Yee Ann (Ean), Tan 's Portfolio

Ean's Portfolio

E.A.N ELoquent Accurate Ardor Novel

My Logo highlights my Goals as a Designer . I seek to become a passionate and eloquent designer That creates novel designs that are appropriately resolved for construction.

2

Contents

http://issuu.com/yeeann

Profile

Pg 5

Curriculum Vitae

Pg 6-7

Studio Air

pg 8-11

Carbon Neutral Star-Gazing Platform: The Infinity Platform, 2014

Studio Earth Studio Water

Monument at Herring Island: Changing Perspectives, 2014

Boathouse at Studley Park : Reflections, 2013

Virtual Environments Construction Design Site Tectonics

Lantern: Natural Interference, 2013

McBride Charles Ryan Architects Pentleigh & Essendon Grammar School, 2014

Relocation of the Farnsworth House at Maribrynong River: Caldera, 2014

Other School Projects

Hobby Since 4 years old

Hobbies: Photography and Traveling Screen Design

Pg 14-15

Pg 16-17

Pg 18-19

Pg 20-21

Pg 22-23

Collages and Illustration

Hobbies: Sketching and Painting

Pg 12-13

http://instagram.com/tanyeeann

Screen Design druing my internship at Capstone Alumnium

Pg 24-25

Pg 26-27

Pg 28-29

3

4

Yee Ann (Ean), Tan http://issuu.com/yeeann

About Me My interest in architecture developed from

I was given the opportunity to learn and

my initial love for drawing and painting. In

hone my digital rendering skills (eg. Learning

addition, I have always had a passion for

Software such as Rhino, Illustrator, Indesign

the Sciences and curiosity about how things

Vray plugin and Photoshop), allowing me

worked. Therefore, it was natural that I was

to pursue my dreams. The course fanned my

drawn to architecture which satisfies both

interest for the arts and design, deepening my

my passion for aesthetics and my scientific

understanding of architecture.

nature. I hope to keep learning and developing my Initially I was unable to design using the

skills in digital presentation to become a

computer and most of my designs were hand

competent architect.

My goal is to design spaces that are functional

drawn. However, through my course of study in

with well resolved details to ensure the users’

the University of Melbourne,

comfort over the lifetime of the construction.

Sketching Hand Models

I personally believe that Form should never

Laser Cutting

compromise Function.

Card Cutter

Proficiencies 3D Printing Microsoft MicrosoftOffice Office

Sketching Sketching

InDesign InDesign

Hand HandModels Models

Photoshop Photoshop

Laser LaserCutting Cutting

Illustrator Illustrator

Card Card Cutter Cutter

Rhinoceros5.0 5.0 Rhinoceros

3D 3DPrinting Printing

Autocad Autocad Grasshopper Grasshopper

Microsoft Office

3D Max Max 3D

InDesign

Revit

Photoshop

Google Sketchup More about Me:

Illustrator Rhinoceros 5.0

Autocad Facebook: https://www.facebook.com/tanyeeann/media_set?set=a.125842878401.105944.635078401&type=3

Issuu: http://issuu.com/yeeann

Grasshopper

Instagram: https://instagram.com/tanyeeann/

3D Max

Vsco: http://tanyeeann.vsco.co/journal/p/1

Revit Google Sketchup

5

Curriculum Vitae http://issuu.com/yeeann

Education

Work Experience

2012-2015

2009-10 (Nov- Feb)

Bachelor of Environments (Major:

Capstone Aluminum ,Malaysia

Capstone Aluminum ,Malaysia

Architecture) , University of Melbourne

Quality Control Assistant:

Mr Tan Hua Tian : 017-7968586

I assisted in the quality control and

Riady: 010-7103173

Jan-Feb 2014

conducted various quality control checks

Winter Exchange Program, Stuttgart

on the aluminum extrusion. In addition, I also

University

dabbled in Stock taking and the Checking

During the exchange I learnt about

of Quantity for Production. During my time

20th Century Architecture and had the

there I oversaw the construction process

opportunity to visit some of them. In addition,

of Curtain wall project for Singapore’s Park

I am blessed to have had the opportunity

Hotel and Australia’s Macquaire Library and

to travel around Europe and experience

Medical Center

Referee

different cultures in breadth. Furthermore, I manged to learn basic German, so that I am

2012 (Jan-May)

able speak and understand German at a

D’Collage Art School ,Singapore

D’Collage Art School ,Singapore

rudimentary level.

Art Teacher:

Mrs Suzanne : +65 96352468

I taught art to Primary School Children. 2010-2012

Through the experience I learnt how to deal

Singapore Armed Forces

with children as well as had the chance to

During my service term I was given the

explore some new painting/drawing mediums

opportunity to hold a leadership position, as

that I did not frequently use.

a Sergeant. From the experience I learnt how to lead men for missions and duties.

2012-2013 (Nov-Jan) Minesco ,Melbourne

Minesco ,Melbourne

2008-2009

Quantity Surveyor Assistant:

Eunice : +61 458972859

Catholic Junior College

I was assigned the role of stock taking and

Jessica: +61 433656720

While studying for my A Levels, I took part

inspection of glazing panels for the compa-

in various co-curriculum activities such as

ny’s projects. Through the inspection process

Canoeing, Overseas Community Involvement

(of ensuring precision of panel dimensions)

Projects and developed my personal

, I was exposed to architecture, shop and

hobby of sketching and painting. I was also

fabrication drawings. During the internship I

awarded the National Youth Achievement

facilitated in various projects namely, Upper

Award (Gold) by the President of Singapore

West side Podium and the Prima Pearl Tower,

in 2009.

in Melbourne.

2003-2007

2014 (June)

Anglo Chinese School (Barker Road)

Janho ,Brisbane

Janho ,Brisbane

Intern facilitating an Engineer Designing

Allan: +61 426200210

structural details:

nx2005ky@163.com

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.

6

Referee 2014 (December Sales) Doro Retail ,Singapore

Doro

Promoter:

Meryl: +65 96602981

I Learned more about Men’s high fashion. Working at Tangs Orchard gave me the opportunity to speak to people of different walks of life. It also taught me how to best present my product to customers. This skill is something that could be applied to presenting my design to clients, Hence I am very glad that I have got the chance to work there. 2014-5 (Dec-Feb) Capstone Aluminum ,Singapore &

Capstone Aluminum Singapore

Malaysia

Mr Tan Hua Joo : +65 96750752

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 Precasting Company (Coninco). During my time there I have had the opportunity to design a privacy screen for a client of Capstone Aluminum.

7

Infinity Platform

Studio Air A P B L 3 0 0 4 8 / 2 0 15

@ Sonder Hoved Pier

Towers

Sanctum

TREE detail

,QÀ QLW\ 3ODWIRUP

n Figure 1: Infinity Platform

7KH ,QÀ QLW\ 3ODWIRUP

302.

47

79

Figure 4: Infinity Platform Perspective Section revaling the Conceptual possiblities of the space Se

cti

Figure 81: Perspective cut of Section AA Mega Tree and the lift that is within the Mega Tree

on

AA

30.05

179.71

Figure 2: Infinity Platform Plan

This diagram shows the Proposed spatial breakdown of the Mega Tree. The circulation of the structure does not follow the pod’s surface but through the internal platforms. The intersection of the pods and the platform at different angles creates unique passageway to the Pods which frames the constellations.

n

104.6

10

1

3

10.38

Carbon Neutral Star Gazing Platform: The Infinity Platform To access the Mega Tree Users can access from

1. The Ground Floor through the central axis to the doors that open The Platform is Situated at Sonder up to theInfinity lift.

N

63.90

Refshaleøen.

18

Figure 82: Plan annotating the circulation access

50.00

2. The ramp to the access corridor and to the lift.

Hoved Pier at Copenhagen Harbor, SCALE 0

50

100

This Star Gazing Mega structure seeks to :

100

METERS

Figure 3: Infinity Platform Section

0

100

200

400

FEET

1. Generate Clean Solar Energy 2. Become Copenhagen’s New Iconic Public Space. 3. Attract Visitors to faciliate both the Old (flea market) and New (Tourist attraction)

8

programs of the site.

C-21

Figure 5: Solar Anaysis of the model to identify the ideal panels to mount the solar panels on.

Figure 6: Shows the orientation points in which the pods are directed to. These oriented views could be utilised to frame constalations

Design Concept: My design concept is “To Humble Users in face of the Vast Space & Cosmos invoking a

Figure 55: Mapping out where the pods would orient towards.

sense of profoundness.�

“The most important scientific revolutions all include, as their only common feature, the dethronement of human arrogance from one pedestal after another of previous convictions about our centrality in the Algorithmic Process cosmos.� Stephen Jay Gould

w out of the Ursa Major Constellation

Iterations Generated for the Branching of the Pod units Figure 7: The spatial experience that users would have in the pods

Process Figure 58:Algorithmic Section cut of a constellation viewing pod

James Turrell’s spatial designs, where he

James Turrell Inspired Pod Orientation Concept

framed views was a precedent that I drew

The opening of the Decahedron would be orient towards constellations. Drawing inspiration from James Turrell’s architecture designs, which frames parts of the sky.8

inspiration from (Figure 9).

The Infinity Platform Project is based on the 2014 LAGI Competition Brief. To fullfil the brief

"T NFOUJPOFE CSJFn Z QSFWJPVTMZ TQFDJm FE QPET XPVME GBDFT UIF constellations while others would be oriented as windows or as openings to views.

Figure 55: Mapping out where the pods would orient towards.

requirements and to fullfil my design intent. Utilising Grasshopper I generated design

Figure 8 (above): Design iterations for the Mega treee structure Figure 9 (Left) : James Turrell’s Dividing Light Installation

Figure 43-54 : Mega tree pod branching iterations

iterations and selected the design that responded to the solar conditions to gener-

The images above showcases the Iterations of

ate solar energy, to fulfill the brief.

structure. The chosen orientation and design

the different branching designs of the Mega Tree JT JOnVFODFE CZ UIF PSJFOUBUJPO PG UIF PQFOJOH The opening would direct the users to either constalations, views of the city or parts of the Figure 56: James Turrell’s Dividing the Light structure. installation 8

Figure 57: View out of the Ursa Major Constellation pod

9

Figure 58: Section cut of a constellation viewing pod

Infinity Platform

Studio Air A P B L 3 0 0 4 8 / 2 0 15

@ Sonder Hoved Pier

Sanctum Towers

Construction Detail I generated several construction detail proposals for the Star gazing Pods. Details 1-3 have a different jointing system and asthetic quality. I tested these designs by prototyping them with a 3D print model to understand the joint systems. Ideally, I would have had the parts fabricated in a factory

Prototype Design 1

Prototype Design 1

and tested to ensure the compliance with

the structural requirments. The decision Detail to use

1Detail 1

cirular hollow sections and circular joint pipes is because they are readily available in the market. Figure 11: 3D print of the Chosen construction joint (Detail 1)

With the 3D printed details I was able to identify issues that the joints had and resolve them.

Figure 111: Detail 1 Circular Joint pipes11

Figure 111: Detail 1 Circular Joint pipes11

Detail 1 Components

2 gn Prot esiotype Design 2 D pe toty Detail 2 Pro 2 tail De Figure 109: Detail 1

Detail 1 Components

Prototype Design 3 Prototype Design 3 Detail 3Prototype Design 3 Detail 3 ents

pon

om

2C

es ns r t pip ctio t fo join ow se a slo lar h ll ircu r ho s wit 1. C ircula ring . C riable 2 Figure 110: Detail 1 components a . l 3. V pane anels the etal p Figure 110: Detail 1 components 4. M tail

De

1. Circular joint pipes 2. Circular hollow1.sections Circular joint pipes 3. Metal panels. 2. Circular hollow sections

3. Metal panels.

Detail 3

Prototype Design 3 Figure 12: Diagram of the Chosen construction joint (Detail 1) Detail 3

Figure 109: Detail 1

Fig

e ur

Fig

ure

11

2:

De

11

2:

De

ta

il 2

ta

il 2

Detail 2 Components 1. Circular joint pipes 2. Circular hollow sections 3. Variable rings with a slot for the panel 4. Metal panels.

C-

33

Figure 116: Bolt on metal plate Fig

Fig

ure

11

3:

e ur

De

ta

il 2

11

co

Detail 3 Components

il 2

eta

:D

113

1. Angled joints 2. Steel plates where Bolts will be attached to. 3. Metal panels.

ents

co

on mp

m

De

C-

33

ta

po

il 2

ne

co

nts

m

po

ne

nts

Figure 114: Detail 3

Figure 115: Detail 3

Figure 114: Detail 3

C-32

Figure 112: Detail 2

ure

Fig

tail

11

e 2: D

Figure 115: Detail 3

s

Figure 113: Detail 2 component

2

Figure 114: Detail 3

Figure 115: Detail 3

Figure 114: Detail 3

2 n ign 2 esig e Des yp D ot e ot yp 2 Pr ot il ot ta 2 Pr Detail De

3:

ure

C-32

Figure 116: Bolt on metal plate 12

Detail 3 Components

Fig

12

Figure 116: Bolt on metal plate 12 Figure 116: Bolt on metal plate 12

Figure 115: Detail 3

3

C-3

p s io m ent ipe ect slo a r Co n t p s 2 po join esow iownitsh t fo il m ll t ta Co lar t phipo segcs a slo Deil 2 cujoinlar owrin ith ta Cir rircuhollblegs w ls. De r riarin el 1.culaCla ne Cir 2.cu Vale an pa. 1. Cir 3r.iab pl talels 2. Va thaene Mpean 3. e p 4t.al th Me 4. on

s

en

ts

ns t fo

r

C-34

10

C-33

Figure 13&14: 3D print & diagram of the Detail 2 construction joint

Figure 15 &16 : 3D print & diagram of Detail 3 C-34 construction joint

joints Detail1.3Angled Components

2. Steel plates where Bolts

be attached to. Detail will 3 Components 1. Angled joints 3. Metal panels. Steel plates 1.2.Angled joints where Bolts will be attached to. Bolts 2. Steel plates where 3. Metal panels. will be attached to.

3. Metal panels.

Figure 17: 3D print of the Model on site

Figure 18: Card model of the Mega tree structure to provide a greater resolution to the strucural form of the design.

Figure 19: Entrance to the Infinity Platform at Sonder Hoved Pier.

11

Interference Interference

Interference Interference ChanGing Studio Earth PersP ectives A P B L 2 0 0 2 7 / 2 014

Chan Ging Pers Pectives @ herring island

Pilgrimage

Infinity Platform

Towers

Sanctum Ground Floor Plan

Scale 1:100

Scale 1:10

1

2

Figure 20: ‘Changing Perspectives’ Rendered on the Site. 3 7 4

Changing Perspectives

1

2

3 7 4

Section 2

Section 1

“ There are things known and there are things unknown, and in between are doors of perception.” Aldous Huxley In this assignment I was tasked to design a

6

6 6

3

Section 2 2 1

place of secrets. exploration ofModel 1:100 Basement levelThrough -not tothe scale both the site and the defintion of secrets, I decided to situate my designed space in the most exclusive spot of Herring Island.

Figure 21: Changing Perspective Plan

The Space at the where the Plan time capsule is located Figure 22:basement Changinglevel Perspective

locks the view fae Screen creates g directions.

6

5

5

12

Section 2

Scale 1:100

Sec

100

Scale 1:100

Figure 23: Perspective view of the 1:100 Design Model

Figure 26: Interior space of the Model and how it interacts with sunlight.

Figure 24: Plan of the Design Model with an exposed roof

Figure 25: Interior view of the Design Model

My design communes with the site’s

My Design Model (Figure 23-25) showcases

topography and seeks to evoke an

both the exterior and interior components.

understanding of the revealing nature of a

(Figure 26-27) shows the choice of materials

‘secret’ .

and the visual outlook of the design.

Figure 27: Digital render of the interior space

13

rreflections rr r

Studio Water A P B L 2 0 0 2 8 / 2 014

@ Studley Park

Interference Interference ChanGing PersP ectives Infinity Platform

Yarra Bend River

Jetty

Section B

ary

Prim

ance Entr

Section A

ry ce

n tra En

‘ Reflections’ is situated along the picturesque Yarra Bend River. The site is surrounded by a 360 degrees of lush greenery. To the north it overlooks the meander of the river. To the south is Studely Park Road that overlooks the site on a cliff. To the East lies the Yarra Bend River Park where which attracts picnicking and jogging. To the West, is the continuation of the cliff that oversee south of the site.

From Studley Park Road

Design Agenda: To design a boat house that allows various users to Reflect, relax and rest.

Figure 28: ‘Reflections’ Rendered into the site, Studley Park

Design Concept: Reflections - The physical reflection of the constructed elements - The mental reflective state of mind induced through the spatial experience.

Reflections

Section B

7

4

Sanctum Design Concept map

Section B

“To create architecture is to put in order. Put what in order? Function and objects.” Le Corbusier 7

6

27

7 3

8

8

5

8

2

9

9

Towers

da

n co

Se

3D Perspective of ‘Reflections’ Car Park Space

20

21

19

9 14

22

In this Module, students were tasked analyse

11

16

10 Section A 12

11

13

1. Boat-storage 2. Kiosk 3. Kiosk staff entrance 4. Entrance to Restaurant 5. Ramp to Restaurant 6. Kitchen 7. Refrigerator/ Cold storage 8. Dump waiter 9. Dry Storage 10. Kitchen Staff Locker space/ Kitchen entrance 11. Male Toilet 12. Female Toilet 13. Ramp to 1F 14. ‘Courtyard’ open space

10

a Master Achitect’s styles and adapt their 17

designing principles to recreate an orignial 11

13

design. ‘Reflections’ is inspired by the Master

Rationalist and designs space that are functional. ‘Reflections’ is Situated along the Yarra River at Studley Park. The form of the structure is both an literal and methaporical reflection of

ramp.

the River Bend. Figure 30: Section AA of ‘Reflections’

In this Design, I employed Le Corbusier’s 5 Points of architecture and his philosphy of

14

Rationalism.

25

24

18

Section A

Architect, Le Corbusier. Le Corbusier is a Figure 29: Plan of ‘Reflections’

8 23

10

1

26

5

15

15. Balcony 16. Office 17. Toilet 18. Ramp to Rooftop Garden 19. Cafe 20. Cafe Counter. 21. Cafe Storage 22. Restaurant 23. Waiting area 24. Vestibule to the toilet 25. Toilet 26. Bar 27. Spiral stairs to loft of the Restaurant

31

2 passage ways.

32

Entering the building and out into an enclosed ramp towards the Restaurant. 33

34

35

36

37

he kiosk and boat storage.

The view when emerging out of the vestibule towards the ramp and toilets. Entering the building and out into an enclosed ramp towards the Restaurant.

The loft: A Private space within the Restaurant.

Restaurant. The curvature and the sky-lighting facilitates the movement to the seats

Figure 31-33: Model of ‘Reflections’ showing (31-32) the structure/form and (33) the boat shed. Figure 34-37 : Digital renders of the (34)vestibule, (35)outdoor space at the back ,(36)the Restaurant and (37)the loft in the Restaurant.

Kitchen: Linear layout of the kitchen equipment.

Restaurant. The curvature and the sky-lighting facilitates the movement to the seats

The loft: A Private space within the Restaurant.

15 The view when emerging out of the vestibule towards the ramp and toilets.

Learning points pointsfrom fromprototypes prototypes ointsLearning from prototypes

Virtural Environments

rreflections rr r Interference Interference

Prototype 1 (2 Skin Concept) Prototype 2 (2 Skin Concept) Prototype 1 (2 Skin Concept) Prototype 2 (2 Skin Concept) Prototype 3 (Fusio Concept) Prototype 2 (2 Skin Concept) A P B L 1 0 0 0 8 / 2 0 13 Paper Lantern

ChanGing PersP ectives Infinity Platform

1. To decrease the offset as the structure was 3. Success in the 3D panel by 5. creating the dash varie The use 1.the To decrease the offset as the structureinwas 3. by Success in the 3D panel by creating theofvaried offset as structure was 3. Success the 3D panel creating the varied over exposed offset with point attractor creating the core an construction over exposed offset with the point attractor creating the core proc and offset with point attractor creating core and the periphery effect in both lantern and the unique and periphery in both the lantern and thedesira periphery effect in both the lanterneffect and the 2. To invert tabs and increase the length of tabs shadows casted. This is based on the Complex increase length tabs casted. on the Complex 2. Tothe invert tabsofand increaseshadows the length of tabsThis is based shadows casted. This is based on the Complex 1. Accentuatin in order to attach the inner skin to the outer skin core theme from the recipe. e innerinskin to the outer skin core theme from order to attach the inner skin to the outer skinthe recipe. core theme from the recipe. 4. The inner layer was not evident 5HÁHFW WKH F when the 4. The inner layer was not4.evident when The inner layerthe was not evident periphery when the with 3D layer was above it. Hence lead to the 3D layer was above it. Hence lead to above the 3D layer was it. Hence lead to the main form. conceptualizing of the central core concept. conceptualizing of the central core concept. conceptualizing of the central core concept.

Towers

Sanctum

Figure 37: ‘Interference’ outer skin

e Tan Y 8 57360 5 3) p Grou ter (1/201 s Seme

This subject is aimed to help First Year

7. The use of differ to distinguish the 3

n)

Figure 38-40: ‘Interference’ outer skin components

== n (Ea e An

+=+

+

Through the exploration of the Leaf veins

students develop computation This materials. as my precedent, Testing of literacy. different ThisI derived a pattern and g of different materials. This Testing of different materials. courseas requires students to fabricate a paper incorporated itThis into my paper lantern. ot desired it did not allow was not desired as it did not allow was not desired as it did not allow ght to pass through. Hence any light to pass through. Hence lantern. This assignment advises students to The interplay between the 2- and any to pass through. nting any shadows to belight any preventing shadows to Hence be use biomimicry to design. 3-dimensional representations of the pattern preventing any shadows to be d casted casted led to my concept of interference.

on Module 3: Fabrication Module 3: Fabrication

16

6. The lighting effe of complex core w disperse as they a

8. The use black a distinguish layers w glowing on the 2 e

9. However there concept in the for FHQWUDO FRUH IRU WK

Assembly drawing Assembly Drawing

Part 4

Part 4

Part 1

Part 1

Part 4

Part 4

Part 2

Part 2

Part 3

Part 3

Part 3

Part 3

Part 2

Part 2

Construction Order:

Construction order:

1. Part 1 (Inner Core) 1. Part 1 (inner core) 2. Part 2 2. Part 2 3. Part 3 3. Part 3 (not closing the structure 4. Part 4 4. Part 4

0RGXOH 5HÁHFWLRQ

Figure 41: ‘Interference’ Assembly Drawing ÁHFWLRQV

Interference

ÀQDO ODQWHUQ IXOÀOV WKH GLIIHUHQW DVSHFWV RI P\ UHFLSH ase Unit g the pentagonal base pattern as the panel option

5HÁHFWLRQV 0\ ÀQDO ODQWHUQ IXOÀOV WKH GLIIHUHQW DVSHFWV RI P\ UHFLSH 1. Base Unit -Using the pentagonal base pattern as the panel option

“In all chaos there is a cosmos, in all 2. Repetition disorder a secret order.” -3 layers distinguished with 1. the type of surface panel 2.

epetition yers distinguished with 1. the type of surface panel 2. different card type (Ivory and Black card)

caling central section(black card) is bigger than the 2 s.

otation 3D grid has a skew rotation.

Page

The different card type (Ivory and Black card)

Carl Jung

3. Scaling -The central section(black card) is bigger than the 2 sides.

The design was a success. The double skin 4. Rotation

stucture created a spectactular -The 3Dinterference grid has a skew rotation.

omplex core pattern. The inteference pattern is seencore from 5. Complex offsets are bigger at the black strip as compared to -The offsets are bigger at the black strip as compared to vory card. the light fragments that arethe projected onto Ivory card. ivory card glows with perforated glow on the ivory -The ivory card glows with perforated glow on the ivory d with a central area brighter the 2nd skin of the lantern and the fractal card with a central area brighter central core -The central diffraction of lights more light fragments at pattern the cen- illuminating out of the lantern. core -The diffraction of lights more light fragments at the cenegion tral region Figure 42: ‘Interference’

17

(R8 same as R1)

K11

Construction Design

L4 L5

K1

A P B L 3 0 0 41 / 2 014

Pentleigh & Essendon Grammar School

K7

LEGEND K20

LEGEND

$ 7RS OD\HU P GHSWK 'DUN *UH\ 6LOW\ VDQG ÀOO -(medium dense, moist and occasionally contains rocks gravel) (Where mass concrete is located) $ 6HFRQG OD\HU P P 3DOH *UH\ 6LOW\ 6DQG ÀOO (very dense and moist) 6WDEOH IRXQGDWLRQ KHQFH WKH ÀOOLQJ WR WKLV ]RQH

A3: 3rd layer (1.20m-1.50m)- Grey Brown Orange Mottled Sandy Silty Clay- (stiff and moist) $ )DOO RI SDYHPHQW LV 7KH SDYHPHQWV LV ÀQLVKHG Conc 3)

M2 B2

K11

K10

K3 K4

To

po

fc

him

To

po

f ro

of

ne

y5

56

7.9

B1: Mass Concrete % $QJOH RI LQĂ XHQFH GHJUHHV

(R8 same as R1)

B1: Mass Concrete % $QJOH RI LQĂ XHQFH GHJUHHV C1: SF4 (Edge Beam) C2: PF4 (Pad Footing) & *URXQG Ă RRU &RQFUHWH 6ODE DQG 6/ 5HLQIRUFHPHQW C4: Bar Chairs C5:K150mm Compacted sand-bed below each plane of the raft slab. C6: 0.2mm Black polythene membrane C7:K7Edge rebate for brick wall 150mm & 5HEDWH IRU 6OLGLQJ GRRU IUDPH

K9

$ 7RS OD\HU P GHSWK 'DUN *UH\ 6LOW\ V dense, moist and occasionally contains roc (Where mass concrete is located) $ 6HFRQG OD\HU P P 3DOH *UH\ dense and moist) 6WDEOH IRXQGDWLRQ KHQFH WKH ÀOOLQJ WR WKLV ]R A3: 3rd layer (1.20m-1.50m)- Grey Brown Ora Silty Clay- (stiff and moist) $ )DOO RI SDYHPHQW LV 7KH SDYHPHQ 3)

K10

C1: SF4 (Edge Beam) C2: PF4 (Pad Footing) & *URXQG Ă RRU &RQFUHWH 6ODE DQG 6/ 5H C4: Bar Chairs C5: 50mm Compacted sand-bed below ea slab. C6: 0.2mm Black polythene membrane C7: Edge rebate for brick wall 150mm & 5HEDWH IRU 6OLGLQJ GRRU IUDPH

L4

B2

L5

D1: First Floor Concrete Slab S32 135 mm thi D2: Slab reinforcing mesh located 20mm from of the slab’s surface

D1: First Floor Concrete Slab S32 135 mm thickness D2: Slab reinforcing mesh located 20mm from the top and bottom of the slab’s surface

80

.96

0

K1 N2

E1 Brick Wall E2 10 mm mortar bed E3 K20 Brick Ties 600mm space each way ( %ULFN 5HLQIRUFHPHQW E5 40mm Brick Cavity (Isolation Joint) E6 Cavity Grout E7 Damp-proof course ( :HHS +ROHV

K7

N4

N5

E1 Brick Wall E2 10 mm mortar bed E3 Brick Ties 600mm space each way ( %ULFN 5HLQIRUFHPHQW E5 40mm Brick Cavity (Isolation Joint) E6 Cavity Grout E7 Damp-proof course ( :HHS +ROHV

K10 M2 B2

) PP QDWXUDO DQRGL]HG )ORRU DQJOHV

Steel beams * 8QLYHUVDO EHDP % % DQG % 8% G2: Universal beam B2: 410 UB 54: * 6TXDUH +ROORZ VHFWLRQ 5% [ [ 2 C2 columns) * 3DUDOOHO Ă DQJH FKDQQHO 5% 3)& gutter) * 5HFWDQJOH KROORZ VHFWLRQ 5% [ [ ER[ JXWWHU

G6 16mm Fire rated plasterboard G7: 2M16 Chemset anchors which as a 120m * ,VRODWLRQ -RLQW EHWZHHQ VWHHO FROXPQ & G9: Shear Studs G10 :Cleats Plates G11: Load Path

) PP QDWXUDO DQRGL]HG )ORRU DQJOHV K10

K1 K15

FFL:

52

.21

Steel beams * 8QLYHUVDO EHDP % % DQG % 8% B2 G2: Universal beam B2: 410 UB 54: * 6TXDUH +ROORZ VHFWLRQ 5% [ [ 6+6 LQ EHWZHHQ $ 7RS OD\HU P GHSWK 'DUN *UH\ 6LOW\ VDQG ÀOO the 2 C2 columns) -(medium dense, moist and occasionally contains rocks * 3DUDOOHO à DQJH FKDQQHO 5% 3)& ERXQGLQJ WKH gravel) ER[ JXWWHU

(Where mass concrete is located) $ 6HFRQG OD\HU P P 3DOH *UH\ 6LOW\ 6DQG ÀOO * 5HFWDQJOH KROORZ VHFWLRQ 5% [ [ 5+6 ERXQGLQJ (very dense and moist) WKH ER[ JXWWHU

K1 6WDEOH IRXQGDWLRQ KHQFH WKH ÀOOLQJ WR WKLV ]RQH

G6 16mm Fire rated plasterboard A3: 3rd layer (1.20m-1.50m)- Grey Brown Orange Mottled G7:K72M16 Chemset anchors which as a 120mm embedded Sandy Silty Clay- (stiff and moist) * ,VRODWLRQ -RLQW EHWZHHQ VWHHO FROXPQ & DQG VWXG ZDOO $ )DOO RI SDYHPHQW LV 7KH SDYHPHQWV LV ÀQLVKHG G9: Shear Studs Conc 3) G10 :Cleats Plates G11: Load Path B1: Mass Concrete

LEGEND

L3

0

K21v H4

K2

L1

G10 K10

K20

K7

L4 K12

K19

K17

K8

N9

K5/N3

K15

G5

K16

K18 D1

G9

K13

L5

K6

K15

L3 G4

K7

M2 M1

K14

L4 G6

+ 7LPEHU VWXGV IUDPH [ 0*3 SLQH DW PP PD[LPXP FHQWHUV QRWFKHG PP IRU EUDFLQJ C1: SF4 (Edge Beam) K9 + 1RJJLQJV C2: PF4 (Pad Footing) & *URXQG Ă RRU &RQFUHWH 6ODE DQG 6/ 5HLQIRUFHPHQW + 3O\ZRRG %UDFLQJ K3 C4: Bar Chairs + 5LGJH 6WUDS

G1 L2 D2 I3

K11

K4

L4 C2

G1

C3

To

po

G6

E1

fc

him

To

: 48

po

.710

E5 I2

ne

y 57

LEGEND

.980

f ro

of

56

.960

C5

E3

H2

M1

N4

J2 N5

A1

E FFL:

A3

J3

52

.210

L3

H4

K2

K3

G10

G5

fc

po

K16

2

him

To

ne

G9

B2

y 57

of

56

.960

N4

E

1 2

GFL

: 48

K15

L3 G4

LEGEND

M1

K9

N

K3

H4

K2

G10 K10

K4

N9

K5/N3

K15

K20

L4

ammar School Junior for Boys by McBridge Charles Ryan Firm K12

K19

K18 D1

K13

L5

L3 G4

M1:Carpet M2: Blinds ) PP QDWXUDO DQRGL]HG )ORRU DQJOHV N1: Up stand N2:Weathering Steel beams N3: Overlap * 8QLYHUVDO EHDP % % DQG % 8% N4:Overhang G2: Universal beam B2: 410 UB 54: N5: Drip * 6TXDUH +ROORZ VHFWLRQ 5% [ [ 6+6 LQ EHWZHHQ the 2 C2 columns) N6:Drain * 3DUDOOHO Ă DQJH FKDQQHO 5% 3)& ERXQGLQJ WKH N7: Weep J2 ER[ JXWWHU

1 %UHDN /DE\ULQWK * 5HFWDQJOH KROORZ VHFWLRQ 5% [ [ 5+6 ERXQGLQJ N9: Sealant joint and gasket

K1

.710

C1: SF4 (Edge Beam) C2: PF4 (Pad Footing) & *URXQG Ă RRU &RQFUHWH 6ODE DQG 6/ 5HLQIRUFHPHQW C6 C4: Bar Chairs C5: 50mm Compacted sand-bed below each plane of the raft slab. A1 C6: 0.2mm Black polythene membrane C7: Edge rebate for brick wall 150mm & 5HEDWH IRU 6OLGLQJ GRRU IUDPH

K21v L1 K8

K15

e Charles

K7

K14

A3

L4 G6

E3

H3 I1 E8/N7 E7 H1 E2 E6

C6

GFL

: 48

.710

( %ULFN 5HLQIRUFHPHQW E5 40mm Brick Cavity (Isolation Joint) E6 Cavity Grout G11 E7 Damp-proof course ( :HHS +ROHV B2

K9

K3

N9

K4

2

3

K15

C1: SF4 (Edge Beam) C2: PF4 (Pad Footing) & *URXQG Ă RRU &RQFUHWH 6ODE DQG 6/ 5HLQIRUFHPHQW C6 C4: Bar Chairs C5: 50mm Compacted sand-bed below each plane of the raft slab.A1 C6: 0.2mm Black polythene membrane C7: Edge rebate for brick wall 150mm & 5HEDWH IRU 6OLGLQJ GRRU IUDPH

K21v L1 K8

K7

K6 K7

A2

D1: First Floor Concrete Slab S32 135 mm thickness D2: SlabA3reinforcing mesh located 20mm from the top and bottom of the slab’s surface E1 Brick Wall E2 10 mm mortar bed E3 Brick Ties 600mm space each way ( %ULFN 5HLQIRUFHPHQW E5 40mm Brick Cavity (Isolation Joint) E6 Cavity Grout G11 E7 Damp-proof course B2 ( :HHS +ROHV

K14

A4

J1

+ 7LPEHU VWXGV IUDPH [ 0*3 SLQH DW PP C8/ F1 PD[LPXP FHQWHUV QRWFKHG PP IRU EUDFLQJ + 1RJJLQJV + 3O\ZRRG %UDFLQJ + 5LGJH 6WUDS

Figure 43: Charles Mcbridge’s Pentleigh & Essedon Grammar I1: 0.2mm waterproof membrane Axonometric Drawing School Axonometric Drawing , 1RPLQDWHG LQVXODWLRQ $XWH[W TXLWHVSDFH PP SDQHO

L4 G1 G6

K1

K21v L1 K8

K7

K6 K7 K14

K11

2

) PP QDWXUDO DQRGL]HG )ORRU DQJOHV

18

Steel beams * 8QLYHUVDO EHDP % % DQG % 8% G2: Universal beam B2: 410 UB 54: * 6TXDUH +ROORZ VHFWLRQ 5% [ [ 6+6 LQ EHWZHHQ the 2 C2 columns) * 3DUDOOHO Ă DQJH FKDQQHO E 5% F 3)& ERXQGLQJ WKH D ER[ JXWWHU J2 * 5HFWDQJOH KROORZ VHFWLRQ 5% [ [ 5+6 ERXQGLQJ WKH ER[ JXWWHU

1 G6 16mm Fire rated plasterboard 2 G7: 2M16 Chemset anchors which as a 120mm embedded * ,VRODWLRQ -RLQW EHWZHHQ VWHHO FROXPQ & DQG VWXG ZDOO 3 E G9: Shear Studs J3 G10 :Cleats Plates N J1 G11: Load Path

E1 E5 I2 E3 H2

E7 H1

E6 C7/N1

A4

C8/ F1

+ 7LPEHU VWXGV IUDPH [ 0*3 SLQH DW PP

E4

E8/N7

G7/G8

C6

C6

C1

B1

E4

E8/N7 H1

J1: Sliding Door D01 J2:Window above the SD J3: Cavity sliding frame K1: MD1-Lysaght Long line 305 K2: MD4 - Color-bond sheet K3: Turn up K4: Turn down . ODSSLQJ VKHHWV LQ WKH GLUHFWLRQ RI Ă RZ . 5RRI ,QVXODWLRQ K7: Sarking . 6DIHW\ 0HVK . 5LGJH &DSSLQJ . 2YHU DQG XQGHU ODS Ă DVKLQJ . 5DIWHU 5 0 ; 0*3 5DIWHUV DW 0D[LPXP centers . 5DIWHU5 [ 0* 5DIWHUV DW PD[LPXP centers . 5DIWHU 5 [ 0*3 5DIWHUV DW PD[LPXP FHQWHUV ,Q EHWZHHQ 5 DQG 5

. 7LPEHU EDWWHQV 7% [ 0*3 %DWWHQV DW 0D[ center) K15: Purlin cleats . 6WDLQOHVV 6WHHO %R[ *XWWHU ZLGH [ GHHS ]LQFDOXPH ZLWK )DOO RI . 6WHHO $QJOH [ PP DW PP FHQWHUV . %R[ *XWWHU WUD\ PP 0DULQH JUDGH SO\ZRRG

. *DOYDQL]HG PP WUHDGHG 5RG %UDFNHW KDQJHUV K20: Skylight . &OLSSLQJ RI URRI SURĂ€OH

N

Penleigh And Essendon Grammar School Junior for Boys by McBridge Charles Ryan Firm , :DOO ÀQLVK PP SODVWHUERDUG Floor Plan Area 3 J1: Sliding Door D01 J2:Window above the SD Scale 1:20

H3 I1

E2

E5 I2

J3: Cavity sliding frame

K1: MD1-Lysaght Long line 305 K2: MD4 - Color-bond sheet K3: Turn up K4: Turn down . ODSSLQJ VKHHWV LQ WKH GLUHFWLRQ RI Ă RZ . 5RRI ,QVXODWLRQ K7: Sarking . 6DIHW\ 0HVK . 5LGJH &DSSLQJ . 2YHU DQG XQGHU ODS Ă DVKLQJ . 5DIWHU 5 0 ; 0*3 5DIWHUV DW 0D[LPXP centers . 5DIWHU5 [ 0* 5DIWHUV DW PD[LPXP centers . 5DIWHU 5 [ 0*3 5DIWHUV DW PD[LPXP FHQWHUV ,Q EHWZHHQ 5 DQG 5

N

/ PP &RPSUHVVHG FHPHQW VKHHW L2: Plywood L3: Acoustic Lining / 5RQGR .H\ ORFN V\VWHP L5 Furring Channel M1:Carpet M2: Blinds N1: Up stand N2:Weathering N3: Overlap N4:Overhang N5: Drip N6:Drain N7: Weep 1 %UHDN /DE\ULQWK

C1

B1

I1: 0.2mm waterproof membrane , 1RPLQDWHG LQVXODWLRQ $XWH[W TXLWHVSDFH PP SDQHO , :DOO ÀQLVK PP SODVWHUERDUG

E1

Steel beams E3 * 8QLYHUVDO EHDP % % DQG % 8% H2 G2: Universal beam B2: 410 UB 54: * 6TXDUH +ROORZ VHFWLRQ 5% [ [ 6+6 LQ EHWZHHQ H3 I1 the 2 C2 columns) * 3DUDOOHO Ă DQJH FKDQQHO 5% 3)& ERXQGLQJ WKH E7 E F D ER[ JXWWHU

E2 * 5HFWDQJOH KROORZ VHFWLRQ 5% [ [ 5+6 ERXQGLQJ J2 E6 WKH ER[ JXWWHU

1 C7/N1 G6 16mm Fire rated plasterboard 2 G7: 2M16 Chemset anchors which as a 120mm embeddedG7/G8 * ,VRODWLRQ -RLQW EHWZHHQ VWHHO FROXPQ & DQG VWXG ZDOO 3 G9: Shear Studs G10 :Cleats Plates E N G11: Load J3Path

M1

Scale 1:10

+ 3O\ZRRG %UDFLQJ + 5LGJH 6WUDS

K11

2

) PP QDWXUDO DQRGL]HG )ORRU DQJOHV

K1

B1: Mass C5Concrete % $QJOH RI LQĂ XHQFH GHJUHHV

E4

H2

L2

N4

K12

K20

K2 K12

L3

L4 K19 G4

L4

K18

K19 G4 K18

M2

J1: Sliding Door D01 J2:Window above the SD J3: Cavity sliding frame K1: MD1-Lysaght Long line 305 K2: MD4 - Color-bond sheet K3: Turn up K4: Turn down . ODSSLQJ VKHHWV LQ WKH GLUHFWLRQ RI Ă RZ . 5RRI ,QVXODWLRQ K7: Sarking . 6DIHW\ 0HVK . 5LGJH &DSSLQJ . 2YHU DQG XQGHU ODS Ă DVKLQJ . 5DIWHU 5 0 ; 0*3 5DIWHUV DW 0D[LPXP Yee Ann Tan centers 573608 [ 0* 5DIWHUV DW PD[LPXP . 5DIWHU5 Tutorial 6 centers Tim5DIWHU Derham . 5 [ 0*3 5DIWHUV DW PD[LPXP FHQWHUV ,Q EHWZHHQ 5 DQG 5

. 7LPEHU EDWWHQV 7% [ 0*3 %DWWHQV DW 0D[ center) K15: Purlin cleats . 6WDLQOHVV 6WHHO %R[ *XWWHU ZLGH [ GHHS ]LQFDOXPH ZLWK )DOO RI . 6WHHO $QJOH [ PP DW PP FHQWHUV . %R[ *XWWHU WUD\ PP 0DULQH JUDGH SO\ZRRG

. *DOYDQL]HG PP WUHDGHG 5RG %UDFNHW KDQJHUV K20: Skylight . &OLSSLQJ RI URRI SURĂ€OH

L3 K15

K15

I1: 0.2mm waterproof membrane , 1RPLQDWHG LQVXODWLRQ $XWH[W TXLWHVSDFH PP SDQHO , :DOO ÀQLVK PP SODVWHUERDUG

E5 I2

C8/ F1

G1

(WhereD2mass concrete is located) I3 $ 6HFRQG OD\HU P P 3DOH *UH\ 6LOW\ 6DQG ÀOO C4 (very dense and moist) 6WDEOH IRXQGDWLRQ KHQFH WKH ÀOOLQJ WR WKLV ]RQH

L4 A3: 3rd layer (1.20m-1.50m)- Grey Brown Orange Mottled C2 G1 Sandy Silty Clay- (stiff and moist) C3 G6 $ )DOO RI SDYHPHQW LV 7KH SDYHPHQWV LV ÀQLVKHG Conc 3)

K2

Detail Drawing Penleigh And Essendon Grammar School Junior for Boys by McBridge Charles Ryan Firm Floor Plan Area 3 Drawing Scale 1:10

K6

A2

PD[LPXP FHQWHUV QRWFKHG PP IRU EUDFLQJ + 1RJJLQJV + 3O\ZRRG %UDFLQJ + 5LGJH 6WUDS

C7/N1 WKH ER[ JXWWHU

G7/G8 G6 16mm Fire rated plasterboard G7: 2M16 Chemset anchors which as a 120mm embedded * ,VRODWLRQ -RLQW EHWZHHQ VWHHO FROXPQ & DQG VWXG ZDOO E G9: Shear Studs J3 Plates G10 :Cleats A4 J1 G11: Load Path

K7

M2

M1

K20

* 8QLYHUVDO EHDP % % DQG % 8%

D1: First Floor Concrete Slab S32 135 mm thickness Axonometric Drawing Detail D2: Slab reinforcing mesh located 20mm from the top and LEGEND Penleigh And Essendon Grammar School Junior for Boys McBridge Charles Ryan Firm bottom of the slab’s by surface Ryan Firm Penleigh And Essendon $ 7RS OD\HU P GHSWK 'DUN *UH\ 6LOW\ VDQG ÀOO Floor Plan Area 3 + 7LPEHU VWXGV IUDPH [ 0*3 SLQH DW PP E1 Brick Wall -(medium dense, moist and occasionally contains rocks PD[LPXP FHQWHUV QRWFKHG PP IRU EUDFLQJ Floor Plan Area 3 E2 10 mm mortar bed Scale gravel) 1:20 + 1RJJLQJV E3 Brick Ties 600mm space each way G9

) PP QDWXUDO DQRGL]HG )ORRU DQJOHV

N9

K16

M1

L3

B1: Mass Concrete centers % $QJOH RI LQĂ XHQFH GHJUHHV

K15 E1 Brick Wall K16 E2 10 mm mortar bed/ PP &RPSUHVVHG FHPHQW VKHHW L5 way K16 E3 Brick Ties 600mm space each L2: Plywood K11 ( %ULFN 5HLQIRUFHPHQW L3: Acoustic Lining E5 40mm Brick Cavity/ 5RQGR .H\ ORFN V\VWHP (Isolation Joint) L5 E6 Cavity Grout L5 Furring Channel E7 Damp-proof course ( :HHS +ROHV E1

B1: Mass Concrete C5 % $QJOH RI LQĂ XHQFH GHJUHHV

3 .210

K16

D1

K13

N

F

K15

52

G5

K12

L5

L4

DN5

K17

L4 K18

G6 $ 7RS OD\HU P GHSWK 'DUN *UH\ 6LOW\ VDQG ÀOO G1 -(medium dense, moist and occasionally contains rocks L2 gravel) (Where D2 mass concrete is located) I3 $ 6HFRQG OD\HU P P 3DOH *UH\ 6LOW\ 6DQG ÀOO (veryC4dense and moist) 6WDEOH IRXQGDWLRQ KHQFH WKH ÀOOLQJ WR WKLV ]RQH

L4 A3: 3rd layer (1.20m-1.50m)- Grey Brown Orange Mottled C2 Silty Clay- (stiff and moist) Sandy G1 $ )DOO RI SDYHPHQW LV 7KH SDYHPHQWV LV ÀQLVKHG C3 G6 Conc 3)

N2

FFL:

K4

K20

M2

.980

f ro

N9

K5/N3

K19

K17

G11

E1 Brick Wall E2 10 mm mortar bed E3 Brick Ties 600mm space each way ( %ULFN 5HLQIRUFHPHQW E5 40mm Brick Cavity (Isolation Joint) E6 Cavity Grout E7 Damp-proof course ( :HHS +ROHV

. 5DIWHU5 [ 0* 5DIWHUV DW PD[LPXP G2: Universal beam B2: 410 UB 54: * 6TXDUH +ROORZ VHFWLRQ 5% [ [ 6+6 LQ EHWZHHQ N5 C1: SF4 (Edge Beam) centers the 2 C2 columns) DW PD[LPXP C2: PF4 (Pad Footing). 5DIWHU 5 [ 0*3 5DIWHUV K21v C6 * 3DUDOOHO Ă DQJH FKDQQHO 5% 3)& ERXQGLQJ WKH FHQWHUV ,Q EHWZHHQ 5 DQG 5

& *URXQG Ă RRU &RQFUHWH 6ODE DQG 6/ 5HLQIRUFHPHQW L1 ER[ JXWWHU

K8 C4: Bar Chairs . 7LPEHU EDWWHQV 7% [ 0*3 %DWWHQV DW 0D[ C1 * 5HFWDQJOH KROORZ VHFWLRQ 5% [ [ 5+6 ERXQGLQJ C5: 50mm Compacted sand-bed below each plane of the center) WKH ER[ JXWWHU

K7 raft slab. K15: Purlin K6 cleats G6 16mm Fire rated plasterboard B1 C6: 0.2mm Black polythene membrane . 6WDLQOHVV 6WHHO %R[ *XWWHU ZLGH [ GHHS G7: 2M16 Chemset anchors which as a 120mm embedded C7: Edge rebate for brick wall 150mm ]LQFDOXPH ZLWK )DOO RI B2 K6 * ,VRODWLRQ -RLQW EHWZHHQ VWHHO FROXPQ & DQG VWXG ZDOO & 5HEDWH IRU 6OLGLQJ GRRU IUDPH . 6WHHO $QJOH [ PP DW PP FHQWHUV K7 G9: Shear Studs K10/N3 . %R[ *XWWHU WUD\ PP 0DULQH JUDGH SO\ZRRG G10 :Cleats Plates D1: First Floor Concrete Slab S32 135 mm thickness K14 K15 K6 . *DOYDQL]HG PP WUHDGHG 5RG %UDFNHW KDQJHUV G11: Load Path D2: Slab reinforcing mesh located 20mm from the top and K20: Skylight K16 B2 bottom of the slab’s surface + 7LPEHU VWXGV IUDPH [ 0*3 SLQH DW PP . &OLSSLQJ RI URRI SURÀOH K10/N3

K9

C8/ F1

K10

D1: First Floor Concrete Slab S32 135 mm thickness D2: Slab reinforcing mesh located 20mm from the top and bottom of the slab’s surface

A4

J1

K15

J1: Sliding Door D01 J2:Window above the SD J3: Cavity sliding frame

J1: Sliding Door D01 J2:Window above the SD J3: Cavity sliding frame

. 2YHU DQG XQGHU ODS Ă DVKLQJ . 5DIWHU 5 0 ; 0*3 5DIWHUV DW 0D[LPXP Steel beams

K15

A2

po

E4

$ 7RS OD\HU P GHSWK 'DUN *UH\ 6LOW\ VDQG ÀOO H3 K1:and MD1-Lysaght Long line 305 -(medium dense, moist occasionally contains rocks I1 K2: MD4 - Color-bond sheet gravel) E8/N7 N9 K3: up E7 (Where mass concrete is Turn located) H1 K4: P Turn down $ 6HFRQG OD\HU P 3DOH *UH\ 6LOW\ 6DQG ÀOO E2 (very dense and moist) . ODSSLQJ VKHHWV LQ WKH GLUHFWLRQ RI à RZ E6 6WDEOH IRXQGDWLRQ KHQFH WKH ÀOOLQJ WR WKLV ]RQH

N5 . 5RRI ,QVXODWLRQ A3: C7/N1 3rd layer (1.20m-1.50m)Grey Brown Orange Mottled K7: Sarking Sandy Silty Clay- (stiff. 6DIHW\ 0HVK and moist) G7/G8 $ )DOO RI SDYHPHQW LV 7KH SDYHPHQWV LV ÀQLVKHG . 5LGJH &DSSLQJ K1 Conc 3)

N2

C6

To

I1: 0.2mm waterproof membrane , 1RPLQDWHG LQVXODWLRQ $XWH[W TXLWHVSDFH , :DOO ÀQLVK PP SODVWHUERDUG

C5: 50mm Compacted sand-bed below each plane of the raft slab. I1: 0.2mm waterproof membrane C6: 0.2mm Black polythene membrane , 1RPLQDWHG LQVXODWLRQ $XWH[W TXLWHVSDFH PP SDQHO C7: Edge rebate for brick wall 150mm , :DOO ÀQLVK PP SODVWHUERDUG & 5HEDWH IRU 6OLGLQJ GRRU IUDPH

C4

GFL

+ 7LPEHU VWXGV IUDPH [ 0*3 SLQH D centers notched 20mm for bracing + 1RJJLQJV + 3O\ZRRG %UDFLQJ + 5LGJH 6WUDS

% $QJOH RI LQĂ XHQFH GHJUHHV

M2

K1: MD1-Lysaght Long line 305 K2: MD4 - Color-bond sheet K3: Turn up K4: Turn down . ODSSLQJ VKHHWV LQ WKH GLUHFWLRQ RI Ă RZ . 5RRI ,QVXODWLRQ K7: Sarking . 6DIHW\ 0HVK . 5LGJH &DSSLQJ . 2YHU DQG XQGHU ODS Ă DVKLQJ . 5DIWHU 5 0 ; 0*3 5DIWHUV DW centers . 5DIWHU5 [ 0* 5DIWHUV DW P . 5DIWHU 5 [ 0*3 5DIWHUV DW P EHWZHHQ 5 DQG 5

. 7LPEHU EDWWHQV 7% [ 0*3 %DWWH center) K15: Purlin cleats . 6WDLQOHVV 6WHHO %R[ *XWWHU ZLGH [ with Fall of 1:200 . 6WHHO $QJOH [ PP DW PP FH . %R[ *XWWHU WUD\ PP 0DULQH JUDGH SO\ . *DOYDQL]HG PP WUHDGHG 5RG %UDFNH K20: Skylight / PP &RPSUHVVHG FHPHQW VKHHW L2: Plywood L3: Acoustic Lining / 5RQGR .H\ ORFN V\VWHP L5 Furring Channel M1:Carpet M2: Blinds N1: Up stand N2:Weathering N3: Overlap N4:Overhang N5: Drip N6:Drain N7: Weep 1 %UHDN /DE\ULQWK N9: Sealant joint and gasket

Grammar School Junior for Boys by McBridge Charles Ryan Firm

/ PP &RPSUHVVHG FHPHQW VKHHW L2: Plywood L3: Acoustic Lining / 5RQGR .H\ ORFN V\VWHP L5 Furring Channel M1:Carpet M2: Blinds N1: Up stand N2:Weathering N3: Overlap N4:Overhang N5: Drip N6:Drain N7: Weep 1 %UHDN /DE\ULQWK N9: Sealant joint and gasket

Yee Ann Tan 573608 Tutorial 6 Tim Derham

Construction Design

“God is in the Detail.” Ludwig Mies Van Der Rohe Through this project. I was able to learn more about the construction of an actual building and understand the beauty and importance of Details.

This project also tested my model making and Drawing skills. Figure 44-50 : Construction Design Charles Mcbridge’s Pentleigh & Essedon Grammar School Model

19

Site Tectonics

Caldera

A P B L 2 0 0 47 / 2 014

@Maribyrong River

Figure 51: Caldera inspired landscape for the relocation of Farnsworth House.

3: OVERVIEW RENDER H HOUSE AT MARIBYRNONG RIVER

Caldera

SCALE -

NAME YEE ANN, TAN (EAN) (573608)

DRAWING SIZE. A2

Date 29/10/14

“ Solitude is a place of Purification� Martin Burber Through this Subject I tested different ways to manipulate the landscape. For this Project I wanted to create a home isolated from the public, while still able to enjoy the natural landscape of the site. Drawing inspiration from the Caldera landscape, I appropriated it to Figure 52: Ramps to go to the Farnsworth House

the site.

The Caldera Design included a water feature at the immediate site, bringing qualities of the river to the living space.

20

Figure 54 shows the Plan of the landscape design. Figure 55-56 shows the rendered image of the site.

SITE PLAN ASSESSMENT TASK2 (AMMENDED) FARNSWORTH HOUSE AT MARIBYRNONG RIVER 1

2

3

4

5

6

7

8

9

10

SCALE 1:500

NAME YEE ANN, TAN (EAN) (573608)

DRAWING SIZE. A2

Date 29/10/14

Figure 54: Plan of the Caldera landscape and ramp design.

ASSIGNMENT 3: SUN SHADOW STUDY 1 (21 March 7:40AM ) FARNSWORTH HOUSE AT MARIBYRNONG RIVER

Figure 55: Rendered pan view of the site

SCALE -

NAME YEE ANN, TAN (EAN) (573608)

DRAWING SIZE. A2

Date 29/10/14

Figure 56: Rendered view of the Ramps to go to the Farnsworth House

ASSIGNMENT 3: OVERVIEW RENDER 2 FARNSWORTH HOUSE AT MARIBYRNONG RIVER

Figure 57: Conceptual model of the site

SCALE -

NAME YEE ANN, TAN (EAN) (573608)

DRAWING SIZE. A2

Date 29/10/14

21

Other School Projects Collages and Visual Communication

These are some of my projects I have done in Printing Collage and Social Engagement and Visual Communications.

Figure 58-62 : Collages and visual communication assignment.

22

23

Hobbies - Sketching & Painting Drawing since I was 5 years old.

Here are some of my paintings and sketches. 63

64

Drawing has always been a passion of mine and I have drawing and painting since I was 5 years old. Figures 54 and 70 were completed when I was 15 years old for my Art Portfolio. I continue to draw during my free time and seek to find opportunities to draw.

65

66

Figure 63-67 : Sketches and Paintings 67

24

68

69

70

71

72

Figure 68-72 : Sketches and Paintings

25

Hobbies - Traveling & Photography https://instagram.com/tanyeeann/

Figure 73- 90 : Photos of my travelling adventures.

26

Figure 91- 98 : Photos of my travelling adventures.

I have been blessed with the opportunity to travel around the world and see beautiful architecture. To preserve these memories, I take photos to document my life experiences. I have been doing this since 2009. I use various social media, such as Facebook and Instagram to help me store my memories.

27

Screen Design For Capstone Aluminium, Johor Bahru

Here I used a random black and white image to map out the perforations in the plane. After which I inputted the data collected from the previous step to map out the opening size and perforation zones.

Here I used a random black and white image to map out the perforations in the plane. After which I inputted the data collected from the previous step to map out the opening size and perforation zones.

After inputting the image data I used sliders to control the opening size (radius) and the minimum penetration which simulates the fabrication limitation which might occur.

After inputting the image data I used sliders to control the opening size (radius) and the minimum penetration which simulates the fabrication limitation which might occur.

45mm to edge of 10mm diameter circle

20mm 10mm 50mm CTRS

Figure 99 : (Test) Grasshopper Image mapper function.

Figure 100-102 : The 3 different Designs presented to the client. 1(top): Lines (Bars) 2(middle): Leaves (Foliage) SUNSCREENinPANEL DESIGN 2 3(bottom):Birds Flight (Flights of fancy)

I have been blessed with the opportunity to

I recommended the third design as it had a A-37

design a number of Privacy Screens during

direct relationship with the bird cages which

my internship at Capstone Aluminium. These

hang adjacent to the fence, along the eaves A-37

screens were necessary for the client’s house,

of the pavilion. The final design mapped out

as there were no plants along one section

birds flying from one end to the other.

of the fence. Using Grasshopper, I designed Perforated Screens with the Image mapper

The decision to use 10 and 20mm

function.

perforations was based on the specifications of the machines at Capstone and to fullfil the

I came up with 3 different design options for the client. I created the designs in response to a site visit and conversation with the client, Mr Lee.

28

primary purpose of the privacy screen.

SCALE 1:25 PAPER SIZE :A3 DRAWN BY: EAN DATE: 2 Feb 2015 REV: 2

Prior to installation, we tested the visual mock up for the actual screen. Having achieved the desired outcome the screens were sent for powder-coating. After the screen was coated they were then installed on site.

Figure 103: CNC punch machine at Capstone Aluminum

Figure 105 : On Site installation of the screens.

Figure 104 : Test Sample for the Aluminium Screen

Figure 106 : On Site installation of the screens.

29