Francesco Barone PORTFOLIO 2015
FRANCESCO BARONE
education
work experience Poptahof Noord 330 2624 RR, Delft/Netherlands frncscbrn@gmail.com +310617291516 behance.net/happycolor Male/6may1991/Italian
softwares
2010 Diploma liceo classico Torquato Tasso Via Sicilia 168, 00187 Rome, Italy 2014 Laurea in Scienze dell’Architettura [110 lode/110] Architecture bachelor degree Università degli studi di Roma Tre 2014-ongoing Delft niversity of Technology
04/2012 -09/2012 waiter and cashier in a catering company 03/2013-05/2014 Assistent in models and prototype laboratory University of Roma Tre, Architecture faculty 01/2013-05/2014 Math and Geometry Private lessons
AutoCAD-Photoshop-Illustrator-Indesign-Rhinoceros-Sketch up-Autodesk Vasari-Autodesk Ecotect-Microsoft Office-Grasshopper
INFO
INDEX 1. UNIVERSITY RESIDENCE in Testaccio, Rome 2. TEMPORARY RESIDENCES in Tuscolana, Rome 3. PROTOTYPE HOUSE for Solar Decathlon 4. REQUALIFICATION of PALAZZETTO DEI PICENI in Rome 5. RENOVATION OF NIRWANA FLAT. TU Delft, Building Technology 6. EGOCITY, The Why Factory-MVRDV, TU Delft 7. DRAWINGS
PROJECTS
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TEMPORARY RESIDENCES
and public services In quartiere Tuscolano , Rome academic project with: Caterina Corsi from 03/2013 to 07/2013 project carried out in 23/07/13 (my last project) supervisor: prof. Luca Montuori luca.montuori@uniroma3.it
author: Francesco Barone
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The theme of the laboratory was the creation of temporary residences and public services in a project area next to the railway station and the chaotic via Tuscolana, in the south of Rome. We chose to create two residential buildings connected by habitable platforms wich house public services. In the residential blocks we tried to diversify the residences alternating four typologies of apartment conceived to accomodate different types of households. The project is deeply connected to the sorrounding urban context: the internal space is not meant just for the residents but also for the entire district, lack of public spaces. A ramp connects the compound to Tuscolana station, directing the stream of people inside the public area. REQUESTS: RESIDENTIAL 1860/2200 sq.m. PUBLIC SPACES 1000 sq.m.
CREATION STEPS 1. project’s area 2. residential buildings
3. habitable bridges 4. public services
1.
2.
3.
4.
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TEMPORARY RESIDENCES +public library +coffee bar +computer lab +time bank +conference room
+6
.1
0
20 sq.m.
35 sq.m. +4
.3
+7
0 +7
.7
0
+4
.7
.3
+7
0
0
.7
0.
00
0
+7
.7
0
45 sq.m.
2TH FLOOR PL AN
55 sq.m.
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1.
a
a’
-1,00
-1,00
0m
4
10
14,5
22
26
33
2.
disposition of the residence typologies
1. section a-a’ 2. south-east elevation
+6,10
+6,10
0m
17
28
33
71
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Drawings: Francesco Barone, Caterina Corsi
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1. project’s view from the railway station
2. the front on via Tuscolana
1.
2.
Renders: Francesco Barone
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the public square inside the project area author: Francesco Barone
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STUDENT RESIDENCES
and respective services In Testaccio,Rome academic project with: Lorenzo Balestra from 10/2011 to 02/2012 project carried out in 29/02/12 supervisor: prof. Lorenzo Dall’Olio lorenzodallolio@uniroma3.it
author: Francesco Barone
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The project area is in Testaccio,in the old town center of Rome, near Roma Tre university. We were asked to create a building for student accomodations (about seventy students) provided with common spaces and relax and study areas. The building is placed in a fragmented urban area, occupied mostly by industrial sheds. We chose not to entirely fill the project area, wich is rather large, but to use it in part as an alternative passage to the road. With it’s trapezoidal shape, the building tapers to one street front, ending with an overhang roof that configures a coverede square. Inside the building, through double eights and transparent courtyards, we tried to create a unified space, in order to promote socialization and communication among students.
CREATION STEPS 1.
project area
2.
cutting of the rectangle
3.
subtractions , opening of the courts
4.
identification of the entrances
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STUDENT ‘S RESIDENCES 1. FULL-EIGHT ATRIUM 2. COFFEE BAR 3. AUDITORIUM 4. COMMON SPACE 5. GYM 6. LAUNDRIES 7. SCREENING ROOM 8. COMPUTER LAB /STUDY ROOM 9. COURTYARD
a’ 4. 3.
5.
9.
6.
7. 6.
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VIA
2.
OL NIC
1.
IA
L AG AB
AZ
VIA
a
C
AIO
TIO CES
T
N TA TES O R HP LIS RY G EN METE CE
section a-a’
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1. DETAILED 1. DETAILED SECTIONSECTION 2. WEST2.ELEVATION WEST ELEVATION
Drawings: Francesco Barone, Lorenzo Balestra
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The pillars sorrounding the roof of the building create a visual and physical relation with the park. The irregular disposition is chosen to not give a direction to the transition and to recreate an artificial forest author: Francesco Barone
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At the ground floor the building is incased by glass surfaces and revolving panels used as brise soleil
author: Francesco Barone
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PROTOTYPE HOUSE
for solar decathlon 2012 academic project individual work from 03/2012 to 07/2012 project carried out in 08/10/12 supervisor: prof. Gabriele Bellingeri gabriele.bellingeri@uniroma3.it
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1.
2.
house area
4.
3.
out
in
out living
out living
80 mq
plan
house the C house is a self-sufficent prototype of residence designed for a familiar core of two people, according to the rules of solar decathlon 2012. It is composed by prefabricated components that can be easily transported and assembled in situ. The peculiar curve wall contains a belt of services to the living zone. The limit of 60 square meters for the internal brought the choice of creating an open space void of partitions which is put in continuity with the external area trough a wide glass surface . All the energy is obtained from the photovoltaic system on the top of the building, balanced on the necessities of the house. The panels also provide to the shading of the building since they are set on a sliding roof.
1.
2.
3.
4.
section
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b
services
sliding wall living
a
a’ services sleeping
living
b’
section a-a’
section b-b’
1. 2. 3. 4. 5. 6. 7.
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1.
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2. 3.
2. 3. 5. 4. 6. 7.
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8. 15. 16.
9. 10. 11. 12. 5. 8. 13. 14.
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7. 19.
9. 10. 11. 12.
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5. 9. 10. 11.
1. photovoltaic panels 2. carriage of the sliding panels 3. rail of the carriage 4. wood beam (not structural) 5. waterproof sheat 6. Exterior Insulation and Finishing System 7. prefabricated wood panels
(including insulation) 8. wood beam 9. wood planking 10. gypsum fiber panels (2x) 11. underfloor heating 12. prefabricated wood panels (including resisting to compression insulation)
12.
13. platform’s wood beam 14. platform’s support 15. wood bracing panel 16. double glazing window 17. sliding French window 18. gutter 19. wood shell
TECHNICAL DETAILS
EXPLODED ISOMETRIC VIEW 1. photovoltaic panels 1.
2. wood shell 3. osb wood panels
CREATO CON LA VERSIONE DIDATTICA DI UN PRODOTTO AUTODESK
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FLOOR’S STRATIPHICATION
1.
2. 3. 4. 5. 6. 7.
4. laminated wood beams
2.
8. 9.
O CON LA VERSIONE DIDATTICA DI UN PRODOTTO AUTODESK
1. wood planks
2. gypsum’s fiber panels (2x1 cm)
a’
3.
3. underfloor heating (pvc tubes) 4. layer of isolating “xps” 5. “osb” wood panels (2x2 cm) 6. vapour barrier “sisalex” 7. insulating layer “xps” 8. “osb” wood panel (3 cm) 9. wind seal layer “ampatop”
4.
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ARTIFICIAL and NATURAL LIGHTING STUDIES Great attention is given to the artificial and natural lighting. The sliding roof protects the interior from direct irradiation in summer and lets the sunbeam warm up the house in the cold season. Every house’s portion is lighted up by a different kind of illumination, according to the needs that the activities require.
summer configuration
winter configuration
summer ventilation
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REQUALIFICATION of PALAZZETTO DEI PICENI in Lungotevere di Tor di Nona, Rome academic project with: Caterina Corsi Lorenzo Balestra Andrea Bartocci from 10/2012 to 02/2013 carried out in 27/02/13 supervisor: prof. Michele Zampilli michele.zampilli@uniroma3.it
Isometric view: group work
1,53 0,6 0,54 0,4 1,64
1,2
14,87 14,47
1,84
2,37
11,63
1,84
2,28
7,42
1,08
3,30
1,72
0,5 1,08
The Palazzetto dei Piceni is an ancient building erected around the XV century in the old town center of Rome, it is gone through various transofrmations during the years. Many restauration projects have been realized but currently it remains a crumbling building. The first part of the course was dedicated to the architectural surveying and the acquaintance of the construction’s history.
FIRST PHASE: knowing of the existing
23 17,53 17,00 16,40
0,00
1,08
Our hypothesis on the historical transformation of the building
sketches by: Francesco Barone-Lorenzo Balestra
24 DEMOLITION
SECOND PHASE: restoration project
RESTORATION
Concluded the knowledge phase, we made the project of the apartments inside the building. According to the new internal suddivision we chose to demolish or restore the existing walls and stairs. There are various dwelling typology, variable from square meters and number of plans. At the ground floor there are shops and ateliers, open on the street front. We mainteined the “profferlo” tipology of stairs as private entrances; two other stairs are in common and serve the entire building.
GROUND FLOOR
1st FLOOR
GROUND FLOOR
1st FLOOR
2nd FLOOR
2nd FLOOR
3rd FLOOR 3rd FLOOR
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ROOF CONSOLIDATION Stratification of the reinforced roof
Isometric exploded view of the roof truss
BAGIOLO
TRAVETTI
ARCARECCI
COPPI EMBRICI PIANELLE
ARMATURA LONG.
ARMATURA TRASV.
Details: group work
1.
STAGES OF IMPLEMENTATION OF THE CURB IN REINFORCED MASONRY the irons are comprised between two meshed brick bands. Is then thrown a cement mortar. the curb in reinforced masonry ensures cohesion between the roof and the wall, making the whole more stable.
2.
3.
Sketch: Francesco Barone
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7.
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The Hague, Netherlands Individual project for Building Technology from 9/2014 to10/2014 supervisor: prof. Pier Jennen, Ssse | OvO associates architects
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the brise-soleil system on the brise-soleil system on the SouthWest and the South-Eas West and the South-East facades prevents the warming of prevents the warming of the apartment ment
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The 3 meters projection The 3 meters projection balcony protects the apartments protects the apartments from the direct sunlight during th direct sunlight during the critical hours hours
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5.
RENOVATION OF NIRWANA FLAT
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In the Winter the balcon In the Winter the balcony can be closed and acts as an in closed and acts as an insulation layer. The balcony beco layer. The balcony become an interior space interior space
The insulation layer insid The insulation layer inside the wall prevents warming dispe prevents warming dispension.
1.
2.
3.
The apartments can be joined or divided according to the necessities o The structural walls coincide with the services of the apartments.
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The task of the studio was to completely re-design the Nirwana flat, by Duiker and Wiebenga working exclusively with wood, or, as we claimed, with as much wood as we can. The efficiency, of the building, in term of sustainability, was one of the main topic, our design had to be ‘2030 proof’. My design was focused on the re-invention and simplification of the structure and the balconies. In the existing building the plan was indeed completely fixed, with no possibility of evolution or adaptation by the families living there; keeping the minimum amount of load bearing walls, each floor work as a plan libre letting the clients modify the dimension of the apartments according to their necessities. The balconies follow the same concept of “flexibility”, they are conceived as extensions of the houses, with the possibility of being interior space in the winter and exterior space in summer.
The apartments can be joined or divided according to the necessities of the residents. The structural walls coincide with the services of the apartments. The apartments can be joined or divided according to the necessities o The structural walls coincide with the services of the apartments.
Delft seminars on Building Technology Redesign Nirwana flat student: Francesco Barone student number: 4408675
Design
The balcony
The apartments can be joined or divided according to the necessities of the residents. The structural walls coincide with the services of the apartments.
1. Pillars and beams structure 2. Prefabricated wood panels 3. External solid wood wall 4. Sliding windows’ rail 5. Sliding windows’ frame 6. Double glazing system 7. Railing 8. Cladding wood panels 9. Brise soleils’ rail 10. Brise soleils
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Technical details of the facade and the balconies
Delft seminars on Building Technology Redesign Nirwana flat student: Francesco Barone
A’ 1:20
original scale 1:20
Section A-A’ 1:20 South-East elevation 1:20
Section B-B’ 1:20
South-East elevation 1
Section B-B’ 1:20
29 13
14
15 16 17
18
1 2
Section A-A’ 1:20
3
mm
4
19 5 20
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B Section A-A’ 1:20
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mm
9 10
B Section A-A’ 1:20
25 mm
11
ndow
panels
1.
2. 3. 4. 5.
A’
6.
1. Greenhouse floor: 12 vegetation layer lightweight soil A’ filter membrane drainage layer root barrier membrane A Detail 1:5 2. Solid wood floor 30 mm 3. Floor retaining structure 50x110 mm 4. Water barrier Greenhouse floor: 5. Exterior insulation layer 50 mm vegetation layer (resisting to compression) lightweight soil 6. Vapor barrier A’ filter membrane 7. Prefabricated wood Panels: osb panels 2X 35 mm drainage layer interior insulation layer 200 mm root barrier membrane rafters 100x200 mm Solid wood floor 30 mm 8. Interior finishing panel Floor retaining structure 50x110 mm 9. Structural beam 300x400 mm Water barrier 10. Steel corner cleat and screws Exterior insulation layer B’ 50 mm 11. Pillar-beam screws connection (resisting to compression) 12. Triple glazing window’s frame 85 mm Vapor barrier
1. Greenhouse floor: 8 vegetation layer 9 lightweight soil filter membrane 22 drainage layer root barrier membrane 2. Solid wood floor 30 mm 3. Floor retaining structure 50x110 mm 4. Water barrier 5. Exterior insulation layer 50 mm 1. Greenhouse floor: South-East elevation 1:20 (resisting to compression) vegetation layer 6. Vapor barrier lightweight soil A’ 7. Prefabricated wood Panels: filter membrane 16 osb panels 2X 35 mm drainage layer interior insulation layer 200 mm root barrier membrane 23 rafters 100x200 mm 2. Solid wood floor 30 mm 24 8. Interior finishing panel 3. Floor retaining structure 50x110 mm 9. Structural beam 300x400 mm 4. Water barrier South-East 1:20 Steel corner cleat and screws 5. Exterior insulation layer 50 mm elevation10. 11. Pillar-beam screws connection (resisting to compression) 1 12. Triple glazing window’s frame 85 mm 6. Vapor barrier 13. Solid wood floor panels 30 mm 7. Prefabricated wood Panels: 2 14. Acoustic insulation layer 30 mm osb panels 2X 35 mm (resisting to compression) interior insulation layer 200 mm B3 Detail 1:5 15. Double glazing sliding windows 25 mm rafters 100x200 mm 13 14 16. sliding window’s wood frame 8. Interior finishing panel 4 17. Railing 9. Structural beam 300x400 mm 5 18. Folding brise soleil 10. Steel corner cleat and screws 6 19. Wheel and rail of the sliding window 11. Pillar-beam screws connection 1 20. Solid wood panels 30x370 mm 12. Triple glazing window’s frame 85 mm with puzzle joint 13. Solid wood floor panels 30 mm 2 21. Vertical rafters 30x660 mm 14. Acoustic insulation layer 30 mm 7 22. Beam-beam screws connection (resisting to compression) 3 23. Electronic folding panels motor 15. Double glazing sliding windows 25 mm 24. wheel-rail system of the folding panels 16. sliding window’s wood frame 4 17. Railing 5 8 18. Folding brise soleil 6 19. Floor Wheel1:20 and rail of the sliding window 9 20. Solid wood panels 30x370 mm 10
South-
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Study of the balcony The balcony is meant as a flexible area, liveable as an exterior space in summer and covering the function of buffering zone in the cold season: if closed it basically represents an highly performant insulation layer between the inside and the outside temperatures.
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1. Pillars and beams structure 2. Prefabricated wood panels
The balcony/exploded view 3. External solid wood wall 4. Sliding windows’ rail
Climate concept
5. Sliding windows’ frame
2.
1.
6. Double glazing system
86 m
7. Railing
2
+
35 m
2
=
121 m 2
8. Cladding wood panels
IN/OUT
IN
9. Brise soleils’ rail
OUT
10. Brise soleils
3.
86 m
2
+
35 m
2
=
IN/OUT
IN
The apartments are refreshed by the big opening on the facade and the balconies. A window is open to the central stair which is used to remove hot air and to create ventilation in the building. On the top floor two greenhouses and two pergolas can be used alternatively according to the season and the temperature. The greenhouses are meant not just as a space to grow plants and vegetables but mostly like common living spaces. On the roof of the greenhouses are placed photovoltaic panels, which perform better without direct sunlight than the classic solar panels.
121 m 2
OUT
.
the residents. .
5.
4.
5.
6.
7.
8.
Ventilation
9. 6. 4. 7.
5. 8.
6.
the brise-soleil system on the SouthWest and the South-East facades prevents the warming of the apartment
9.
The 3 meters projection balcony protects the apartments from the direct sunlight during the critical hours
10.
In the Winter the balcony can be closed and acts as an insulation layer. The balcony become an interior space
10.
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EGOCITY
maximum desire maximum density TU Delft, academic project. Tutors: Winy Maas, Felix Madrazo, Adrien Ravon, Arend Van Waart Students: Charles Ducerisier, Chun Hoi Hui, Francesco Barone, FĂŠlix Borel, Iason Stathatos, Javier LĂłpez-Menchero Ortiz de Salazar, Lucile Dugal, Marek Nosek, Matteo Pavanello, Niels Baljet, Olina Terzi, Prokop Matej, Tarryn Leeferink, Wen Jun Tan, Woo Soojung, Zichen Liu, Loes thijssen From 10/2014 to 2/2015
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The loss of human scale and diversification in high density conditions is a recurring topic in contemporary architecture and whether individuality can coexist with it is still an un-resolved question. Egocity proposes a new way of dealing with the increasing urban density in a time when the standardization of the lifestyle seems to be the only possible solution. Rather than being based on imposed aesthetical or functional paradigms, it proposes the individual desire as the only driving force in the creation of the city. This participatory design process is achieved by the creation of a real-time multi-users video game, intended as a platform where the users can shape their apartment on their individual desires, without any mediation. Parameters (volume, surface, accessibility, privacy, sunlight...)have been set before starting the game to evaluate user’s satisfaction about the outcome
17 players
17 Dreamhouses
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The catalog of desires
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The slab the game’s output credits: Javier Lopez-Menchero, Tan Wen Jun
For a living version of the slab
youtube.com/ watch?v=lxNqW6j1_a4 credits: Prokop Matej
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The model
(1:50, 80x80 cm)
Model masters: Francesco Barone Felix Borel Charles Ducerisier Loes Thijssen
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Vertical City Asia (competition) TU Delft, Tutors: Stephan de Koning (MVRDV), Maurice Harteveld, Yiannis Tsoskounoglou, Vicky Metzen. February 2015-ongoing.
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Drawings
ink & pencil sketches from different courses
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Conceptual sketch for a competition entry of Vertical Cities Asia 2015 (ongoing)
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from my personal skecthbook of the Architectural Drawing course.
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