PORTFOLIO Ran Li Selected Works 2015-2019
RAN LI Email: bonnie11123266@gmail.com Language: English, Chinese
Designning Environment The First Plan & Model I did in the University of Melbourne
Explorations (Landscape Studio 1) The first landscape course I did in the University of Melbourne
CONTENTS
0
1
2
Sketches
SOLAR TRIANGLE
GROW LAND
Paintings Sculpture
The Land Art Generator Initiative
University of Melbourne Studio Fire
3
4
5
SMART CITY
BLOOD-COOLING GLOVE
SERENDIPITY
Architectural Association School of Architecture
University of Melbourne Studio Air
Australian Institute of Architects
CONSTRUCTION + KKAA WORKS
KKAA WORKS
Feb-April 2019 Architectural Intern Kengo Kuma & Associates, Beijing Project: Preliminary design-Haikou Tourist Centre&Zhuyeqing Tea Scienic Park Schematic design-Changdao Creative Centre of Economy-Cultural Art Centre -From conceptual stage discussions, model making, drafting, proposing design concepts, diagraming, 3d modeling, rendering, CAD Drawing, construction design, communication with company partner&material suppliers and landscape designs. Non Disclosure Agreement, Information and images provided limited. CAD Drawing details can not provided
TOP VIEW
PRELIMINARY DESIGN -Haikou Tourist -Construction design
OpA
OpB
EXTERIOR PERSPECTIVE
SECTION
OpA
OpB
EXTERIOR RENDER 1
EXTERIOR RENDER 2
INTERIOR RENDER 1
INTERIOR RENDER 2
PRELIMINARY DESIGN -Centre&Zhuyeqing Tea Scienic Park MASTERPLAN SCHEME
VIP CLUB
VIP CLUB MUSEUM
MUSEUM SCENIC AREA RETAILS
SCENIC AREA RETAILS
INVITE AMENITY
ROAMING LAKE
MAIN ACCESS
INVITE AMENITY
FLOATING RING
INVITE AMENITY A
MUSEUM A INVITE AMENITY B
MUSEUM B
MUSEUM C
INVITE AMENITY C
VIP CLUB
MAIN ACCESS
01 TABLE - SOIL 1.1
0 - 300 mm : Crushed Rocked Capped by 30mm Asphalt, Grey, Moist, Sand, Cement Stabilised, Medium Dense
1.2
300 - 800 mm : Crushed Rock and Cement Stabilised, Grey/Brown, Moist, Trace of Silt, Medium Dense 800 - 1300 mm : Clay, Grey/Brown, Moist, Silty, Stiff 1300 - 3000 mm : Extremely Weathered, Yellow/Orange/Grey, Silty and Gravels, Very Low Rock Strength
1.3 1.4
Construction Design -Axonometric Drawing Elizabeth Blackburn School of Sciences(EBSS)
02 TABLE - FOOTING
2.2.1
Pad Footing : 750 mm depth MIN. / Under the column / Used to spread loads from column to foundations Pad Footing Square Meshes Reinforcement : SL81 BOTTON (L1200 x W1200 x D750 mm MIN.) Strip Footing : 600 mm depth MIN. / Under wall structures / used to spread loads from wall structure to foundations Trench Meshes Reinforcement : 3 - L12 - TM TOP AND BOTTOM (W300 x D600 mm MIN.)
2.2.2
Trench Meshes Reinforcement : 4 - L12 - TM TOP AND BOTTOM (W450 x D600 mm MIN.)
2.3 2.3.1 2.4
Bored Piers : 2000 mm depth MIN. / 3 - L12 - TM TOP AND BOTTOM Additional 2N12 - 200 CRS x 2000 long each way at Bored Piers Blinding Concrete : 50mm MIN. 15 Mpa / WEAK MIX CONCRETE BLINDING / Used to provide even and clean surface Bar chairs : Used to level reinforcement to certain height
2.1.1 2.2
5.6
03 TABLE - SLAB 3.1 3.2 3.3 3.4
Polystyrene Layer 100 mm depth Construction Joint 2N12 Bars x 1500 Long Tie to cast in plate bars W 300 x D 600 Deep Beam
R
L
2.5
41 .3 5
2.1
7.1.1
5.1 5.1
04 TABLE - PRECAST 5.11
7.1.2
4.12 4.11 6.12
.0 36
CC1 600 x 300 mm Concrete Column 8N24 Bars 15 mm Chamfer N12 LIGS - 300 CRS CC3 400 x 300 mm Concrete Column 6N24 Bars 15 mm Chamfer N12 LIGS - 300 CRS
0
CP1 - Edge flush 4 / M16 - NF in 30 rebate nf M20 - NF
L
4.7 4.7.1 4.7.2 4.8 4.9 4.10 4.10.1 4.10.2 4.10.3 4.10.4 4.10.5 4.11 4.11.1 4.11.2 4.11.3 4.12.1 4.12.2 4.12.3 4.12.4
Ground Floor Column 125 x 125 x 4.0 mm SHS 75 x 75 x 6.0 mm SHS / 350 Mpa MIN. / To be restrained at first floor level by cast in plate Purlins at 450 mm CRS MAX. 1 Row bridgeing mid span / C20024 Raker Angle 100 x 100 x 10 mm EA Hot Dip Galvanised 200 x 75 mm PFC Door Header Beam 250 x 150 x 5.0 RHS 12 mm Thick cast in plate 4N12 Deformed bars 200 mm long x 50 mm cog F.S.B.W. to cast in plate typical Purlins at 450 mm CRS MAX. 1 Row bridgeing mid span / C20024 Concrete Column 600 x 300 mm Concrete Column 400 x 300 mm Deep Beam W300 x D600 mm 8mm Thick cleat plate 2M12 - 4.6/s bolts 4 mm CFW all round PC2A & PC2B 2/50 Dia corrugated ducts x 700 long, central in panel edge, with bleeders to nf 3/M16 - Edge entral
R
4.1 4.1.1 4.1.2 4.2 4.3 4.4 4.5 4.6
3.4
5.10
05 TABLE - ROOF AND CEILING
.3
2
3.1 1.1
07 TABLE - OUTSIDE CORRIDOR STRUCTURE Gutter W250 x D150 mm Custom folded eaves gutter W150 x D150 mm Custom folded eaves gutter Downpipe / Connected to storm water system Epoxy / Polyurethane paint finished steel sill EBSS Geotechnical Investigation Report The site is vacant and currently used as car B parking area. The surface drainage of the site is moderate. Majority of thesite is covered with asphalt. Underground services exist underlying the site at what appears to be significant depth (>3.0m). Concrete Blinding 15 MPa Footings 25 MPa Suspended Ground Floor Slab 32 MPa Suspended First Floor Slab 40 MPa Section B North East Corner Columns 40 MPa 7.1 7.1.1 7.1.2 7.2 7.3
30 R L
R
L
30
.0
2 6.6 2.1.1 1.4 1.4 2.5
.3 2
C
28
Window frames Powdercoat Aluminum Frame with Shugg Frame Insert Window Flashing Concrete Block Stud framing / support structure for aluminium composite clabbding Aluminum composite cladding 'AXIOM' Arn top rail aluminium channel for top edge support U shaped aluminium channel fixed within wall for side edge support Brick Brick Ties N12 - 200 CRS 'Z' Bars 12 mm ECHO panel fixed directly to concrete panel 100 mm Wide powder coated aluminium centre glazed window frame Flat Skicked' Aluminium composite cladding 200 mm THK Concrete pre cast panel Fire rated flushing plasterbored Timber Lining Type1 Concrete Block
2.4
R L
6.3 6.4 6.5 6.6 6.6.1 6.6.2 6.6.3 6.7 6.8 6.9 6.10 6.11 6.12
2
31
1.3 4.10.1
06 TABLE - WALL AND CLADDING SYSTEM 6.1 6.1.1 6.1.2 6.2
.0
R
L
31
1.2
L
Alumimium Composite Cladding Suspended Ceiling C20024 - 1200 MAX.CRS / Eave Purlin C15019 / No lap required 1 row of bridging per bay 2M16 - 8.8 / S Blots 10 mm Thick cap plate 6 mm cfw all around 8 mm Cleat 100 mm Thick cap plate 2M16 - 8.8 / S Bolts 6 mm CFW all around 75 x 75 x 50 mm EA
6.12
R
5.7 5.8 5.9 5.10 5.11 5.12 5.13 5.14 5.15 5.16
2
5.6
150 x 75 mm PFC 230 x 75 mm PFC 250 (V) x 150 x 5.0 RHS / 350 Mpa MIN. 50 x 3 Flat M.S. Plate / Fix to top of each purlin 12 guage tek screwa 16 mm Diameter rod / Universal wind bracing bracket support from roof purlins at midspan 20 mm Diameter rod / Universal wind bracing bracket support from roof purlins at midspan Metal Deck Roof Sheets Metal Cladding
.5
5.1 5.2 5.3 5.4 5.5
3
2
D 1
Individual work (Semester-long), Tutor: Anthony Blazquez Software: Rhino, AutoCAD
0. Pavilion-Designning Environment University of Melbourne, 2016 Semester-long, Tutor: Vedad Huric Software: Photoshop, AutoCAD
SITE PLAN
MODEL
Explorations (Landscape Studio 1)
University of Melbourne, 2018 (The first landscape course I did in the University of Melbourne) Semester-long, Tutor: Bede Brennan Software: Illustrator, Photoshop, Indesign, AutoCAD, Rhino, Lumion SITE ANALYSIS-PRIMAL PLAN The site is an open space on the Swanston Street and next to the Potter Cafe, consists of all the current lawn area and associated garden landscape. The location and presence of the concrete bunker, with its walls of around one meter in thickness. Two large elm trees that provide shade in summer and allow winter sun to penetrate the site. Inspiration from Martha Schwartz and Robert Smithson's works
0
5m
CONCEPT To Repeat / To Integrate / To Transpose
CONCEPT RHINO MODEL
CONCEPT PHYSICAL MODEL
FINAL PLAN Swanston Street
3 4
Study Area Fast and convenient seating Area
2
Social Area
The design provides three different functions for this area 1
0
Study Area -The steps and the screens create a sense of quietness. Fast and convenient seating Area -Serves people who mainly come from the Swanston street. People can sit down and wait for someone here, or they can read a book and rest. It is an area offering convenient services, with natural shadow from the tree. Social Area -There are four sheltered tables in the site, each with 6 seats.
5m
EXTERIOR PERSPECTIVES View 1-4
1
2
3
4
1. Solar Triangle (Sustainable Design)
THE SOLAR PALM TREE
LAGI 2018 Design Competition/The Land Art Generator Initiative Team Leader/Group Work (1 month) - The design has been selected for inclusion in the publication Software: Rhino, Grasshopper, Photoshop The Renewable Energy Action Plan sets out how Victoria will ensure a renewable, affordable and reliable energy supply, which uses large-scale renewable energy technology and ensures grid stability. One of our technologies used in the Solar Triangle is highly efficient solar panels, which was owned by SunPower brand [1], attached on the art installed roof top. The efficiency received reaches satisfied value at 22 %, making this panel as one of the promising technologies for the clean energy production, whereas the majority of conventional panels range from 15% to 17% in efficiency rating. The other applied technology installed is coloured building integrated photovoltaic (BIPV) panel [2], which offers an aesthetically pleasing alternative without sacrificing too much power. Another highlight in the Solar Triangle is the Solar Palm Tree. It is an integrated design that imitates the leaves and trunk of a natural palm tree. It consists of one layer of leaves (8 pieces) with Sunpower folding and flexible solar panel [3] on top and multicolour smart LED layers at the bottom; rain water collecting and filtration system at the crown; and embedded adjustable quick washing facilities attached on the trunk. The efficiency of the flexible Palm Tree solar firm is around 20-25%, which is about 30% higher than traditional solar panels. In addition, this design collects the solar energy with less occupation of ground space compared with ground-stand solar panels. It can supply the power for lighting during night and other electrical facilities around with excessive power, recycle and save the water resource, and provide shades in summer. Both the location and size of the Solar Palm Tree can be flexible based on varying demands.
RAIN
FILTER
4M
2M Self-cleaning surface
Solar firm Smart LED
EXTERIOR PERSPECTIVE
This project is basically designed to produce clean energy by using strong solar power at the site. It works as a solar radiation receiver that consists of a major multi-colour solar panel roof groups and a range of integrated Solar Palm trees. The panels itself consists of Silicon which consequences high efficient electricity production in long turn. It is a promising zero greenhouse gas emission material that will not generate any form of environmental pollution. And will become one of the backbone of the Victoria’s Net zero greenhouse gas emissions for 2050. The primary structure is built majorly by steel to ensure the stability. Other construction materials such as steel reinforced concrete, are recyclable and have no greenhouse gas emission during the function time.
However, considering the project site is located near the sea shore, strategies to mitigate foreseeable issues are: 1) An online monitoring electricity performance system should be involved to make sure all the panel models are working properly; 2) it is suggested to install bird-friendly devices especially at the top the Palm Tree structure to avoid birds’ nesting, which may lead to blockage of the rain water collection system, or rather just provide nesting space for birds; 3) Anti-rusting methods should be considered to prevent exposed steel components from corrosion in high salinity environment.
ENERGY PRODUCTION AND MANAGEMENT The total area of solar panel is 11240 m 2 . Given current capture rates of comparable technology and the weather data provided, our team has estimated that solar panels can harness approximately 80% of the potential energy. The area and rated output of solar panels we assumed are 2 m 2/panel and 300 W/panel, respectively [5]. About 1.7 MW solar panels can be installed in the design area. Annual power generation was estimated on the basis of annual global solar exposure (MWh/ year/m2) [6] and the efficiency. 1.72 ([MWh)⁄year/m2] × 11240 [m2] × 0.15= 2,900,000 [kWh/ year] (Annual global solar exposure) × (Design area) × (Efficiency) = (Annual power generation)
For one Solar Palm Tree, taken the average efficiency of 22.5% [4], for eight units of leaf with leaf’s dimension of 4m*2m, the annual power generation is about 19,000kWh/tree. The area and capacity of lithium-ion battery we assumed are 0.1 m2/pack and 1.7 kWh/pack, respectively [7]. About 200 MWh batteries installation was assumed in this design area. We have estimated that the energy system with 1.7 MW solar panels and 200 MWh batteries can cover about 2000 MWh/year electricity demand according to the calculation based on daily profile of global solar exposure (kWh/day/m) [5]. REFERENCE:
[1] https://news.energysage.com/what-are-the-most-efficient-solarpanels-on-the-market/ [2] https://kameleonsolar.com/customization-options/#4 [3]https://m.made-in-china.com/product/Sunpower-100W-Foldingand-Flexible-Solar-Panel-for-High-End-Market-823086725.html [4] https://pse.com/aboutpse/EnergySupply/Documents/IRP_2015_ AppL.pdf [5] http://www.bom.gov.au/climate/data/index. shtml?bookmark=193 [6] https://news.energysage.com/average-solar-panel-size-weight/ [7] http://www.hitachi-chem.co.jp/english/report/057/57_tr01.pdf
EXTERIOR PERSPECTIVE
2. Grow Land
Studio Fire, University of Melbourne, 2018 Individual work (Semester-long), Tutor: Sarah Song Software: Rhino, AutoCAD, Photoshop, Indesign A new learning centre complex as part of the University High School, Story Street, Parkville, including General Learning Areas and a Sports Department.Established in 1910, The University High School relocated to its current site in 1930, and is the year 7-12 high school for the city and Docklands areas. The University High School is known for being dynamic and forward thinking, with various extension programs and specialist facilities, including the Elizabeth Blackburn School of Sciences and a city central language program.
“From the first day of schooling, children are taught to watch, perceive, and understand the beauty of the natural and social world around them.... We teach children to see the most detailed beauty of nature in all seasons and various weathers.� - Vasyl Olexandrovych Sukhomlynsky
CONCEPT
Encourage communication between different generations
Provide healthy indoor & outdoor areas for individuals & groups
Encourage students to learn from nature
FORM FINDING
INTERIOR PERSPECTIVE
General Learning Area
Architecture & Natural Student & Staff
Staff Area
Blur/balance the edge
Movable wall Maximum natural sunlight orientation facing north
Mixed function (For after-school activities)
CLASSROOM A
EXTERIOR PERSPECTIVE
CLASSROOM B
EXTERIOR PERSPECTIVE (FRONT)
3. Smart City
AA Visiting School, 2017 Group member/Group work (9 Days Studio), Tutor: Gilles Retsin, Zhang Lei An Intelligent Urbanism, shaped and materialized through flows of information through responsive infrastructure, interfaces and the Internet of Things. Software: Rhino, Grasshopper, Processing, Keyshot, ZBrush, Photoshop, illustrator
OPEN
CLOSE Design Statement open VS close (Urban Scale)
Unit system arrangements dissolves the smaller elements in a large form and creating a voxel based urban environment and generate a highly differentiated and complex urban fabric. The development of large form -BoxBoxBox- is optimised from serious of structural analysis, which minimise the material needs and allows the overall form to be created in a more economical way. The output of the analysis or a series of dates are utilised to further develop the arrangement of single module. The element design or the case design links to the idea of private and open space. Frame element around the unit or open plan creates more space and circulation. Solid elements in the middle of the module limits flow and the spaces are more divided and private. The processing scripts are provided by Gilles Retsin and further developed by Catherine Chow. STRUCTURAL FORM
MODULE 1.0
FORM
VOID
SUPPORT
LOAD
STRUCTURAL FORM
FORM STUDIES 2.0
MAXIMUM STRESS
STIFFNESS FACTOR
STRESS LINE
DEFLECTION
TENSION VECTOR
VONMISE STRESS
POINT CLOUD
PRINCIPAL STRESS
NEW DEFINITION DISSOLVE & REASSEMBLE IN CODING
TEST 1
TEST 2
TEST 3
SELECTED MODULE(BOX) TESTING 3.0 Same module-different form
Successful testing
Fail testing -Apply weight No load & Support Structurally failed the test
DESIGN 3
DESIGN 4
DESIGN 1
DESIGN 5
DESIGN 2
TEST 3-BOX
SLAB TEST 1 MASTER PLAN 1
MASTER PLAN 2
FINAL MASTER PLAN
4. Blood-cooling Glove
Studio Air, University of Melbourne, 2017 Semester-long, Tutor: Dan Schulz
Rabbit Ears
Computation on architectural design "Body of the future"
Built-in Radiater
Software: Rhino, Grasshopper, Photoshop
AVAs (arteriovenous anastomoses) Hairless areas o f t h e b o d y t h at feature extensive networks of veins very close to the surface of the skin.
The scenario for this studio is 'body of the future'. Designed a prosthetic/ wearable architecture that had an inside and an outside. This prosthetic augment a part of the body (arm). In order to find a new boundry of the body.
VASODILATION “On the other hand, when an endotherm needs to get rid of heat—say, after running hard to escape a predator—these blood vessels get wider, or dilate. This process is called vasodilation. Vasodilation increases blood flow to the skin and helps the animal lose some of its extra heat to the environment.”
COUNTERCURRENT HEAT EXCHANGE
Design concept-Biomimicry
VASOCONSTRICTION “Shrinking the diameter of blood vessels that supply the skin, a process known as vasoconstriction, reduces blood flow and helps retain heat.”
Palm and neck are usually referred to as ‘radiators of the human body’ (regions of the body surface designated for dissipating excess heat from the body core to the environment). When an athlete gets hot, blood flow at these regions naturally increases to dissipate heat through specialized blood vessels called arteriovenous anastomoses (AVAs). There are hairless areas of the body that feature extensive networks of veins, laid very close to the surface of the skin. Blood vessel circulation mechanism: When an endotherm (bird, mammals) needs to get rid of excessive heat—say, after running hard to escape a predator—these blood vessels get wider, or dilate. This process is called vasodilation. Vasodilation increases blood flow to the skin and helps the animal lose some of its extra heat to the environment. Furry mammals often have special networks of blood vessels, located in areas of bare skin, for heat exchange. For example, jackrabbits have large ears with an extensive network of blood vessels that allow rapid heat loss. This adaptation helps them live in hot desert environments. Stegosaurus bone plates may had played a passive role in managing body temperature because of their large size and extensive blood vessels.
DESIGN CONCEPT COLLAGE
Heat-exchanging vein network
Scenario 1: It is highly possible, if no effective countermeasures are taken, the global warming will continue to deteriorate and threatens to challenge human body’s capability to regulate its own temperature if exposed to high level of moisture and sunlight. This heat-exchanging vein network is invented, therefore, to assist our body’s self-regulation to cool the blood.
Scenario 2: Many people, particularly athletes and outdoor workers, struggle to keep their core body temperature at a certain level during those long, hot days of the year, and consequently, heatstroke is a common concern, in need of further solution.
COLLAGE
TOWARDS THE FUTURE-OPPORTUNITY IN THE SPORT INDUSTRY Legalised Functioning Clothes In accordance to the brief's consideration of the future context that the design could possibly be further developed, the team immediately thought of the scenario where the mechanic can be applied to clothes to create specialised functioning clothes in the future. These clothes can possibly be customised base on the nature of movements that typically needed for each sport and the affecting position of the user's bodies.
STRUCTURE DIAGRAM
170mm
R85mm
270mm
98mm
ELEVATION
SECTION
PLAN
How does the body function under normal thermal circumstances? As a steady-state situation, the heat produced by the body is balanced by the heat lost to the environment. An equation for the body heat balance can be written as:
M ± W = ± R ± C ± E ± S [W/m²] “where M is the rate at which thermal energy is produced by the body through metabolic processes, W is the rate of work produced by or on the body, R is the rate of radiant heat exchange with the surroundings, C is the rate of convective heat exchange with the surroundings, E is the rate of heat loss due to evaporation of body water, and S is the rate of heat storage in the body. Numerous studies have confirmed that in many species, an absorbed dose of microwave energy equivalent to the resting metabolic heat production, elevates the deep body temperature of the animal by 1 degree or more. S should ideally be close to zero in order to prevent body temperature changes.”
. How much heat does the body produce? According to the Basal Metabolic Rate (BMR), the heat production of a human in a thermoneutral environment (33°C or 91°F) at rest mentally and physically more than 12 hours after the last meal. Reference: 7-10 Polk, Charles and Elliot Postow, ed. Handbook of Biological Effects of Electromagnetic Fields. 2nd ed. CRC Press: Boca Raton, FL, 1995.
What are the means of heat loss from the body? Radiation, convection, and evaporation are ways of heat loss that are directly related to the surface area of the human’s body. A example: wind makes a hot day feel much cooler due to heat is removed from human body more efficiently.
FUNCTIONING DIAGRAM
SKETCH
STEAM 1
STEAM 2
PROTOTYPE DEVELOPMENT Steam 1: Fail Steam 2: Aimed towards finding the appropriate material and material and method to create the primary structure.
STEAM 3
Steam 3: Aimed to create the form of the vessel network that is self-supported.
ALTERNATIVE PROPOSAL Transparent 3D Printing & Fiberglass Prototypes
FINAL MODEL The final model reveals the discrepancy between itself and the digital model in terms of scale and materiality, Which was caused by the transition towards fabrication and assembly. However, it can still be considered as an architectural representation of the glove's functioning methodology, which is believed to be the most important objective of the model's role in the Prostheic Theme of the final presentation.
MAKING PROCESS
1
2
3
5. SERENDIPITY (Concept Design) SONA 2018 Design Competition
Australian Institute of Architects Team Leader/Group Work 48hr Design Studio Breathe in. Breathe out. Software: Rhino, AutoCAD, Photoshop, illustrator
"When seasoned by the subtleties of accident, harmony, favor, wisdom, and inevitability, luck takes on the cast of serendipity. Serendipity happens when a well-trained mind looking for one thing encounters something else: the unexpected." —— Margot Lee Shetterly
CONCEPT
As we observe a conventional study mode students usually takes is to sit at a stationary spot and look at laptops and readings. Usually they are too concentrated and forget about time and miss out what's going on campus. This is unhealthy and stressful. But changing the surroundings will make the studying journey more refreshing, relaxing and efficient.
CURRENT BLOCKY COMPUS
COMBINATION
ADDING A SHIFTING BELT FOR STUDYING
PORES ON ROOFSCAPE
ADDING A GRID OF SKYLIGHTS
REMOVING SKYLIGHTS
CONVENTIONAL STUDYING SETTING
NEW SLOW-SHIFTING BELT FOR STUDYING
You might start studying outside some classrooms on the morning, later you found yourself surrounded by outdoor gardens and breathe in fresh air or even take a short walk. On the afternoon you are exposed to a lot of events by other faculties.
So the constantly changing seneries makes your studying journey physically exposed to many other opportunities of relaxation and activities while you just stay on your moving seat. You might even make unexpected friends in this collective studying journey.
OTHERS Skectches, Paintings, Drwaings, Sculpture
OTHERS
- POINT/LINE/PLANE - MASS - FRAME & INFILL The three architectural research exercises carried out in this first part of the Studio Earth.
Skectches, Paintings, Drwaings, SculptureI
THREE RELATIONSHIPS
OTHERS Skectches, Paintings, Drwaings, SculptureI