved step by step, which are an essential part of the course.

Assessment methods

The exam is composed of preliminary written test and a subsequent oral part.

The written test always include the solution of a numerical problem like those shown during the lessons. This is useful to verify the student's ability to apply the learned methods and tools to modelize a given situation, calculate the results ad interpret their meaning.

Only the students who passed the written test are admitted to the subsequent oral part.

Students who did not pass the written test must try again the full exam (written and oral) in another date.

The questions aim to ascertain two main didactic objectives:

the full knowledge of the theoretical concepts and methods presented to the classroom;
the ability to use these tools to solve problems in the engineering field.

The exam will be in presence. Should an on line exam becomes obligatory, the students must prepare in advance their workplace, following the instructions available on the teacher's web site.

Teaching tools

PC projector.

PDF copy of all slides shown during lessons downloadable from https://virtuale.unibo.it.

Links to further information

http://acustica.ing.unibo.it/indexfta.html

Office hours

See the website of Massimo Garai

SDGs

This teaching activity contributes to the achievement of the Sustainable Development Goals of the UN 2030 Agenda.