ARCH EAN Yee Ann (Ean) Tan Portfolio
THE ROCKING CHAIR WORRYING IS LIKE A ROCKING CHAIR, IT KEEPS YOU IN MOTION BUT GETS YOU NOWHERE ASHWIN SANGHI
@arch.ean
TABLE OF CONTENTS
1. Curriculum vitale
6-11
01 EDUCATION
UNIVERSITY OF MELBOURNE
02 STUDY EXCHANGE
UNIVERSITY OF STUTTGART, TECHNOLOGICAL UNIVERSITY OF DELFT (TU DELFT)
03 WORK EXPERIENCE
CAPSTONE ALUMINUM, MINESCO, JANGHO
04 PROFIECEINCES TECHNICAL SKILLS
2. Cover letter (Insert)
12-15
01 CAREER GOALS AREAS OF INTEREST
3. Letter of recommendation
16- 21
01 MINSECO
EUNICE - PROJECT MANAGER
02 UNIVERSITY OF MELBOURNE LAURA - POSTGRADUATE STUDIO LEADER ANDY - UNDERGRADUATE STUDIO LEADER
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TABLE OF CONTENTS
4. Design Projects 01 OPPORTUNISTIC DWELLING
22-39
DESIGNING /ACTIVATING POTENTIAL SPACE Left-over space, Site evaluation, Urban planning initiative, Socia housing, Detailing, optimsied housing design.
02 MOTTAINAI
40-53
ZERO WASTE: OPTIMISE HOUSING Social housing, Site context evaluation, Space optimisation research, Building systems, Customisation, Energy effeciency
03 STACKED TOWER
54-61
TOWER DESIGN Documentation, drafting, solar and wind analysis, building environment system, podium, facade and crown design.
04 INFILTRATION
62-71
CHAOTIC INVASION Form finding, Algorithm,Parametric design and Conceptual design concept
05 ENCLOSE
72-85
DUAL FUNCTION: STORAGE AND STRUCTURE Detailing, Structure analysis, Prototyping, cost and functionality evaluation.
5. Personal Interest 01 TRAVELING AND PHOTOGRAPHY
86-97
CAPTURING MOMENTS IN LIFE
02 PERSONAL INTEREST SKETCHING/ PAINTING/DESIGN MODELS
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98-103
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THE UNIVERSITY OF MELBOURNE
CURRICULUM VITALE EDUCATION /STUDY EXCHANGE WORKING EXPERIENCE LEVEL OF PROFICIENCIES
THE JOURNEY KEEP WALKING THE WALK, ONE STEP AT A TIME JOYCE MEYER
@arch.ean
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1. Education 01 CATHOLIC JUNIOR COLLEGE
HIGH SCHOOL (2009-2010) While studying for my A Levels, I took part in various co-curriculum activities such as Canoeing, Overseas Community Involvement Projects and developed my personal hobby of sketching and painting. I was also awarded the National Youth Achievement Award (Gold) by the President of Singapore in 2009.
02 SINGAPORE ARMED FORCES MILITARY TRAINING (2010-2012)
During my service term I was given the opportunity to hold a leadership position, as a Sergeant. From the experience I learned how to lead men for missions and duties.
03 UNIVERSITY OF MELBOURNE
BACHELOR OF ENVIRONMENTS (ARCHITECTURE)(2012-2015)
04 UNIVERSITY OF MELBOURNE MASTERS OF ARCHITECTURE (2015-2017)
2. Study Exchange 01 STUTTGART UNIVERSITY UNDERGRADUATE WINTER EXCHANGE
During the exchange I learned about 20th Century Architecture and had the opportunity to visit some of them. In addition, I am blessed to have had the opportunity to travel around Europe and experience different cultures in breadth. Furthermore, I manged to learn basic German, so that I am able speak and understand German at a rudimentary level.
02 TU DELFT
POSTGRADUATE SEMESTER LONG EXCHANGE BUCKYLAB STUDIO Having such a good experienced during my Undergraduate exchange program I decided to plan for a full semester long exchange for my masters program. This would enable me to not only to learn from another university and have a longer period of time to experience a new culture. From the Buckylab studio at TU Delft I was able to study subjects that relate to building technology widening my understanding of the roles of the engineers and architects.
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3. Work Experiences 01 CAPSTONE ALUMINUM QUALITY CONTROL ASSISTANT DETAIL DRAFTING ASSISTANT
REFEREE Capstone Aluminum ,Malaysia Mr Tan Hua Tian : 017-7968586 Riady: 010-7103173
Quality Control Assistant: I assisted in the quality control and conducted various quality control checks on the aluminum extrusion. In addition, I also dabbled in Stock taking and the Checking of Quantity for Production. During my time there I oversaw the construction process of Curtain wall project for Singapore’s Park Hotel and Australia’s Macquaire Library and Medical Center
Building Facade Designer’s Assistant/ Third Party Quality Control Personnel for IGLU Project in Brisbane: Working in the Singapore branch, I had the opportunity to understand the process of getting BCA (Singapore) approval for curtain wall details, where I played a part in amending Shop Drawings and Panel Drawings for the Facade company Capstone. In addition I learned different components and features of windows and the Curtain wall Unitized Panels. I also visited the branch in Malaysia ,where I was antiquated with several key personnels in the glazing and curtain wall testing. I was fortunate to get first hand dialogue with Aluminum Power Coating Company (iCoat) in Malaysia and a Pre-casting Company (Coninco). During my time there I have had the opportunity to design a privacy screen for a client of Capstone Aluminum.
Capstone Aluminum Singapore Mr Tan Hua Joo : +65 96750752
02 MINESCO QUANTITY SURVEYOR ASSISTANT Minesco ,Melbourne Quantity Surveyor Assistant: I was assigned the role of stock taking and Eunice : +61 458972859 inspection of glazing panels for the company’s projects. Through the inspection Jessica: +61 433656720 process (of ensuring precision of panel dimensions), I was exposed to architecture, shop and fabrication drawings. During the internship I facilitated in various projects namely, Upper West side Podium and the Prima Pearl Tower, in Melbourne.
03 JANGHO
DETAIL DRAFTING ASSISTANT Intern facilitating an Engineer Designing structural details: During my internship, I had the chance to learn more about fabrication and basic shop drawings, over the duration I oversaw the commencement of Queensland Childrens Hospital.
Janho ,Brisbane Allan: +61 426200210 nx2005ky@163.com
School tutors UNIVERSITY OF MELBOURNE CONSTRUCTION TUTOR (MARK LAM)
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University of Melbourne mark.lam@unimelb.edu.au
4. Proficiencies 01 3D MODELING
RHINO 3D GRASSHOPPER PLUG-IN 3D MAX SKETCH UP REVIT
02 RENDERING PHOTOSHOP V-RAY
03 TECHNICAL DRAWINGS ILLUSTRATOR AUTOCAD
04 LAYOUT INDESIGN
05 MODEL MAKING LASRCUTTING 3D PRINTING CARD CUTTING
06 ADMINISTRATION WORDS POWER-POINT EXCEL
07 VIDEOGRAPHY AFTER EFFECTS
08 ANALYSIS PROGRAMS
GRASSHOPPER -LADYBUG (SOLAR AND WIND ANALYSIS) ECOTEC (SOLAR AND WIND ANALYSIS) CES (MATERIAL/COST ANALYSIS) SEFAIRA (BUILDING SYSTEM ANALYSIS) DIANA (STRUCTURAL ANALYSIS)
09 MAPPING ARCGIS DEPTHMAP
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SEARCH FOR EVERYONE WHO ASKS RECEIVES; THE ONE WHO SEEKS FINDS; AND TO THE ONE WHO KNOCKS, THE DOOR WILL BE OPENED. Matthew 7:8
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COVER LETTER
More about me 01 ISSUU : OTHER PROJECTS http://issuu.com/yeeann
02 INSTAGRAM : HOBBY
https://www.instagram.com/arch.ean/?hl=en
03 EMAIL ADDRESS tanyeeann@hotmail.com
04 CELLPHONE +61 420440101
05 WEBSITE
https://wordpress.com/post/archeanblog.wordpress.com/9
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ENDEAVOR WHATEVER YOU DO, WORK HEARTILY, AS FOR THE LORD AND NOT FOR MEN, Colossians 3:23
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LETTER OF RECOMMENDATION MINESCO -EUNICE UNIVERSITY OF MELBOURNE - LAURA, ANDY
15 HEWITT WAY TULLAMARINE, VICTORIA, 3043 AUSTRALIA TELEPHONE (+613) 8318 8800 FACSIMILE (+613) 9338 1888
To : Whom it may concern
Re: Mr.Tan Yee Ann Dear Sir/Mdm Yee Ann worked with us as a design assistant for 10 weeks in 2012-2013 between the periods of November to January. In the time that Yee Ann worked with us, Yee Ann was in charge of checking the fabrication drawings of windows and doors for Upper West Side AppartmentTower 2 located at Spencer St, Melbourne. He has demonstrated good understanding of fabrication details, taking on the role in ensuring the dimension are correct before actual production. Yee Ann is a fast learner who was able to observe and quickly pick up skills required. We were also impressed with how responsible Yee Ann was despite his young age. Yee Ann is always punctual despite the long commuting hours to come to our office. We would love to have Yee Ann work with us again during his holidays. I believe he would be an asset to any employer that hires him.
Yours Sincerely
Eunice Lee Project Manager Minesco Pty Ltd
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From:
Laura Mártires, Mártires Doyle
10/07/17 To whom it may concern,
In my capacity as a sessional staff member at the Melbourne School of Design, I have known Tan Yee Ann for approximately two years. Yee Ann was a member of my masters design studio ‘The Selfish Gene’ in 2015. During this period he struck me as a driven student with strong work ethics and an enthusiastic interest in the architectural/urban research fields to produce complex architectural outcomes. He has demonstrated very good drawing and 3d modeling skills and a strong sense of critical self assessment and reflection upon resultant designs. During the semester he was able to adapt and create unique responses to the architectural problems posed by the studio as well as a great sensitivity to the effects of architectural design in built environments. He seemed genuinely interested in learning and engaging with out of the ordinary design ideas even when unfamiliar with them. For these reasons I believe he would be a great candidate for a position that allows him to learn and grow as an architect, as well as providing an important exposure to a range of ideas that could assist his professional career. I believe he is an engaged and hard-working individual that could positively contribute to an established design team,
Kind regards,
________________ Laura Mártires (Director)
36 Cobden Street, North Melbourne VIC 3000
T 03 9020 1007 E hello@martiresdoyle.com www.martiresdoyle.com
ACN: 149940910 ABN: 2973476470
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Letter of Reference for Mr. Yee Ann Tan
To whom it may concern I am writing in the capacity as Mr Tan’s studio tutor in Architecture Design Studio “Earth” in 2013, Bachelor of Environments, University of Melbourne. Mr Tan has shown an academic aptitude and ambition above his peers, he participated the studio with great interest and enthusiasm. It was clear that he put in great efforts in all his assignments, which was evident from the quality of his weekly assignments as well as his final project. He is noted for his hardworking ethics and his willingness to improve himself as a designer. He often made critical remarks on class discussions that demonstrated his ability to analyze designs and In addition, he has shown a great capacity to take on critiques and develop his design. Without reservation, I recommend him highly as a candidate for employment. Please do not hesitate to contact me to provide you with any further information regarding Mr Tan. Best regards,
Andy Yu E : andy.ca.yu@gmail.com T : +33 799 78 9194 (France)
16.07.2017
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DESIGN PROJECTS OPPORTUNISTIC DWELLING
Can the city provide dwellings for the marginalized?
Figure 1: Illustration that encapsulate the key question that provoked an investigation to 1. exisiting dwelling condition 2.dwelling designs 3. underutilised 'left-over' space within the city
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Can 'left-over' public space be considered to create dwellings spaces for inhabitation in Melbourne CBD
M
elbourne has been lauded as one of the world’s most livable cities for the past 6 years, according to The Age and ABC News.1,2 This has been largely attributed to its medium density population, moderately priced housing, and accessible transportation. Over the last few years however, the population of Melbourne has increased and is expected to double in the next 15 years.3,4&5 To cope with the new influx of people coming into Melbourne, housing developments have increased exponentially. A report carried out by City of Melbourne shows that 5154 new dwellings were constructed last year and another 17,074 residential dwellings are underway.6 However, a study conducted in
same year (2016) has revealed shocking truths about Melbourne’s housing situation. It is identified that 4.8% of the total apartments lie vacant in Melbourne city.7 The past two years have also revealed a 74% estimate increase in the population of homeless individuals who sleep in the CBD.8 Considering literature such as Opportunistic Urbanism, Pet architecture and Loranin Henning’s book on Squatting has propelled this project to reconsider ways in which underutilised spaces in the CBD can be better utilised. 9,-12
An investigation of underutilized public spaces within the urban fabric has been conducted and 15 spatial typologies identified. This project serves as a precursor investigation to the development of these potential sites for
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Laneways
Laneways
Parks
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Dead corners LanewaysDead corners
Awnings Public walkways
‘Flag-Site’ Dead corners
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Awnings Edges of buildings Edges of buildings Public walkways
Parks Awnings Public walkways
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Public Space
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Potential opportunity sites (Left-over space typology) Roof tops
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Public SpaceCorners Public Space
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Public space Public space Public space Public toilets Food/ news stand Food/ news stand
'Flag-site' Public Space Public Space
Edges of buildings
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Space that is not utilised 24/7 Laneways Car parks Office buildings
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stops Bus stops RooftopBus extensions Public Space
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24/7 that is not utilised 24/7 Space that is not utilisedSpace Abandoned buildings Office buildings Office buildings
24/7 that is not utilised 24/7 Space that is not utilisedSpace Space that is not utilised 24/7 Abandoned buildings Abandoned buildings Car Car parks tops Roof topsCar parks Roofparks Office buildings Office buildings Office buildings
Abandoned buildings Laneways Dead corners
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Space that is not utilised 24/7 ‘Flag-Site’ Office buildings
corners Dead ‘Flag-Site’
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Space that is not utilised 24/7 Car parks Office buildings
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Space that is not utilised 24/7 Car parks Office buildings
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Space that is not utilised 24/7 Roof tops Car parks Office buildings
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Building edges Laneways
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space space Public Public stops Bus 24/7 Space that is not utilised Road barriers Car parks Office buildings
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buildings A. Designing toAbandoned respond to the
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Space that is not utilised 24/7 Car parks Office buildings
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Public space Food/ news stand
Awnings ‘Flag-Site’ Public walkways
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C. Transaction between stakeholders, of buildings Edges 24/7 utilised is not Space that
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Space that is not utilised 24/7 Car parks Office buildings
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Figure 2-16: Potential underutilsed space 'left-over' space Figure 17-19 : Design principles guiding the design of the small dwelling intervensions
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Public space Public toilets Space that is not utilised 24/7 Office buildings
towards a positive compromise
Public space Bus stops
Public space Bus stops
Space that is not utilised 24/ Office buildings
Public space Food/ news stand
building elements
Roof tops Public space Bus stops
Abandoned buildings
Public space Food/ news stand ParksDead corners
B. OptimsingParksboth the site and
immediate context
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Space that is not utilised 24/7 Office buildings
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that is not utilised 24/7 Space buildings Abandoned Office buildings
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Public space Public toilets
Public space Food/ news stand
Public space Food/ news stand
Public space Food/ news stand
inhabitation. It focuses on the evaluation of two typologies, namely lane-ways and shop awnings. The following are the three design principles governing the design process. 1. Designing to respond to the immediate context 2. Optimsing both the site and building elements 3. Creating a transaction between stakeholders, towards a positive compromise of the public space. - both residents and the public would benefit from the urban intervention.
Potential spaces found in Melbourne city
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his project has inhabitation potential in these ‘left-over’ spaces9 . Depending on the developer these dwellings could aid in, but are not limited to: 1. Challenging the existing housing scheme by providing affordable dwellings for marginalised communties in response to Melbourne’s existing needs. This can be realised through a collaboration between the Victorian government and non-governmental organisations (NGOs) such as the Salvation Army, Council for the Homeless and Sacred Heart Missions.
These temporary installations could potentially be long term depending on the owner of the dwellings. In conclusion, this project hopes to start meaningful conversation between architects, urban planners and the city council on the potential of left-over spaces in Melbourne CBD.9 References: 1. abcnews. “Australian Cities among most Liveable due to their Size, Say Experts.” abcnews, last modified August 18, 2016, accessed March 21, 2017, http://www.abc.net.au/news/2016-08-18/australian-cities-among-most-liveablebecause-they-are-smaller/7763016. 2. Clay, Lucas. “Melbourne Named World’s most Liveable City, for Fifth Year Running.” The age, last modified August 19 2015, accessed March 2017, 2017, http://www.theage.com.au.ezp.lib.unimelb.edu.au/victoria/melbournenamed-worlds-most-liveable-city-for-fifth-year-running-20150818-gj1he8.html. 3. Anderson, Stephanie. “Melbourne’s Population Tipped to Double as Victoria Grows to 10 Million, New Projections show.” abcnews, last modified July 15, 2016, accessed March 17, 2017, http://www.abc.net.au/news/2016-07-15/ melbourne-double-in-size-as-victorias-population-10million/7632700. 4. Butt, Craig. “Apartment Numbers in Melbourne could Double in Coming Years.” domain, last modified April 8 ,2016, accessed March 20, 2017, https://www.domain.com.au/news/apartment-numbers-in-melbourne-could-double-incoming-years-20160407-gnyr2b/. 5. City of Melbourne. “Development Boom in Melbourne as Population Grows.” City of Melbourne, last modified February 23 ,2017, accessed March 20, 2017, http://www.melbourne.vic.gov.au/news-and-media/pages/ development-boom-in-melbourne-as-population-grows.aspx. 6. David, Rebecca. “Massive Number of Melbourne Homes are Lying Vacant, Angering Homeless Agencies.” Herald Sun, last modified February 16, 2016, accessed March 14, 2017, http://www.heraldsun.com.au/news/victoria/ massive-number-of-melbourne-homes-are-lying-vacant-angering-homeless-agencies/news-story/86c1de02ad a02dce7c9b1bca9f6b147d.
2. Housing overtime workers for an immediate resting space, this alternative would naturally be funded by the owners of the respective buildings or businesses.
7. George, Bernadette. 2016. “Solving Melbourne’s Housing Crisis in Five Easy Steps.” Planning News 42 (7): 18. 8. Dow, Aisha. “The Homelessness Crisis Gripping Melbourne “, last modified July 18, 2016, accessed March 17, 2017, http://www.theage.com.au.ezp.lib. unimelb.edu.au/victoria/the-homelessness-crisis-gripping-melbourne-20160715-gq6yog.html. 9. Ramirez-Lovering, Diego. 2008. Opportunistic Urbanism Melbourne : RMIT Publishing, 2008. 10. Kaijima, M., 1969-.Petto kitekuch gaidobukku = pet architecture guide book. Tky: Wrudo Foto Puresu. 11 Bow-Wow, Atelier. 2005. Some Pet Architectures Architectural Association of Ireland. 12. Henning, Larrane, ed. 2013. A Practical Guide to Squatting: waxcastle workshop.
3. Becoming a novelty hostel that allows transient residents to be immersed in the unique urban setting.
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Section AA (Dwelling 1 & 2 )
Bourke Street
Lt Bourke Street
Section AA Figure 41 (Top): Section AA (1:100 not to scale) Figure 42 (Bottom): Section AA (1:500 not to scale) Figure 43 (Right): Section BB (1:50 not to scale)
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The subsequent drawings that would showcase urban intervension of the two selected 'left-over' space typology explored, namely the laneway and awnings. The images on the right showcases the laneway design of an the axonometric drawings of dwelling 1&2 (Figure 44) . It showcases the construction of the various building components, while showing the plans of each dwelling. The bubbles in Figure 44, highlights the various optimising elements on site based on the 3 designing princples described earlier (Figure 17-19 ). On the right (Figure 45), the drawings showcases three axonometric detail of the dwelling 1 &2 . In the subsequent pages, renders of the dwellings 1 and 2 would be shown. Followed by the section, renderings , axonometric drawings and details of dwelling 3-8 representing the exploration the potential of an awing typology.
Figure 44 (Left) : Exploded axonometric drawing of dwelling 1&2, showing the construction and plan of the dwellings (1:50 not to scale) Figure 45 (Right) : Three exploded axonometric detail drawing of dwelling 1&2 (1:25 not to scale)
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Figure 46(Left) : Render of dwelling 1 & 2 view south of La Trobe Pl. Figure 47 (Top) : Peeled back render of dwelling 2 Figure 48 (Middle) : Render of dwelling 1 Figure 49 (Bottom) : Render of La Trobe Pl with public space created as a result of the addition of dwelling 1 &2
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*Dwelling section is set back from section cut with facade peeled
Swanston Street
Russell Street
Section BB Figure 50 : Section CC of the dwellings 3-6 (1:100 not to scale)
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Figure 52 (Top) : Render of dwelling 3-6 of the awning typology intervension along Bourke street. Figure 53 (Top-left) : Render of dwelling 3 interior Figure 54 (Middle-left) : Render of first floor vestibule to dwelling 3 &4 Figure 55 (Bottom-left) : Render of second floor vestibule to dwelling 5 &6 Figure 56 (Right) : Render of dwelling 3-6 along Bourke street.
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Figure 57 (Left) : Exploded axonometric drawing of dwelling 3-6, showing the construction and plan of the dwellings (1:50 not to scale) Figure 58 (Right) : Three exploded axonometric detail drawing of dwelling 3-6(1:25 not to scale)
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DESIGN PROJECTS MOTTAINAI
Figure 59: Internal render of dwelling showcasing the kitchen and living area with a foldable small dining table. Figure 60: Internal render of bedroom with space optimising beds that fold down and sliding screens that can divide pubic and private areas.
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'Mottainai is a Japanese phrase captures the essence of ‘not wasting’ or‘don’t waste’
M
ottainai is a housing design project aimed at improving the social housing conditions in Curitiba Brazil. It reinvents the existing social housing scheme. It is a project that investigates how small spaces can be optimized in order to make dwellings comfortable despite small spaces. Mottainai dwellings utilises space-saving furniture and partition screens to achieve multifunctional and flexible internal space. As part of the course, students had the opportunity to visit and experience the favala lifestyle that is common in the lower income groups. This experience contextualised and enabled the design to identify the various dynamics of a family unit.
the hope of meeting different family units, while keeping the dwelling design fairly standard (Figure 64) This design allows flexible expansion or reduction dependent on the family cell. In addition to the optimization of dwelling spaces, this project considers local materials and methods which facilitate the homes in achieving zero energy. This course is linked to Zero Energy Mass Custom Home (ZEMEC) Network. This project addresses both the present and the future issues of social housing. The project not only seeks to showcase a range of housing material options but discusses the potential of achieving homes that fully optimises the site conditions. The inclusion of light transmittable polycarbonate facades, skylights and rainwater catchments aid in reaping maximum benefits.
8 dwelling configurations were established through this project in For more information on ZEMEC Network and this course please visit : http://ndsufpr.wixsite.com/zemch2016
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MOTTAINAI もったいな Moradias Castanheira (Villas Castanheira)
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Total area :4128 m2
40 m
88.4 m
10m slope gradient
100
0
200
In between 2 two-way Roads Top road : Rua Joãƒo Kowal Bottom road: Rua Acir Perira Conserved vegetation on the East of the site
Figure 61: Site plan of the social housing in Curitiba, that responds to the local site condition, optimising the site conditions.
Issues with existing site Figure 61 showcases the new site proposal which optimses natural lighting and prevents overshadowing of the adjacent Increase GHG and CO2 Loss of Eco-diversity as a emission result of urban sprawl house.
of case studies (Figure 62).
The housing plans are designed with the various rules in mind. In Insufficient housing for low Most homes in Brazil are poorly income people slumps massinsulated homes with zinc roofs orderliving toinenable customisation, and concrete walls different housing options (Figure The development of design rules 63) are designed within a standard were born out of an investigation to grid with a paired dwelling unit optimise space through the analysis (Figure 64). There is a total of 6
Cohab house design
(Not meeting the need of users)
Expansion of boundaries
and alteration of internal space
Design Concept: 44
Construction of wall fences
Unsightly Litter
Resident: Diverse family unit
Bad living conditions in river settlement favelas
Government: balancing
between cost and quality of living space
Relo fave
Mottainai
Multi-Functionality
Condensed Living
This Japanese phrase captures the essence of ‘not wasting’.
A single component that can perform many functions.
Avi Friedman/ Alejandro Aravena
Small, tall and narrower homes require less materials Energy saving --> adjacent buildings reduces heating of up to 30-40%
1. Loss of Environment --> reduce materials and architecture footprint 2. Lack of housing for low income communities --> de nsifying the site
Reduce urban sprawl Optimising space : Free plan --> utilising partitions
3. Cheap and little materials to construct homes.
Design rules
Society
Comfort
Efficiency 5. Communal space to promote social
1. Double height volume for cross
9. Optimising building components 2. Living spaces facing north Long side facing north to get more
th store inds (southeastern wind)
Rectangle module
elderly
3. Spacing out homes to prevent overshadowing. 2
A
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IRA
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Elderly/Disabled family
Extended family
Figure 62: Design rules
40 m
m
Cohab’s plan is to cram as much apartments into the site without any consideration of
ay Roads
o Kowal
1. The site context
cir Perira
2. Social conditions
n on the
3. Future developments.
er
Single family
7
200
20 m
m
4128 m2
Flexibility of grid plan allowing for rearrangement of partitions
b. Stacking of homes.
3. Overcasting of shadows 4. Brief requirement (32 houses)
6.00
3.00
2.00
1.00
+0,00
Standard nucleus family
dynamics. Double height potential space
Different size houses. a. Puzzle module
1. Sunlight 2. Capturing natural ventilation.
12.00
JO
Bigger
1
4. Responding to site conditions Balancing between
10. Adaptable for future changes in family
7. Meet the needs of different demographics
Smaller
ture of Coldest month ( June):
A
component furniture)
c. Internal partition of space
Puzzle module
ing site itions
a. Envelop (walls, ceilings, roofs) b. Furniture (fold-able, unit
6. Provision of ground floor access for
Grid Unit: 1500x750 Height: 5m Step Distance: 4.5m House Area: 33.75sqm house
natural light
RU
Modular Grid
House Unit
House dimension: 9000x3750 Semi detached house (balance between heat loss and natural light)
mild temperate climate hly temperatures of 7.7oC ture in Curitiba is 16.50C average: 10.3oC ture of Hottest month (February):
8. Quick construction
cohesion
ventilation
いない
5
Toilet/Kitchen module fixed: 3000x 2250 2 dwellings and 4 dwelling for each house unit
0
1
2
4
6
10
14
1:200 on A0
Dwelling Type
Sleeping
Working/ studying
Customisable components
Leisure/ weekends
A
Double storey for future expansion+ cross ventilation
1
2
Dwelling 1: (more efficient space) 2 Bedroom + 1 Living bedroom + Bigger living room space Single parent
A
Standard nucleus family
2x4 Grid
Double deck bed
Dwelling 2: (more privacy option) 2 Bedroom + 1 Living room
g ty
Ventilation Natural light Outdoors
- Smaller living room + More private spaces Single parent
Relocation of the Riverside favela to Social housings
Loft bed/table module
Foster community
Standard nucleus family
Awning wall
3
Designing and planning
4
B
B
Ground floor units for family with elderly
Architects and Urban planners IPPUC:
Dwelling 3 (more efficient use of space) 1 Bedroom + 1 Living bed room
C
Single Parent Standard Nucleus
3
iving
4
5
2x5 Grid
Double deck bed
Family Room
2x Loft bed/
2x Loft bed/ table module
Double deck bed
table module
C
Dwelling 4 (more private space) Single storey
1 Bedroom + 1 Living bed room Single Parent Standard Nucleus
6
ess materials uces heating of up to 30-40%
g partitions
2x4 Grid
Double storey for future expansion+ cross ventilation For extended family with the potential to expand upwards D
Dwelling 5: 1 combined Bedroom + 1 Living bedroom + 2 big living space Extended family Standard nucleus family
D&E 2.5x5 Grid
Dwelling 6: 1 Bedroom + 1 Living bedroom - No living space in pubic areas + Can utilised both bedrooms and transform them into a big living/multi-functional space. Extended family/ Standard nucleus family/
2 rooms separated by screens
Single room divided by a
2 separated rooms
screen
E
Single parent family
struction
Double deck bed/ living room space
F
2.5x4 Grid
Single room that can be a living room
2 separated rooms
g building components op (walls, ceilings, roofs)
ture (fold-able, unit nent furniture) nal partition of space
F
7
8
e for future changes in family
height potential space ity of grid plan allowing for gement of partitions
7
8
Ground floor units for family with elderly Dwelling 7: 3 Bedroom + 1 Living bedroom + big living space Extended family/ Standard nucleus family
G
3.5x3 Grid
Dwelling 8: 2 Bedroom + 1 Living bedroom - No living space in pubic areas
+ Can utilised both bedrooms and transform them into a big living/multi-functional space. Extended family/ Standard nucleus family/ Single parent family
2 bed rooms/ living room
2 bed rooms/ living room
1 bedroom/ living room
2 bed rooms and a storage
3 bedrooms
4 bedrooms
G
3x4 + 3x2 Grid
F 1:100 on A0
0
00
1
2
4
6
10
14
Yee Ann, Tan 573608
Figure 63: Design panel showcasing the various dwelling options
45
1 2.
Dwelling 5
Dwelling 6
3. 4. 5. 6. 7.
1:50 Axonometric drawing of dwelling 5 & 6 1
1T 2.P 3.T
2.
3
1. R 2. P 3. I
Figure 64: Axometric diagram of a standard dwelling unit pairing.
dwelling options. The materials are evaluated (Figure 65) according to the varied dwelling options alongside a list of different structural and materials involved in mass customisation.
46
Customised social homes would utilise materials that are more affordable. The option of including more advanced materials and building systems arise as a option when the project has eventuated.
1. Seamless diamond patterned
5. Light brown ceramic tiles
9. Skylights /solar hotwater
3. Light grey slate shingles 4. Dark brown ceramic tiles
8. Solar PV roofs
12. Rainwater collection
slate shingles 2. Dark grey slate shingles
6. Light grey corrugated steel roof 7. Green roof
10. Timber shingles 11. Red corrugated steel roof
Material option: External walls Solid wall options 1
2
3
4
5
1 Reinforced concrete with form-work texture (150mm 0.95) 2. Standard reinforced in-situ concrete walls 3. Reinforced concrete panels 4. Licracon wall 5. Mycotech wall
Framed wall components 1
2
3
4
5
6
7
1 External cladding (polycarbonate) 4mm twin wall 1.42 R-value
Dwelling 6
2. Insulation/ fill for framework (bubble wrap/air) 3. Framework (Steel) 4. Internal finishing (polycarbonate) 5. Blinds (either 5 or 7) 6. Openings (windows and door frames) 7. External Shading (Screens/Sunshades)
1 External cladding
3. Framework 1
2
4
5
1 Timber board 2.Painted plywood 3.Texture fiber concrete panels
2
6
4.Fiber cement cladding panels 5. Colored polycarbonate wall 6.Polished concrete or plaster for paint application after completion.
2. Insulation/ fill for framework 1
1
3
1. Steel frame 2. Timber frame
4. Internal finishing 1
2
2
4
3 3
1. Recycled paper insulation 2. Paper tubes with insulation 3. Insulation boards
1. Polycoated recycled paper 2. Recycled paper panels. 3. Oriented strand board (OSB) 4. OSB painted with white paint
Figure 65: Material options for customisation. Yee Ann, Tan 573608
47
0
1
2
4
6 0
1
2
10 4
6
Dwelling 5 14
10
14
Dwelling 6
Figure 66 & 67: Axonometric drawing of the dwelling iteration pairing option (dwelling 5 & 6)
48
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+0
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5
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1:100
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E
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200
D wel l i ng 5 mo d u le
D wel l
i ng 6
A B/C
L1 zone
Figure 68: Rendered plan for Dwelling 5 & 6 option.
9.00
7.00
8.00
49
mo d u
le
ey
5
6
9.00 10.00
RU
A
02
AA
12
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0
BB
r family members at home)/weekend
bqor just to rest and be expose to nature
100
200
0
1
2
6
4
Figure 69: Block diagram for dwelling 5 & 6 Figure 70:Plan of dwelling 5 & 6
50
0
1
2
4
6
10
14
10
14
Section AA
Activity: Work/study
Section BB
Activity: Work/study
1:100
Figure 71: Section AA (Work/study layout) Figure 72: Section BB (Work/study layout)
51
Section AA
Section BB
1:100
Figure 73: Section AA (Weekend/ leisure layout) Figure 74: Section BB (Weekend/leisure layout)
52
Activity Leisure/weekend
Activity Leisure/weekend
53
54
DESIGN PROJECTS STACKED TOWER
56
Photo by Shawn Koh Jyh Shen
Stratified bands repeat along the stacked segments. of the tower. at and clean an and SINGLE WESTERN FACADE UNIT
0 a3.2
S
SINGLE NORTHERN FACADE UNIT W
ES
tack tower is a T FACADE construction focused AXONOMETRIC EXPLOSION OF THE WEST & NORTH FACES DETAILED EXPLOSION UNITS the floor project.OFItSINGLE reduces areas and lift cores as it increases in height.
PASSIVE CIRCULATION SYSTEM THROUGH HIGH AND LOW OPENINGS VIA LOUVERS.
The tower is positioned in an optimum orientation to maximize solar heat gain, natural lighting and wind shear (Figure 75)
E
AD
AC ThisRTproject utilises a novel cooling HF NO system, the underfloor air distribution system (UFDS). Fresh air is drawn from the facade of the building through the underfloor space. It's temperature is mediated by the slab's thermal mass (Figure 76 & 77)
ACTIVE CIRCULATION SYSTEM IS ACTIVATED VIA MOTORIZED LOUVERS & ENVIRONMENTAL SENSORS
The subsequent pages showcase the details of the integration of the UFDS and the curtain wall facade.
JWI 100.VF PITCH ADJUSTABLE ALUMINIUM VENTILATION LOUVERS SOLARONIX PHOTOVOLTAIC SUNSHADING SYSTEM
0 A3.2
ENVIRONMENTAL CONTROL SYSTEMS & PHOTOVOLTAIC SUNSHADING ACTIVE & PASSIVE SYSTEMS & PHOTOVOLTAIC SUNSHADING SYSTEM BY SOLARONIX
SINGLE WESTERN FACADE UNIT
SINGLE NORTHERN FACADE UNIT W
ES
TF
AC A
H RT
DE
NO ENVIRONMENTAL ANALYSIS A3.2 WIND ROSE & SOLAR ANALYSIS AT THE PEAK OF SUMMER AND WINTER AXONOMETRIC EXPLOSION OF THE WEST & NORTH FACES 0 JEN YOUNG TAN APPLIEDa3.2 CONSTRUCTION ABPLEXPLOSION 90118 ENVELOPE : DETAILED OF SINGLE UNITS TAN YEE ANN
CA FA
DE
0
SEM 1 / 2016
TUTORIAL 1 Dr. MARK LAM MODEL & 3D
CATHERINE MEI MIN WOO
DRAWING GROUP 1
A 3.2
PASSIVE CIRCULATION SYSTEM THROUGH HIGH AND LOW OPENINGS VIA LOUVERS.
ACTIVE CIRCULATION SYSTEM IS ACTIVATED VIA MOTORIZED LOUVERS & ENVIRONMENTAL SENSORS JWI 100.VF PITCH ADJUSTABLE ALUMINIUM VENTILATION LOUVERS SOLARONIX PHOTOVOLTAIC SUNSHADING SYSTEM
0 A3.2
ENVIRONMENTAL CONTROL SYSTEMS & PHOTOVOLTAIC SUNSHADING ACTIVE & PASSIVE SYSTEMS & PHOTOVOLTAIC SUNSHADING SYSTEM BY SOLARONIX
Figure 75: Wind analysis and Solar orientation analysis Figure 76: Underfloor air distribution system (UFDS) and sunshade responding to sunpaths
57
2100
2100 2100 2100 5 2100
1500 1500 1500 1500 1500 1500 1500
945
52100 5 2100
945 1840 945 945 945 1840 1840 1500 18401840
300
945 1840
DOUBLE GLAZED GLASS STEEL EMBEDDED COLUMN
SUNSHADING ALUMINUM FINS ANGLE AT 30°
A
BRACKET
BAND BEAMS @ 2000 CTRS
N
SMOKE CAP
400
2600
400 400 400
STACK JOINT
4000
400
400 2600
2600 4000 4002600 400 400 400 2600 26002600 4000
LOUVERS
1500
600
FIRE PROOFING COATING STEEL UB STRUCTURAL TRUSSES
2600
NORTH ELEVATION
600 600
BIRD MESH
400
LOUVERS 1500
600
1500
400
HORIZONTAL BRACING
PT CONCRETE SLAB
TRING-
SC 3.6KN SED FOR E.
A
C
600X1200 GRID LAYOUT
FRAME
HE EEN THE EVENT
LOUVERS
RAISED FLOOR SYSTEM DUCT WORK INSULATION BAND BEAMS @ 2000 CTRS
STACK JOINT
PT CONCRETE SLAB BRACKET BOLTED WITH MOVEMENT JOINTS FILLED WITH GROUT EDGE BEAM LOUVERS FIRE PROOFING COATING
600 400
TOP HAT BRACING ALUMINUM LOUVERS FRESH AIR INPUT
58
4000
AIR VENTS
DRAWING TAN YEE ANN GROUP 1 CATHERINE MIN WOO Figure 77:MEI Technical drawing of plan and section of the middle section of the tower, showing sunshading and UFDS 2600
ASSIGNMENT 4.2
SUNSHADING TRIPLE GLAZED ALUMINUM FINS PANEL VISION ANGLE AT 30° YOUNG TAN JEN
A 4.2
TYPICAL FLOOR
SUSPENDED CEILING ARMSTRONG PEAKFORM PRELUDE 24 SUSPENDED CEILING
section : TYPICAL AND M&e fLOOR 50 140 1:50 at A2
LAM STRUCTURE: TOWER FACADE 1500 1500 1500
N
UNDERFLOOR AIR DISTRIBUTION SYSTEM VENT
4000
STER T RROSION.
RAISED FLOOR SYSTEM: SC ULTRA FIXED SYSTEM
BAND BEAMS @ 2000 CTRS
HORIZONTAL BRACING VERTICAL BRACING BIRD MESHBRACING VERTICAL HORIZONTAL BRACING LOUVERS VERTICAL BRACING HORIZONTAL BRACING MODIFIED CURTAIN WALL VERTICAL BRACINGBRACING HORIZONTAL BRACING VERTICAL SUNSHADING BIRD MESH BASED OFF CAPRAL MODULE INSULATION HORIZONTAL BRACING ALUMINUM FINS BRACING HORIZONTAL ALUMINIUM LOUVERS BIRD ANGLE ATMESH 30° BIRD MESH CW150 Curtain Wall LOUVERS ALUMINUM SPANDREL BEAM SUPPORT PLATE WITH INSULATION LOUVERS PANELS ANCHOR BOLTS BIRD MESH 150MM X 75MM FRAME BIRD MESH INSULATION ALUMINUM LOUVERS LOUVERS INSULATION LOUVERS FRESH AIR INLET PLATE WITH FIRE STOPPER BEAM SUPPORT BIRD MESH ROCK WOOL ANCHOR BOLTS BEAM SUPPORT PLATE WITH INSULATION CONCRETE EXTENSION CAST IN INSERTS INSULATION BEAM SUPPORT ANCHOR BOLTS PLATE WITH FIRE STOPPER SMOKE CAP ANCHOR BOLTS ROCK WOOL 3 SMOKE BARRIER FIRE STOPPER BEAM SUPPORT PLATE WITH ALUMINUM LOUVERS A 5.2.1 BEAM SUPPORT PLATE WITH CONCRETE EXTENSION FIRE ROCK WOOL ANCHOR BOLTS HOT AIR STOPPER EXPLUSION ANCHOR BOLTS ROCK WOOL CONCRETE BLIND PELMET EXTENSION CONCRETE EXTENSION FIRE STOPPER FIRE STOPPER ROCK WOOL 7ROCK WOOL ALUMINUM MULLION CONCRETE EXTENSION CONCRETE EXTENSION A 4.2
WEST ELEVATION
ECTURAL
300mm DEEP WITH VERTICAL BRACING 3 ANCHORS HORIZONTAL BRACING REBATE FILLED WITH GROUT VERTICAL BRACING BIRD MESH
CARPET FINISH
600x300 CONCRETE TILE 8000
ALUMINUM TRANSOM SUSPENDED CEILING: ALUMINUM TRANSOM SERRATED BRACKET ARMSTRONG CAST IN INSERT PEAKFORM PRELUDE 24 STEEL PLATE WITH BOLTS
UNDERFLOOR AIR DISTRIBUTION SYSTEM VENT 600
400
: SC
8000
ALUMINUM TRANSOM ALUMINUM TRANSOM ALUMINUM TRANSOM M16 ANCHOR BOLT
SUNSHADING ALUMINUM FINS ANGLE AT 30°
DOUBLE HEIGHT M & E FLOOR
A STEEL UB STRUCTURAL TRUSSES ALUMINUM TRANSOM
SMOKE BARRIER
DOUBLE HEIGHT M & E FLOOR
1600 POWERSHADE SUN SHADE SYSTEM
BAND BEAM EDGE BEAM
300
OPTIONAL SOLAR PANELS: ALOCA
AND SSES OF THE
1500 1840 8000 8000 8000 8000 8000 8000 80008000 80008000
6MM CLEAR GLASS
1500
VERTICAL BRACING
DOUBLE HEIGHT DOUBLE &EE FLOOR DOUBLE DOUBLE HEIGHT HEIGHT MHEIGHT & EHEIGHT MFLOOR &MM E&FLOOR DOUBLE MFLOOR & E FLOOR
MAX X
WEST ELEVATION
GLASS: PILKINGTON PLANAR LAMINATED GLASS
8000
WI
8000
ALUMINUM TRANSOM
STEEL PLATE WITH BOLTS
400
600
AIR FLOW
BRACKET BOLTED WITH MOVEMENT JOINTS FILLED WITH GROUT
4000 4000 40004000
400
OPERABLE ALUMINUM LOUVERS FOR FRESH AIR INPUT
945
acade
DOUBLE GLAZED VISION PANEL
4000 4000 40004000
1500 1500 1500 1500 1500
4000
1500 1500 1500 1500 1500
ALUMINUM MULLION
4000
VISION
4000
OPERABLE ALUMINUM LOUVERS FOR HOT AIR EXPLUSION BLIND PELMET
400
INSULATION BIRD MESH
RAISED FLOOR SYSTEM AIR DISTRIBUTION UNDERFLOOR AIR UNDERFLOOR SYSTEM VENT RAISEDVENT FLOOR SYSTEM DISTRIBUTION SYSTEM DUCT WORK AIR DUCT WORK CONNECTED WITH FANS UNDERFLOOR UNDERFLOOR BAND BEAM RAISED FLOORAIR SYSTEM DISTRIBUTION SYSTEM VENT INSULATION DISTRIBUTION SYSTEM VENT UNDERFLOOR AIR DISTRIBUTION BAND BEAMS @ SYSTEM 2000SUSPENDED CTRSCEILING CABLES RAISED FLOOR INSULATION SYSTEM VENT UNDERFLOOR AIR DUCT WORK RAISED FLOORAIR SYSTEM UNDERFLOOR SUSPENDED CEILING SUSPENDED CEILING DISTRIBUTION SYSTEM VENTAIR VENTS DISTRIBUTION SYSTEM VENT INSULATION RAISED FLOOR SYSTEM DUCT WORK ARMSTRONG PEAKFORM BAND @ 2000 CTRS DUCT BEAMS WORK RAISED FLOOR SYSTEM PRELUDE 24 SYSTEM RAISED FLOOR INSULATION DUCT WORK CONNECTED WITH FANS SUSPENDED CEILING INSULATION SUSPENDED CEILING BAND BEAMS @ 2000 CTRS DUCT WORK BAND BEAMS @ 2000 CTRS BAND BEAM ARMSTRONG PEAKFORM AIR VENTS DUCT WORK SUSPENDED CEILING PRELUDE 24 CEILING INSULATION 600 SUSPENDED INSULATION ARMSTRONGCEILING PEAKFORM SUSPENDED BAND BEAMS @ 2000 CTRS ARMSTRONG PEAKFORM BAND BEAMS 2000 CTRS PT CONCRETE SLAB SUSPENDED CEILING CABLES PRELUDE 24 @ AIR VENTS24 CEILING PRELUDE SUSPENDED SUSPENDED CEILING CEILINGBAND BEAM INSULATION SUSPENDED EDGE BEAM SUSPENDED CEILING ARMSTRONG PEAKFORM AIR VENTS SUSPENDED CEILING ARMSTRONG PEAKFORM AIR PRELUDE 24 VENTS PRELUDE 24 SUSPENDED CEILING CEILING AIR VENTS SUSPENDED AIR VENTS AIR VENTS 1500 1500 4000
ALUMINUM LOUVERS FRESH AIR INPUT
400
SPANDREL
A 5.2.1
DOUBLE HEIGHT M & E FLOOR
1500 1500 1500 1500 1500
DISTRIBUTION SYSTEM VENT
FRAME MODULE
2 SPANDRAL ALUMINUM PANELS
1500
N
TYPICAL FLOOR TYPICAL FLOOR TYPICAL TYPICAL FLOOR FLOOR TYPICAL FLOOR
ANGLE AT 30° ALUMINUM SUNSHADING ALUMINUM LOUVERS FINS ALUMINUM SPANDREL FRESH INLET ALUMINUM FINS ANGLEAIR AT 30° PANELS BIRD MESH ANGLE AT 30° SUNSHADING ALUMINUM SPANDREL FRAME MODULE SUNSHADING ALUMINUM LOUVERS CAST IN INSERTS SPANDREL ALUMINUM FINS PANELS ALUMINUM FINS FRESH AIR INLET PANELS ALUMINUM SPANDRAL SMOKE CAP ANGLE AT 30° AT ANGLE 30° ALUMINUM LOUVERS BIRD MESH PANELS ALUMINUM LOUVERS ALUMINUM SPANDREL FRESH AIRSPANDREL INLET ALUMINUM ALUMINUM LOUVERS CAST INAIR INSERTS FRESH INLET PANELSLOUVERS BIRDAIR MESH ALUMINUM PANELS HOT EXPLUSION BIRD MESH SMOKE CAP FRESH AIR INPUT ALUMINUM LOUVERS CAST IN INSERTS BLIND PELMET ALUMINUM LOUVERS CAST IN INSERTS FRESH AIR INLET ALUMINUM LOUVERS SMOKE CAP FRESH AIR INLET BIRD MESH SMOKE CAP INSULATION BIRD MESH HOT AIR EXPLUSION 1500 1840 50 1500 ALUMINUM ALUMINUM MULLION LOUVERS CAST IN CAST INSERTS BLIND PELMET BIRD MESH IN INSERTS ALUMINUM LOUVERS HOT AIR EXPLUSION 140 SMOKE CAP HOT AIR EXPLUSION SMOKE CAP TRIPLE GLAZED OPERABLE ALUMINUM LOUVERS BLIND PELMET 50 BLIND PELMET VISION PANEL FORALUMINUM HOT AIR EXPLUSION LOUVERS ALUMINUM MULLION ALUMINUM LOUVERS HOT AIR HOT EXPLUSION BLIND PELMET 140 50 AIR EXPLUSION ALUMINUM MULLION 50 TRIPLE GLAZED BLIND PELMET BLIND PELMET ALUMINUM MULLION 140 VISION PANEL 140 TRIPLE GLAZED ALUMINUM MULLION 50 TRIPLE GLAZED 50 VISION PANEL ALUMINUM MULLION ALUMINUM MULLION VISION PANEL 2100 STACK JOINT 140 140 DOUBLE GLAZED TRIPLE GLAZED TRIPLE GLAZED TOP HAT BRACING VISION PANEL VISION PANEL VISION PANEL ALUMINUM LOUVERS STACK JOINT FRESH AIR INPUT TOP HAT BRACING STACK JOINT CONCRETE SLAB STACK JOINTPT STACK JOINT ALUMINUM LOUVERS TOP HAT BRACING BRACKET BOLTED OPERABLE ALUMINUM FRESH AIR INPUT WITH MOVEMENT TOP HAT BRACING 5 ALUMINUM LOUVERS JOINTS FILLED WITH GROUT LOUVERS STACKFOR JOINT ALUMINUM PT CONCRETE SLAB STACK JOINT FRESH AIR LOUVERS INPUT 600 FRESH AIR INPUT 2100 EDGE BEAM FRESH AIR INPUT TOP HATTOP BRACING 600 HAT BRACING BRACKET BOLTED WITH MOVEMENT PT CONCRETE SLAB ALUMINUM PT LOUVERS CONCRETE SLAB GROUT JOINTS FILLED WITH ALUMINUM LOUVERS LOUVERS AIR FLOW BRACKET BOLTED WITH MOVEMENT FRESH AIR INPUT FRESH AIRBOLTED INPUT WITH MOVEMENT EDGE BEAM BRACKET JOINTS FILLED WITH GROUT FIRE PROOFING COATING PT CONCRETE SLAB JOINTS FILLED SLAB WITH GROUT PT CONCRETE EDGE BEAMMOVEMENT BRACKET BOLTED WITH LOUVERS EDGE BEAM BRACKET BOLTED WITH MOVEMENT BRACKET BOLTED WITH MOVEMENT JOINTS FILLED WITH GROUT STEEL UB STRUCTURAL JOINTS FILLED WITH GROUT FIRE PROOFING COATING LOUVERS ARROWHEAD CORNER JOINTS FILLED WITH GROUT TRUSSES LOUVERS EDGEMULLION BEAM EDGE BEAM FIRE PROOFING COATING LOUVERSTRIPLE GLAZED GLASS FIRE PROOFING COATING STEEL UB STRUCTURAL LOUVERS LOUVERS STEEL EMBEDDED COLUMN TRUSSES STEEL UB STRUCTURAL FIRE PROOFING COATING STEEL UB STRUCTURAL FIRE PROOFING COATING TRUSSES TRUSSES STEELINSULATION UB STRUCTURAL STEEL UB STRUCTURAL TRUSSES SUNSHADING TRUSSES ALUMINUM FINS ANGLE AT 30° ALUMINUM TRANSOM FIRE PROOFING COATING
N
UNDERFLOOR AIR FRAME MODULE
TYPICAL FLOOR
1500
RAISED FLOOR SYSTEM:
SC ULTRA FIXED SYSTEM BAND BEAMS 2000 CTRS BAND@ BEAMS @ 2000 CTRS N
REBATE FILLED WITH GROUT SCREW FOR SMOKE CAP
TYPICAL FLOOR
1500
N
600x300 CEMENT BOARD
300
1500
600
WEST ELEVATION
300 300 300
300
600 600 600
300
1500 1500 15001500
1500
600
600
TYPICAL FLOOR
1500
UNDERFLOOR AIR1500 1500 1500 DISTRIBUTION SYSTEM VENT
E52627
1500
FRAME MODULE
5
Plan: Western & WEST Northern Facade ELEVATION CORNER PANEL A2 FRAME MODULE SUNSHADING CORNER PANEL
1500
1500
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BLIND PELMET POWDER COAT RAL7024 ALUMINUM MULLION 2 A 5.2.1
APPLIED CONSTRUCTION ABPL 90118 ASSIGNMENT 5.2 SEM 1 / 2016 TUTORIAL 1 Dr. MARK LAM PLAN & SECTION DETAILING
JEN YOUNG TAN TAN YEE ANN CATHERINE MEI MIN WOO
Section detail1 : TYPICAL stack joint 1:10 at A2 DRAWING
GROUP 1
A 5.2.1
Figure 78: Scaled down 1:10 technical drawing of plan and section
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SILL COVER
STACK JOINT PRESSURE EQUALISER CHAMBER
SPONGE BLOCK RAIN SCREEN
TOP HAT BRACING INSULATION
PLASTER BOARD FINISHING POWDER COAT RAL 7024 APOLIC FOLDED ALUMINUM SHEET SPANDREL PANELS
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section Detail 2: TYPICAL M&e fLOOR stackjoint 1:10 at A2
Figure 78: Scaled down 1:10 technical drawing of plan and section
The UFDS not only provides fresh air to the occupants of the tower, but allows tenants to save on operational cost with an efficient system in place. The details shown in Figure 76 , 77 & 78 illustrate the middle section of the tower. It shows both a typical curtain wall module and the corner details. The tower has a clean aesthetic that employs bands of louvers and curtain wall panels to create a ASSIGNMENT 5.2 PLAN & SECTION DETAILING stratified facade (Figure 79 & 80).
APPLIED CONSTRUCTION ABPL 90118 SEM 1 / 2016 TUTORIAL 1 Dr. MARK LAM
JEN YOUNG TAN TAN YEE ANN CATHERINE MEI MIN WOO
DRAWING GROUP 1
Figure 79 : Tower set on site with a stratified facade
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A 5.2.2
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APPLIED CONSTRUCTION ABPL 90118 ENVELOPE : SEM 1 / 2016 TUTORIAL 1 Dr. MARK LAM PLAN & SECTION
MODEL OF MID ZONE TOWER WITH FACADES DRAWING
JEN YOUNG TAN TAN YEE ANN CATHERINE MEI MIN WOO
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APPLIED CONSTRUCTION ABPL 90118 STRUCTURE : SEM 1 / 2016 TUTORIAL 1 Dr. MARK LAM MODEL & 3D
DRAWING Figure 80 : Model parts of stacked tower.
JEN YOUNG TAN TAN YEE ANN CATHERINE MEI MIN WOO
GROUP 1
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DESIGN PROJECTS INFILTRATION
Figure 81: Infiltration tower juxtaposed in Shibuya Figure 82: Rendering of Infiltration tower in the background of the iconic Shibuya crossing
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' Infiltration is a project that studies the flows of human behavior. The architecture seeks to reflect the organised chaos that is in the Shibuya crossing'
I
nfiltration is a project that is meant to replace the iconic Shibuya 109 tower. It is situated at the famous Shibuya crossing and viewed westwardly from Dogenzaka slope. The design of this tower (Figure 81 & 82) seeks to act as a physical reflection of the chaotic pedestrian flow that has attracted tourist and avid photographers who attempt to experience and capture the phenomenon. This project's design is inspired by the flock theory that studies the movement of animals and the way they organise themselves. Similarly this project seeks to identify ways in which people move. Research and iterative studies derive an algorithm which generate forms that could respond to human traffic.
Ironically, the construction of a physical building would limit the circulation path. The permutation of internal human traffic would still be limitless. (Figure 83) The algorithm is created for the iterative study of each design iteration. 'Species' were set loose and directed within the design boundaries with varying intensities of attraction. This is based on the program's usage frequency within the design bounding box. (Figure 85) The design process was inspired by Kadinsky and employs the extrapolation technique in the algorithm. Figure 84 showcases the generated iteration of the flows diagrams in response to the study of human
65
process Yee Ann (Ean),TanDesign , 573608, Year C
Studio 6 , Laura Martines
Master of Arch
Design Process
Spheres
SPHERES: Repulsion point REPULSION POINTS
LINES: Lines PATHS TAKEN SPECIES Paths taken BY by the species
Spheres SPHERES: Attraction nodes of varying POINTS intensity based on ATTRACTION the product
iter
iteration 20 Relationship lines: LINES:: RELATIONSHIP between species over time LINESLinesBETWEEN SPECIES' PATHS OVER TIME
iteration 1
iteration 2
3D form: 3D FORM:: EXTRAPOLATION ExtrapolationOF of linesTHE to generate 3 Dimensional space FORM
iteration 3
iteration 7 iteration 8 iteration 9\ IterationFigure Generated 83: Design process that would be interpolated into an Grasshopper algorithm for an iteration 20
iterative study of computer simulated flow of pedestrians.
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iteration 1216 iteration
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iteration 13. 3
iteration 1 8. 18. is contrasted with flow.3.The extruded forms that were (Figure 87). This 4a iteration 5 shift downprograms(Figure 88) generated in iteration Figure4 4iteration wasiteration analysed rectilinear 7 iteration 8 iteration 9\ iteration 13 iteration 14 iteration 15 iteration 16 iteration 17v3 variable pipe iteration 2 iteration 3 iteration 17v2 iteration 2 iteration 3 iteration 1 4. 14. 9 iteration 16 iteration and later selected for the devised . The infiltration of9\the iteration 10 iteration iteration 12 19. iteration 17v2organic 17v3 variable pipe iteration 7 iteration118 iteration circulation forms. forms is a physical metaphor that iteration 4 iteration 4a iteration 5 shift down iteration 4iterationiteration 4a 5 shift iteration down 14 iteration 13 15 iteration 7 8 iteration 9\ iteration iteration 20 iteration iteration 19 iteration 17 5. 10 10 iteration iteration 11 15. reflects iteration 12the chaotic 20. yet organised iteration 15 trinag uv 4 iteration 15 trinag uv 7 iteration 4a iteration 5 shift down The circulation of iteration movements at15the Shibuya crossing. iteration 13 down 14 iteration 4 iteration 4a iteration 5 shift iteration 10 iteration iteration 11iterationiteration 12iteration 20 iteration 19 iteration 17 16 (Figure 86) is defined by a iteration 16 iteration 10 iteration 11 iteration 12 iteration 17v3 variable pipe iteration 17v2 iteration 15 trinag uv 4 iteration 15 trinag uv 7 sinuous form. It was then further simplified and extrapolated to iteration iteration 17v3 variable pipe iteration 15 trinag uv 4 iteration 15 trinag uv 716 iteration 17v2 form functional circulation spaces
iteration 16
Species circulating in a bounded box 66
iteration 17
iteration 17 iteration iteration 8 iteration iteration 9\ iteration iteration 10 3 7iteration 11iteration 12 20 iteration 19 iteration 17
iteration 2
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Extruding space
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Iteration Selection Process
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13. 18. iteration 2 iteration 3 13. iteration 20 iteration 19 18. iteration 17 iteration iteration 8 iteration iteration 9\ iteration iteration 10 3 7iteration 11iteration 12 20 iteration 19 iteration 17
iteration4a 2 8. iteration
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iteration 13 iteration 14 iteration 15 iteration 16 iteration 17v3 variable pipe iteration 14. 19. 17v2 iteration 2 9. iteration 3 iteration 16 iteration 4 iteration iteration 4a iteration 5 shift down iteration 17v3 variable pipe iteration iteration 12 17v2 iteration iteration 7 iteration10 8 iteration11 9\ iteration 7 iteration 8 iteration iteration 9\ 13 iteration 14 iteration 15 iteration 16 iteration 17v3 variable pipe iteration 3 iteration 17v2 iteration 2 iteration 3 iteration iteration 17v3 variable pipe iteration 5 10shift down iteration 11 16 iteration 12 17v2 iteration iteration 4a iteration
iteration 3
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iteration 7 iteration 8 down iteration 9\ iteration 4iterationiteration 4a 5 shift iteration 13 iteration 14 20 iteration 15 iteration 7 8 iteration 9\ iteration iteration iteration 19
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iteration 4iterationiteration 4a 5 shift iteration down 14 iteration 15 uv 4 iteration 15 trinag uv 7 iteration 13 15trinag iteration 7 8 iteration 9\ iteration iteration 20 iteration iteration 19 iteration 17 15. 10down iteration 5iteration shift 10 iteration 11 iteration 12 20.
iteration 4a
iteration 13 down 14 15 iteration 5 shift iteration 15 trinag 7 iteration 10 iteration iteration 11iterationiteration 12iteration 20 uv 4 iteration iteration15 19trinag uv iteration 17
Figure 84: Iterative study of different permutations of attraction and repulsion nodes.
iteration 4a
iteration 5 shift down
iteration 13 12down 14 15 16 iteration iteration 4 iteration iteration 4aiteration 11iteration 5 shift 10 iteration iteration 17v3 variable iteration 10 iteration iteration 11iteration iteration 12iteration 20 17v2 iteration 19 iteration iteration 17 pipe
iteration 15 trinag uv 4 iteration 15 trinag uv 7
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Species circulating in a bounded box Species circulating in a bounded box
Figure 86: Extruding spaces based on circulation intensity
Organic x circulation
Recti linear x programs
Organic x circulation
Figure 88: Rectilinear / Programs
Figure 85: Species circulating in a bounded box
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iteration iteration 15 trinag uv 4 iteration 15 trinag uv 716
Figure 87: Organic / Circulation
Extruding space Extruding space
Recti linear x programs
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Figure 89: Rendering of ground floor entrance Figure 90: Rendering of the restaurant space Figure 91: Rendering of the karaoke rooms
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Lift core
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Figure 92: Section cut of Infiltration tower
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Entrance 1 Tube circulation 3
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GF: Information & Karaoke reception GF Administration
2f B1: 24 Small karaoke rooms
b1 Karaoke 24 Small Rooms
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Figure 93 : Exploded axonometric drawing of Infiltration tower showcasing the programs Tube circulation 3
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Entrance 7 Pedestrian Bridge
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DESIGN PROJECTS E
ENCLOS
Figure 94: Enclose structure assembled on festival site with a Manitou Figure 95: Render of how the enclose structure would be in a festival
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' EnclosE is a project that seeks to optimise the packaging of festival structures.'
E
nclosE (Figure 94) is an architectural product that employs a simple concept a box module that is not only able to hold festival components, but also able to provide ease to: 1. Construction/Fabrication 2. Assembly 3. Packing and storage
These boxes have the potential to be arranged in different forms for different festivals. (Figure 95).
This product is designed for Mojo, an events company that organises multiple festivals annually in the Netherlands.
1. CSE Edu pack: Evaluate and identify the shear stesses, cost and physical and chemical properties of potential materials for the design. (Figure 109)
The box is constructed to fit the dimensions of the longest length of the steel structure (1m). These boxes are designed to withstand shear and loading stresses in different stages while considering transportation, assembly and usage (Figure 110) . The dimensions of the product is seen in figure 101105.
In this design studio (Buckylab) conducted in TU delft . There was an emphasis on structural and material analysis, as well as detailing and prototyping the product. The use of programs such as
2. Diana fx + : Structural analysis of the product design. (Figure 107 &108) 3. Grasshopper: Arrangement iterations. EnclosE is a box made with an aluminum frame with notches that
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Figure 96: 1:1 Prototype detail Figure 97: 1:1 Prototype detail Figure 98: 1:50 Prototype model
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holds polycarbonate infill. This project required us to perform rigorous testing of our product through 3d modeling, prototyping, structural and material evaluation. Figures 96 & 97, showcase 1:1 detail of how the boxes interlock with each another. This product borrows a shipping containers' twist lock system and forklift slot detail, to incorporate into the Enclose box. (Figure 100) A 1:50 prototype was also created to showcase the possible
arrangement potential, providing a physical representation of how the boxes connect with each other. (Figure 98) The box considers the use of Polycarbonate for it's transparency and longevity. It allows for possible LED lighting potential. (Figure 99) EnclosE boxes are made up of aluminum profiles, aluminum die casted nodes, and polycarbonate infill. (Figure 101-105) The choice of materials allows for boxes to withstand loading and be used for more than 10 years.
Figure 99: Render showing the possible LED light Figure 100: 1:50 prototype model showcasing how the Manitou would lift the boxes.
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Figure 103 (Right): 1:10 Detail of the Alunminum extruson profile
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AA
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The above diagram exhibits the plans and sections of the final product of the project.( Figure 104) Figure 105 shows the detail of the aluminum nodes. The nodes are slotted into the aluminum profile,
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and screwed in, to secure them. The box has few unique pieces allowing for mass production, thus reducing the cost of each box. The design would require 3 aluminum profiles and 4 nodes to construct.
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Figure 106: The endless iteration of structures that can be designed with the boxes.
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Figure 107: Diagram to showcase the bending stress when an iteration is assembled that would be structually analysed before the commencement of the event Figure 108: Diagram showcasing the loading stress during the transporation phase of the box
Figure 109: Material and physical property analysis with CES.
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Figure 109: Different stages of the box
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Mock up test
Repeat from 2
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PERSONAL INTEREST PHOTOGRAPHY + TRAVELING
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“Taking an image, freezing a moment, reveals how rich reality truly is.�- Anon
P
hototaking and not photography. I am not a
professional photographer nor do I claim to know photography. I do, however, enjoy capturing moments in my life. This immortalises my experiences. Capturing scenes and curating them is something that I perceive as a hobby and pursue in my free time. I enjoy a simple and clean aesthetic, with a dash of desaturation to convey a moodier visual experience. I feel that this gives depth to the photo, evoking halcyon emotions, while also embody melancholic contrasts.
to my parents for cultivating the individual that I am today. This hobby of mine allows me to explore the perspective of a person without any architecture biasness. This exercise has helped me shaped and formulate the spaces I design and challenge the quality of space I create. There is still much I have yet to learn.
I consider myself blessed to have had the opportunity to travel and experience different cultures all over the world. It has been a privilege to be able to visit reknown architecture masterpieces through my travels. Above all, I am grateful
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Figure 110: London
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Figure 111: London
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Figure 112: Munich Figure 113:Copenhage round tower
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Figure 112: Singapore Figure 113:Copenhagen
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Figure 114 (Top) : Seattle, USA Figure 115 (Left) : BMW museum, Munich Germany Figure 116 (Right) : Copenhagen, Denmark
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Figure 117 (Top) : Seattle, USA Figure 118 (Bottom) : Seattle, USA Figure 119 (Right) : Allianz Arena, Munich Germany
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Figure 120: A block of photos on instagram @arch.ean
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Figure 121 : Second block of photos on instagram @arch.ean
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PERSONAL INTEREST ART: MIX MEDIA MODEL MAKING
Week 3:
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5. Juxtaposition 6. Mix Media This composition is similar in technique to that of the previous composition. This pieces emphasizes the highlights and the shadows of this androgynous man’s face. The emphasis of the light and darkness of the person is to juxtapose the message of how every person is capable of great evil and great good. It also conveys a message that everybody is always a state of conflict between good and evil. Although the message seems cliche but the message holds true.
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Figure 122(Top left) : Mix media collaging Figure 123 (Top right) : Collaging Figure 124 (Bottom left) : Etching and printing Figure 125 (Bottom right) : Pencil sketch (when I was 17years old)
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Upon review by and Gina I have to crop the pho accentuate the the art work an certain details t dynamism and the compositio sea monster is s behind the iceb
Figure 126 (Top) : Mix media collage Figure 127 (Left) : Life drawing
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(Figure 15-26) Showcases the Plans that I have worked out for Cube Motel. (Figure 27&28) shows my 1:200 scale model of the Motel and the plans that can be removed to explain the spatial distribution.
Figure 27 & 28 : 1:200 scale model of the Cube Motel Figure 15-26 : Plans of the Cube Motel
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Figure 126: 3D printed faded of a design project
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Figure 127: Floor plans of model Figure 128: Model photo Figure 129: 3D printed design project
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Figure 130: Construction model showing different building elements.
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