Carla Sujanto
University of Melbourne Bachelor of Environments, Architecture Major (graduating 2018)
I think that architecture shapes our daily life, our culture and society. I believe that it will also play a major role in shaping our future, and I strive to play a part in designing the future built environment. Carla Renata Sujanto | 09.09.97 Australian/Indonesian
Contents EMERGENCE 4 (re)TREE 11 CHAOS & CLARITY 15 TRANSFERENCE OF FEAR 19 VARSAM GATTU 23 OTHER WORK 26
2018, Semester 2, 3rd Year Studio: Fire (capstone) Individual Project
EMERGENCE
render: view from Royal Pde.
Page 4
EMERGENCE
EMERGENCE of the school
circulation through building
Site: The University High School, Story street, Parkville Client: The University High School, The University of Melbourne Tutor: Robyn Pollock Brief: Sports Department and General Learning Area complex for VCE students
from school
to oval to oval
The University High School is well known for its high standard of education. To facilitate for their projected increase in numbers, they require a new sports department and VCE learning complex. My design focuses on the concept of ‘emergence’; emergence of the school into the public realm and emergence of the student into the world.
from school to oval: thoroughfare cuts through building
drone view of surrounding site from traffic lights to stadium to gym
Royal Para de
Stor y St reet
from traffic lights to public sports facilities
Like a sprout emerging from the ground, University High School emerges and grows. to school
to bike storage to VCE building
N site: University High School
from tram stop
from tram stop to VCE building and existing school
Page 5
diagram by Kenn Fisher: learning clusters
EMERGENCE of the student
The program is based on Dr. Kenn Fisher’s research on pedagogy. He details different types of learning clusters and learning settings which encourage students to communicate with others, think critically and be independent. Instructional: taught by teacher Practice-based: group work and project work Informal/Self-directed: Independent study and socialising
Instructional Learning Practice-based Learning Informal/Self-directed hierarchy of space from supervised learning to unsupervised learning
Page 6
Current Uni High students had also stated that the school does not provide space for senior students to feel independent. The senior common area is located on the second floor away from the other teaching spaces. This provides independent study spaces and a space to feel separate from the rest of the school.
Emerged: view from senior common area to stadium, trees and streets
Above ground: view from first floor overhang down into auditorium
Underground: view from submerged auditorium looking up
close-up section of general learning area showing pedagogical activities. Sketches by Kenn Fisher: learning settings
Page 7
Balcony
Kitchen
Breakout space
Balcony
Second Floor
Staff meeting room Male changerooms Nurse’s office Balcony
Hanging classroom Female changerooms
Collab. room
Stadium
Staff office Breakout space Classroom
Lift Breakout space
Double Classroom Balcony
EMERGENCE in form
Storage
Staff office
Balcony
First Floor
The architecture boasts a unique form which ‘emerges’ from the underground auditorium at the south end and grows up and outwards with each shell.
Auditorium 1
Staff office Collab. room Project room
Auditorium 2 Collab. room
Auditorium 4
Collab. room
Admin
Auditorium 3
Project room
Staff office Gym/Aerobics
Staff office
Toilets
Ground Floor
south to north section in context
Page 8
Roofs are angled to allow more sunlight in winter and block sunlight in summer. It also allows more light into the southern shell so that it is not blocked by the larger shells. Summer
Summer sunlight
Autumn
Equinox sunlight
Winter
Spring
Winter sunlight
Page 9
render: view from Story St. entrance
1:500 physical model, side
1:500 physical model, stadium
1:500 physical model, interior of general learning area
Page 10
render: close-up of space in between panels
2018, Semester 1, 3rd Year Studio: Air Group Project (7 members)
(re)TREE
Responsibilities in group: (approx. 23% overall) - ideation 17% - research 17% - computational design development/testing 30% - final computational design 95% - diagrams, illustrations, renders 35% - final fabrication and construction 4%
Page 11
(re)TREE
design development
digital process
Site: Merri Creek, CERES park Client: Friends of Merri Creek, small local spiders Groupmates (7 members): Arianna Garay, Sabrina Widjaja, Arwa Edris, Jacinta Chan, Adrian Chiodo, Sherry Li. Tutor: Dan Schulz Brief: (Re)Fuse - Non-human Citadel Our studio responded to the environmental crisis of the near future in which plants and animals struggle with the decline of habitat trees; our brief asks how digital design and fabrication can create a man-made habitat tree. My team explored the idea of abstracting the habitable aspects of a dead tree (rotted log) and repeating it across a larger component to make an artificial eco-system for local small spiders.
1. Tree ring decay determined by amount of rainfall. More rainfall=stronger wood=less rotting. This created the patterns of the top of panels. Panel and gap widths were determined by yearly rainfall over 35 years. Months January Febuary March April May June July August September October November December
Rainfall - 1993 92.2 62.9 38.5 27.4 38.7 54.2 45 60.1 127.6 51 77 171.8
Months January Febuary March April May June July August September October November December
Rainfall - 1994 38.8 109.6 37 63.8 32.8 42.6 15.2 29.2 38.4 20 40.6 12.4
Months January Febuary March April May June July August September October November December
Rainfall - 1995 135.4 18.8 71.6 111.4 87.4 87.8 72.8 56.8 40 85 70.2 38.8
Months January Febuary March April May June July August September October November December
Rainfall - 1996 114 93.8 45.8 148.6 34.4 59.2 90.1 56.2 67.4 50 40.8 23.8
Months January Febuary March April May June July August September October November December
Rainfall - 1997 23.2 6 16.4 14.4 68.2 31.6 20.2 31 54 29.8 61.2 7.2
Months January Febuary March April May June July August September October November December
Rainfall - 1998 48.6 85.6 11.6 63.4 59.6 64.4 51.4 23.8 37.2 94.2 61.6 63.6
Months January Febuary March April May June July August September October November December
Rainfall - 1999 26.8 31.4 62 35.4 58.2 47 14.2 84.8 28 62.4 35.4 131.2
Months January Febuary March April May June July August September October November December
Rainfall - 2000
Months January Febuary March April May June July August September October November December
Rainfall - 2001 12.4 16 79.6 123.2 19.6 61.6 14.6 53.2 44.4 80.4 65 45.2
Months January Febuary March April May June July August September October November December
Rainfall - 2002 38.6 77.6 31.3 43.2 35.8 29 30.7 47.9 34.1 29.2 28 11
2. Data mapped into lines and adjusted to become smoother. Yearly data points overlayed onto existing points to create smaller curves at spider’s scale.
31 35.4 27 42.2 87.8 40.6 52.2 46.2 80.6 109.6 40.9 38.8
1. single panel prototypes and sandblasting tests
concept iteration 1
2. fabrication testing and 1:100 component prototype iteration 2 iteration 3
unrolling of rotted tree trunk
initial concepts
3. Panels made from lines. Yearly rainfall data remapped into more standard timber plank widths.
1.1 3.1
1.2
HOLLOWS, IMAGE SAMPLING, CNC MILLING Image sampling then CNC milling onto several sheets of MDF to add depth.
3.2
2.1 4.1
2.2
4.2
3. panel construction
BRANCHING, SHORTEST WALK Simulate tree branches and creating hollows using shortest walk algorithm.
shortest walk script
branching script
Page 12
By simulating the natural development and decay process of a log into our computational design, and through a sandblasting surface treatment of our physical design, we simulated an environment suitable for spider habitation. final 1:1 model
panel 10, representing 2001. (photos by member Jacinta Chan)
sandblasting simulates natural wood texture
Page 13
axonometric
final render: single (re)tree component in context plan view
front view one panel consists of 6 planks local small spiders inhabiting component
side view The variation in panel and gap width creates an environment for different sized species of small spiders with various types of webs. Page 14
render: view up to cube from first floor
2017, Semester 1, 2nd Year Studio: Earth Individual Project
CHAOS & CLARITY
Page 15
chaos & clarity Site: Herring Island Tutor: Sarah Kahn Brief: A Place for Keeping Secrets - something like a pavilion, on Herring Island This project explores the spatial relationship between three zones: below ground, ground and above ground. The final composition should express the sequence, journey and connection between these zones. The pavilion must also facilitate the keeping or discovery of a secret. My final design explores the idea of chaos and clarity which reflects how Herring Island is a quiet retreat into nature in the middle of a busy city. This is expressed through the disjointed and chaotic beams and pillars, which in turn create a chaotic journey through the space. The moment of clarity comes when they find their way into the cube which gives a retreat from the chaos. They find the pavilion’s secret, a time capsule, inside the cube; the capsule is metaphorically frozen in time like the cube is frozen in space.
LEGEND
N
Existing path Path to pavilion Vegetation
site: Herring Island
conceptual sketch model. Chaotic journey circling a central still object.
Page 16
3
second floor
isometric view inside cube. chaos is created by the frames, clarity is created by the cube
pavilion on site contours
first floor
1
LEGEND
5
4 6
2
7
storage, toilets
1 2 3 4 5 6 7
Entrance Sheltered space Secret (time capsule) Female toilets Male toilets Cleaner’s cubicle Storage
ground floor
perspective section through pavilion and cube
Page 17
1. entrance
2. below ground
3. on ground
4. keeping of secret
Exploded axonometric: circulation into pavilion, through the three zones, and out
5. discovery of secret
6. above ground
Visitors would enter into the BELOW GROUND space first, then ascend into the ON GROUND zone, then to ABOVE GROUND zone inside the cube and platforms.
Page 18
final 1:1 model: close-up of texture
2017, Semester 1, 2nd Year Digital Design and Fabrication Group Project (3 members)
TRANSFERENCE OF FEAR
Responsibilities in group: (approx. 50% overall) - ideation 40% - research 40% - design development/testing 60% - final design 95% -fabrication and construction 40% - diagrams, illustrations, renders 80% Page 19
Transference of Fear
proposal
Site: Human Groupmates: Joanna Tidy, Ope Olubodun (joined later), (past member: Brooke Zhang) Tutor: Joshua Russo Brief: Personal space (section/profile systems) This project explored the concept of personal space and how personal space is affected by different situations. The task was to express this concept into a tangible obejct on a person. My group expressed the idea of psychological personal space and how this is affected by fear. Our chosen scenario involved a pedestrian paranoia as they walk the streets at night and encounter another stranger. Our design illustrates this person’s desire to both hide from the stranger and scare them away; hence, the transference of their own fear onto the passerby.
distortion of the wearer’s identity
concept
form
texture
user’s identity is obscured to onlookers.
eerie texture that blends in with night
final digital model isometric
front view
right view
Page 20
final 1:1 model: close-up of layers
(1:1 model photos by Joanna Tidy)
final 1:1 model: close-up of connection
Page 21
model on person: right view
model on person: 3/4 view
model on person: left view
Page 22
render: Varsam Gattu placed along the Gattu (field boundary)
2018, Summer Term, 3rd Year Humanitarian Design Internship Group project (3 members)
VARSAM GATTU
Responsibilities in group: (approx. 30% overall) - ideation 30% - research 27% - design development/testing 30% - final design 25% - diagrams, illustrations, renders 45% Page 23
Varsam Gattu
material
Varsam: (Telugu) rainwater Gattu: (Telugu) the physical boundaries of a field Site: Gangineni Village, Andhra Pradesh, India Client: Gangineni farmers Groupmates: Genevieve Kour, Rudi Saniga Tutor: Piyush Tiwari, Jyoti Rao Brief: How can design improve the welfare and happiness of a society?
main materials: rope, bamboo, tarpaulin and drum
We prioritised the use of vernacular material and construction methods. Farmers would be able to construct this themselves, giving them a sense of independence.
My group focused on Gangineni village, an agricultural society that is heavily dependent on groundwater for irrigation as rainwater is often insufficient. However, some farmers must pay for water access. Additionally, the rate of groundwater extraction had lead to depletion.
first design
Our project is a rainwater collection and storage unit. It consists of a wide funnel which would collect rainwater in monsoon season into a drum. This is flipped to become shade over the drum in dry seasons. The tap encourages farmers to use drip irrigation systems for water efficiency. We aimed to alleviate the burden of water sourcing/ storage for the farmers, while also allowing the water table to recharge. Farmers would have their own personal water supply, increasing their water security. isometric
site: Gangineni Village
diagram of parts
1:5 prototype
development sketches 2 people required for setup
2 people required for pack up
placement on the GATTU
Our initial idea focused on the efficiency in setting up/packing up the unit. The funnel unit can be setup, removed and stored easily and is held down by a boulder. However, this design would not withstand monsoon winds.
Page 24
top view
new design collecting rainwater
side view
drip irrigation system connected to tap
final design To improve stability in monsoon winds, PVC pipes are embedded into the GATTU for the bamboo poles to be slotted into. Although this design may be harder to setup and store, it is more lightweight and stable than our first design.
final design isometric
Page 25
Occupy | Alien Construction Design Travel Photography
OTHER WORK Page 26
occupy | alien 2016, Semester 2, 1st Year Designing Environments Individual Project Tutor: Hella Wigge Alien conveys the idea of University of Melbourne’s Concrete Lawn as a foreign space in which the conventions of walking through and occupying the space are changed; pedestrians must consciously maneuver through the frames and landforms. early models exploring ‘disjunction’ and ‘landform’
frames and landforms creating maze-like space
Page 27
5
NOTES Finishes
1. Modular carpet tiles, apply with direct stick method 2. Sheet vinyl flooring, Armstrong ‘Contour’, 2.0mm thick 3. Aluminium composite cladding, Alucobond, 4mm thick, supported on joints
6
Glazing
12
4. Powdercoat aluminium frame
7 3
Roof Cover 5. Bluescope Lysaght, ‘Spandek’, 0.48 BMT, colorbond finish 6. CSR Bradford ‘Anticon 130’ Roofing Blanket with Medium Duty Thermofoil 730, ‘Ashgrid’ suspended ceiling system, 110mm metal spacers installed over blanket 7. Rondo key-lock concealed suspended ceiling system 8. 150x150 custom folded eaves gutter
9 8 10
Roof Structure
11
9. (P2) C purlin, 203x76x2.4, 1200 CRS 10. (WH2) 200 PFC 11. (RA1) 150x90x10 UA 12. (RB2) 20 diameter rod bracing, universal wind bracking bracket
4
First Floor Structure 13. First floor slab, 220mm, 1mm CONDEK 14. (1BB4) 2400x450 concrete beam
RL 36.00
Precast Walls
1
13
15. (PC4) Precast concrete panel, 200mm, RL818 mesh, M16 L70 Cast in Ferrules and 15mm max. rebate for first floor slab and beams 16. (PC5) Precast concrete panel, 175mm
RL 34.47
14 15
Steel Structure
16
17. (SC4) 89x89x6 SHS, fixed on cast-in plate 18. (SS2) 230x75 PFC, stair beam, hot dip galvanised 19. (SB2) 230x75 PFC, stair stringer, hot dip galvanised 20. (SB3) 250x150x6 RHS with 10mm cap plate, connected to cast-in plates in precast panel with 10mm cleat plates and 2 M20-8.8/s bolts 21. (SB4) 230x75 PFC, stair beam, hot dip galvanised 22. (ST1) 65x65x5 EA 23. 6mm thick steel floor plates at landings 33. Handrail, galvanised mild steel
RL 32.97
26
Block Veneer Wall
24
24. Block Veneer Wall, Boral DesignerBlock, 390x90x90, honed face, hollow 25. Steel stud framing, 450 max. CRS 26. Sarking, CSR Bradford ‘Breatherfoil Antiglare’ vapour permeable sarking 27. Thermal insulation, CSR Bradford ‘Gold’ wall batts, R2.5, 90mm thick 28. Fire rated plasterboard
23
20
2
17
RL 31.80
21 27
28
33
29
18
100mm polystyrene compacted granular fill crushed rock clay and silt
19 22
crushed rock and cement
25 stiff clay
32
Ground Floor Structure 29. Ground floor slab, 150mm, SL92 top and bottom mesh, 30 cover
extremely weathered siltstone
30
Footings 30. (F2) Pad footings, 1200x1200x750min., SL81 bottom mesh reinforcement 31. (SF2) Strip footings, 400x600min., 4-L12-TM top and bottom mesh reinforcement 32. (EB1) Edge beam, 300x600min., 3-L12-TM top and bottom mesh reinforcement
31
construction design 2018, Semester 1, 3rd Year Individual Project This project focused on a section of Elizabeth Blackburn School of Sciences (University High BIO21 SCIENCE SUB School) and demonstrating our SCHOOL understanding of the section’s Scale | 1:20 @ A0 construction systems from Carla Sujanto Tutorial 17 foundations to finishes. 14/03/2018 Tutor: Michael Collins
Elizabeth Blackburn School of Sciences Axonometric Drawing Section H South-East
axonometric drawing: section with cut-aways showing different elements
photos of physical model and different construction elements
Page 28
travel photography 2015-2018
Page 29
THANK YOU carlasujanto@gmail.com (+61) 432 981 709 instagram.com/csu_aesth issuu.com/csujanto