
Course unit
APPLIED THERMODYNAMICS AND HEAT TRANSFER (Ult. numero di matricola da 0 a 4)
IN06103169, A.A. 2016/17
Information concerning the students who enrolled in A.Y. 2015/16
ECTS: details
Type 
ScientificDisciplinary Sector 
Credits allocated 
Core courses 
INGIND/11 
Environmental Technical Physics 
6.0 
Course unit organization
Period 
First semester 
Year 
2nd Year 
Teaching method 
frontal 
Type of hours 
Credits 
Teaching hours 
Hours of Individual study 
Shifts 
Lecture 
6.0 
48 
102.0 
No turn 
Start of activities 
01/10/2016 
End of activities 
20/01/2017 
Examination board
Board 
From 
To 
Members of the board 
14 2017 Canale 2 
01/10/2017 
30/09/2018 
MORO
LORENZO
(Presidente)
CAMPANALE
MANUELA
(Membro Effettivo)
DI BELLA
ANTONINO
(Supplente)
ROSSETTO
LUISA
(Supplente)

13 2017canale 1 
01/10/2017 
30/11/2018 
DORETTI
LUCA
(Presidente)
MANCIN
SIMONE
(Membro Effettivo)
MORO
LORENZO
(Supplente)

12 2016 canale 1 
01/10/2016 
30/11/2017 
DORETTI
LUCA
(Presidente)
MANCIN
SIMONE
(Membro Effettivo)
MORO
LORENZO
(Supplente)

11 2015 canale 1 
01/10/2015 
30/11/2016 
DORETTI
LUCA
(Presidente)
MANCIN
SIMONE
(Membro Effettivo)
MORO
LORENZO
(Supplente)

10 2015 canale 2 
01/10/2015 
30/11/2016 
DORETTI
LUCA
(Presidente)
MANCIN
SIMONE
(Membro Effettivo)
MORO
LORENZO
(Supplente)

Prerequisites:

Prerequirements for the course are the basic concepts of differential calculus and thermodynamics acquired from the student in the courses of the first year.
It is given for acquired the concepts: energy, power, heat, work, temperature, Carnot's cycle, first law of thermodynamics, perfect gas theory. 
Target skills and knowledge:

The course supplies the engeneering bases with to face the various withins of energy management both on large scale (energy conversion plants) and on small scale (energy requirement of the inhabited structures).
The course presents the main applications to engineering of the Physics course basic concepts (temperature, heat, work etc), the Thermodynamics laws; in particularly will be faced the real thermodynamic cycles (derived from the Carnot's cycle) with attention to the production of electric power and the refrigeration. The course introduces the heat transfer with reference to the applications to the building structures and the heat exchangers used in the conversion plants.
The heat transfer analysis will come moreover finalized to the understanding of the interaction of the human body inside confined system (air conditioning). 
Examination methods:

The examination is based on 2 contextual written tests (that is not separable): a numerical test and a theoretical one with 23 opened questions, final vote in 30th is the sum of the two single tests in 15th.
The positive vote has 1 year validity. Retabling themselves to a new exam and delivering the test the previous ballot is cancelled, withdrawing itself to the test maintains the previous vote. 
Assessment criteria:

The student should demonstrate to master the theoretical learned skills and to know to manage the calculation and design instruments viewed during the course. He should be able to apply the theory to the real engineering cases and in particular to civil applications. 
Course unit contents:

Dimensions and unit systems: fundamental and derived dimensions, International system, Technical system, English system, conversion tables.
APPLIED THERMODYNAMICS
Temperature and zeroth law of thermodynamics.
First law of thermodynamics: heat, work, temperature. System and control volumes, closed and open systems. Examples of reversible process. Internal energy and enthalpy.
Second law of thermodynamics: KelvinPlanck and Clausius statements. Heat engine. Energy efficiency. Carnot cycle. Carnot principles. Clausius equality and disequality. Entropy.
Perfect gases: equation of state. Specific heats for perfect gas. State relations for perfect gas.
Processes for perfect gas: constant pressure, constant volume, isothermal, isoentropic process.
Pure fluids: diagrams of properties. Gibbs relation (free energy). pvT data for pure fluids.
Tv, pv, pT diagram. Saturated vapour, vapour quality. Superheated vapour and subcooled liquid.
hs Mollier diagram. Ts ammonia diagram. ph R134a diagram. Saturation tables.
Vapour power cycles: Rankine cycle, reheat cycle, Hirn cycle.
Gas power cycles: Otto and Diesel cycles. Gas turbine cycle (BraytonJoule cycle).
Reversed cycles: heat pump and refrigeration cycles. Coefficient of Performance. Double compressions cycle.
HEAT TRANSFER
Steady thermal conduction: Fourier's law, substances thermal conductivity. Thermal resistance.
Natural and forced thermal convection: basics and practical parameters use.
Overall heat transfer: overall heat transfer coefficient, building structures application.
Heat exchangers: basic analysis, thermal profiles, tubeintube heat exchanger design. Thermal effectiveness. Log mean temperature difference.
Radiation heat transfer: basics, blackbody radiation fundamental laws, radiation heat transfer between black bodies. View factor. Emissivity. Radiation heat transfer between gray bodies. 
Planned learning activities and teaching methods:

Theoretical frontal lessons and numerical practices necessary for the examination test. 
Additional notes about suggested reading:

Besides the advised texts, the exercises carried out during the lessons, the unit conversion tables, the diagrams, the tables of the fluid properties used during the course will be uploaded and downloadable by Moodle platform. 
Textbooks (and optional supplementary readings) 

Gianni Comini, Stefano Savino, Fondamenti termodinamici dell'energetica (II edizione). Padova: SGE Editoriali, 2014. Testo obbligatorio

Manuela Campanale, Problemi risolti di Fisica Tecnica. Padova: Edizioni Progetto, 2011. Testo consigliato


