Study-unit APPLIED SCIENCES FOR DESIGN A
| Course name | Design |
|---|---|
| Study-unit Code | A002527 |
| Location | PERUGIA |
| Curriculum | Comune a tutti i curricula |
| Lecturer | Bruno Brunone |
| CFU | 10 |
| Course Regulation | Coorte 2023 |
| Supplied | 2023/24 |
| Supplied other course regulation | |
| Type of study-unit | Opzionale (Optional) |
| Type of learning activities | Attività formativa integrata |
| Partition |
INDUSTRIAL TECHNICAL PHYSICS
| Code | A000258 |
|---|---|
| Location | PERUGIA |
| CFU | 5 |
| Lecturer | Cinzia Buratti |
| Lecturers |
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| Hours |
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| Learning activities | Base |
| Area | Formazione tecnologica |
| Sector | ING-IND/10 |
| Type of study-unit | Opzionale (Optional) |
| Language of instruction | Italian |
| Contents | The course of Industrial Applied Physics offers learners teaching units aimed at learning the propertise of the materials when interacting with heat, sound, light, and environmental conditions, and their impact on the environment. It will include the main modes of heat transfer and related applications in the construction field. The course also proposes the study and analysis of indoor comfort, the characteristics of the building materials and the related measurement methods. Finally, the main theoretical aspects related to architectural acoustics and lighting technology will be discussed in relation to Interior Design, Exhibit Design or Retail Design. |
| Reference texts | ¿ Mauro Felli, Lezioni di Fisica Tecnica I, Termodinamica, macchine, impianti a cura di Francesco Asdrubali, Ed. Morlacchi ¿ Mauro Felli, Lezioni di Fisica Tecnica II, Trasmissione del calore, Acustica, Tecnica dell'Illuminazione, a cura di Cinzia Buratti, Ed. Morlacchi. Slides from the lessons |
| Educational objectives | The main objective of the course is to provide learners with theoretical knowledge and practical skills for the analysis of these phenomena and the recognition of the effects they cause on human health. The main knowledge acquired will be: - theory of heat transfer - material properties and related measurement methods - theory and phenomenology of the internal and external microclimate of buildings - basic elements of the different environmental phenomenologies and their effects on human health - techniques of acoustic analysis and lighting in interiors and exteriors of buildings. The main skills acquired will be: - evaluate the principles of thermodynamics and the related application consequences - analyze the main heat exchange mechanisms - assess the quality of the internal environments and the microclimatic characteristics of the same - evaluate the characteristics and the main acoustic and lighting engineering parameters and their effect on human health. |
| Prerequisites | As for recommended preparatory steps |
| Teaching methods | The course is divided into: 1) Theoretical lessons 2) Application exercises |
| Other information | n.a. |
| Learning verification modality | The exam is a written test and an oral discussion concerning the program |
| Extended program | 0. SI UNIT OF MEASUREMENT 1. MATERIALS AND HEAT 1.1 Heat transmission methods (chap. 1 - Felli 2) 1.2 Thermal properties of materials (Felli 2) 1.2.1 Thermal conductivity and diffusivity (2.4, 5.6, slides) 1.2.2 Heat transmitted by conduction 1.2.3 Fourier postulate (2.1, 2.2) 1.2.4 Emission and absorption properties of bodies (4.1, 4.2 and 4.4) 1.2.5 Kirchhoff principle and black body (4.5 and 4.6) 1.2.6 Heat transmitted by radiation 1.2.7 Radiant properties of bodies (4.7) – Greenhouse effect (4.8) 1.2.8 Convection (3.1, 3.3, 3.4); Heat transmitted by convection and formulas for calculating hc 1.2.9 Adduction (5.1) 1.2.10 Transmittance of a wall, cavities, glass walls (5.2, 5.3 and 5.5) 1.3 Standard materials (conductors, insulators, building materials) 1.4 Innovative materials (aerogel, recycled materials, PCMs) 1.5 Measurements of thermal properties (slides) 1.5.1 Conductivity measurements 1.5.2 Transmittance measurements 1.5.3 Specific heat measurements 1.5.4 Measurements of radiant properties 2. THE MATERIALS AND THE SOUND (chapters 8, 9 and 10 - Felli 2) 2.1 Physical acoustics and acoustic sensation 2.1.1 The organ of hearing (9.1) 2.1.2 Acoustic quantities and spectra (8.2, 8.3) 2.1.3 The normal audiogram (9.4) 2.1.4 Sound absorption and sound insulation (synthesis 8.4, 8.5 and 8.6) 2.2 Room Acoustics 2.2.1 Reverberation (10.2) 2.2.2 Acoustic quality of rooms and acoustic design (10.3 and 10.4) 2.3 Acoustic properties of materials 2.3.1 Absorption coefficient (2.4, 5.6, slides) 2.3.2 Noise Reduction Index (4.7) 2.4 Standard materials (solutions available on the market) 2.5 Innovative materials (aerogel, recycled materials) 2.6 Measurements of acoustic properties (slides) 2.6.1 Sound absorption measurements (impedance tube and reverberation chamber) 2.6.2 Acoustic insulation measures (impedance tube and coupled reverberation chambers) 3. MATERIALS AND LIGHT (chapters 11, 12 and 13 - Felli 2) 3.1 The visual sensation 3.1.1 The organ of sight (11.1) 3.1.2 The visibility curve (11.2) 3.1.3 Photometric quantities (11.4) 3.2 Colorimetry (slides) 3.2.1 Chromatic coordinates 3.2.2 Grassmann's laws 3.2.3 Color rendering 3.3 Optical properties of materials 3.3.1 Transmission, absorption and reflection coefficient (see 1.4.2) 3.4 Standard materials (float and low-emissivity glass, double glazing, polycarbonates, translucent materials, etc.) 3.5 Innovative materials (aerogel, ..) 3.6 Measurements of optical properties (slides) 3.6.1 Transmission and reflection measurements (spectrophotometers) 3.6.2 Color rendering measurements 3.7 Artificial light sources (ITE slides) 3.8 The lighting design (13.1, 13.2) 4. MATERIALS AND CONSERVATION (summary chapter 9 - Felli 1 + slides) 4.1 Comfort and thermo-hygrometric balance of the human body 4.2 PMV and PPD 4.3 Comfort environmental conditions (global and local) 4.4 Psychrometric diagram (description only) and air treatments 4.5 Air conditioner 4.6 Conservation of works of art (chap. 14 - Felli 2) 4.6.1 Environmental conditions (thermohygrometric, lighting, air quality) (14.1, 14.2, 14.3, 14.4) 4.6.2 Environmental monitoring and risk indices (14.5, 14.6) 5. MATERIALS AND THE IMPACT ON THE ENVIRONMENT (slides) 5.1 Life cycle analysis 5.2 Methodologies for LCA 5.3 Regulations 5.4 The Carbon Footprint 5.5 Environmental product certifications ¿ Invia commenti Riquadri laterali Cronologia Salvate Contribuisci |
FUNDAMENTALS OF FLUID MECHANICS AND MEASUREMENTS
| Code | A002528 |
|---|---|
| Location | PERUGIA |
| CFU | 5 |
| Lecturer | Bruno Brunone |
| Lecturers |
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| Hours |
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| Learning activities | Affine/integrativa |
| Area | Attività formative affini o integrative |
| Sector | ICAR/01 |
| Type of study-unit | Opzionale (Optional) |
| Language of instruction | Italian |
| Contents | The behavior of the fluids and their main properties. Statics of liquids. Kinematics of liquids and flow equations. Weakly dissipative flow processes. Laminar and turbulent uniform flow. Artificial porous media. |
| Reference texts | B. Brunone, S. Meniconi e C. Capponi (2021). Fondamenti di Meccanica dei Fluidi Incomprimibili per allievi del corso di Laurea in Design. Morlacchi Editore U.P. (ISBN/EAN 9788893922692). Distributed free of charge to students. |
| Educational objectives | The main aim of this course is to lay the foundations of the fluid behavior from both the qualitative and quantitative point of view. |
| Prerequisites | There is no prerequisite. |
| Teaching methods | The course is divided into lessons and exercises. If allowed, some practical applications will be take place at the Water Engineering Laboratory (WEL) of the Department of Civil and Environmental Engineering. |
| Other information | At the end of the course some summary lessons will take place. |
| Learning verification modality | The exam is oral. |
| Extended program | The behavior of the fluids and their main properties (density, specific weight, no-slip condition, Newton law and viscosity measurement, stresses in a liquid, non-dimensional numbers (Reynolds number and Froude number), equation of state and compressibility, vapor pressure and solubility of air in water). Statics of liquids (Stevin law, pressure distribution in a still liquid, pressure measurement). Kinematics of liquids and flow equations (flow field characterization, flow discharge, gradually varied flow and the related pressure distribution, continuity equation, Bernoulli theorem, extension of the Bernoulli theorem to real liquids, discharge measurement). Weakly dissipative flow processes (Pitot tube, outflow processes and Torricelly equation, Venturi process). Laminar and turbulent uniform flow (Reynolds results, Moodu diagram, friction formulas). Artificial porous media (Darcy law, the moka principle of functioning). |