KADK_CITAstudio_Material Dynamics Portfolio by Lyn Poon

THE FLIP Layering - Bending Dynamic Adaptation in an Environment KADK - CITAstudio 2013

Material Dynamics: Semester 1 2013 Studio Project Group members: Mattias Lindskog (stud5518), Lyn Poon (stud5636), Karoline Wæringsaasen (stud5641), Thyge Wæhrens (stud4023)

THE FLIP Material Component Inspiration Inspiration relating to light Our research for this project began with finding inspiration that referenced to the effects of light.

Inspiration taken from the effects of layering and filtration of the light and the visual output.

Arnaud Lapierre

Ned Kahn

There was interest in the distortion of light and the effect related to the visual impact. Nobuhiro Nakanishi Olafur Eliasson

Inspiration in mechanical systems After studying many examples of dynamic systems, our focus was to keep the activation mechanism simple. Our goal was ‘maximum effect for minimum input’ Examples of desert grasses, that keep its rigid posture with a small curvature at its base became a source of reference. The simplicity of the bending curvature at its base to achieve the rigid extensive of the leaf was a simple yet effect notion to achieve its positioning.

Ammophila plant

Group members: Mattias Lindskog (stud5518), Lyn Poon (stud5636), Karoline Wæringsaasen (stud5641), Thyge Wæhrens (stud4023)

Tara Donovan

KADK - CITAstudio 2013 -Material Dynamics Project

THE FLIP Dynamic Material Component Study Material study and performance qualities

While experimenting with the properties of the material various bending options were tested. Looking more closely at the properties of how plants curl, this option was also tested as a possible movement for the component. However the decision was made that this required another input such as a string to create the full curl, this added another mechanism to the system and we felt this was no longer material dependent. We wanted a system that reacted mostly on the properties and behaviours of the material rather than us training the material to fit a mould or shape.

With this other mechanism, although it achieved the final rigid shape, the system moulded the sheet around a mould thus the properties of bending created naturally was not utilised.

Exploring with the ‘pinching’ forced on either side of the strip a study was made about the desired effects of when the components are placed alongside each other.

Group members: Mattias Lindskog (stud5518), Lyn Poon (stud5636), Karoline Wæringsaasen (stud5641), Thyge Wæhrens (stud4023)

KADK - CITAstudio 2013 -Material Dynamics Project

THE FLIP Material Component Component Study, Proto-typing, Acetate Material With the desire to work with reflectance and a more rigid material; from the selection of materials, a choice to study the acetate/plastic material was decided. The behaviour of the acetate material gave the most potential for manipulating the extension and rigid position of the leaf structure. As we explored the bending motion and the erection of the material, we discovered the potential it could have in creating a series of motions that reflected light in different manners. To enhanced the reflective light qualities we explored layering 3M mirror sheets on top of the acetate.

9.80665

Studies of varying the weight on a strip, gave different possibilities of the relaxed position of the component as well as requiring more force to reach the rigid state.

9.80665

The bending motion into its full rigid state gave the potential for a system with gradual motions and a variety of effect to light rather than just an open or closed state.

Even reinforcement at bottom

Even weight added on top and reinforced in centre

The bending behaviour of sheet of plastic to reach its rigid upright position Added weight on corner and reinforced in centre

Group members: Mattias Lindskog (stud5518), Lyn Poon (stud5636), Karoline WĂŚringsaasen (stud5641), Thyge WĂŚhrens (stud4023)

KADK - CITAstudio 2013 -Material Dynamics Project

THE FLIP Aggregation Pavilion, Facade Mechanism

Initial aggregation studies of the components

A simple rail mechanism was to activate the bending of the components so that a unified rail motion could potentially activate a whole series of the components in unison. It was decided that the variation in flips would depend on the weighting of each strip thus the rail movement would use one force to activate all the strips.

Prototype of rail system on single component

Prototype development made from acrylic to be used in physical testing machine

Development of mechanism into a rail system for aggregation of components

Diagram of the development of the rail system to activate the bending of the component

Physical model

Group members: Mattias Lindskog (stud5518), Lyn Poon (stud5636), Karoline WĂŚringsaasen (stud5641), Thyge WĂŚhrens (stud4023)

KADK - CITAstudio 2013 -Material Dynamics Project

THE FLIP Material Component Component Study, Proto-typing, qualities Light Reflectance Benders

Reflection outcomes Experimenting with layering various weights on the strips provided different levels of curvature in the bending and as a result a variety of reflectance effects. Types of layering

Total bend

Half bend

Straight

There was the potential for layering the sheet to create different areas of diffusion of light and visual effect. The movement of each strip could also be varied by the weighting and reinforcement of certain parts of the strip. Group members: Mattias Lindskog (stud5518), Lyn Poon (stud5636), Karoline WĂŚringsaasen (stud5641), Thyge WĂŚhrens (stud4023)

KADK - CITAstudio 2013 -Material Dynamics Project

THE FLIP Material Component Component Study, Proto-typing, Reflectance qualities Maya light studies of the reflective qualities in the strips when places together Controlled study over light reflections in a cubic room.

Setting up

Front

Back Outer strips

Middle strip

All without room

Group members: Mattias Lindskog (stud5518), Lyn Poon (stud5636), Karoline WĂŚringsaasen (stud5641), Thyge WĂŚhrens (stud4023)

All with room KADK - CITAstudio 2013 -Material Dynamics Project

THE FLIP Material Component Component Study, Proto-typing, Reflectance qualities Maya light studies of the reflective qualities in the strips when places together Setup 2 - Changing the position of the light

Lamp

Room

Lamp

Front

Back

Bent

Group members: Mattias Lindskog (stud5518), Lyn Poon (stud5636), Karoline WĂŚringsaasen (stud5641), Thyge WĂŚhrens (stud4023)

KADK - CITAstudio 2013 -Material Dynamics Project

THE FLIP Aggregation Mechanism Development Rail system proto-typing A initial acrylic two rail system was developed and tested as a rig for the physical simulation testing of the material properties of the component.

Prototype of rail system on single component modelled in Rhino

Prototype of rig tested on acetate sheet- Testing material acetate 100 x 297 x 0.3mm

Prototype of rig tested on acetate sheet with 3M applied - Testing material acetate with 3M mirror layer 100 x 297 x 0.3mm

Group members: Mattias Lindskog (stud5518), Lyn Poon (stud5636), Karoline WĂŚringsaasen (stud5641), Thyge WĂŚhrens (stud4023)

Studies of the 3M acetate aggregated on a rail and the reflective qualities KADK - CITAstudio 2013 -Material Dynamics Project

THE FLIP Aggregation Aggregation of components Façade system Studies were made exploring the possibilities of aggregating the components at different scales and the layering effects.

Studies into layering effects

Group members: Mattias Lindskog (stud5518), Lyn Poon (stud5636), Karoline Wæringsaasen (stud5641), Thyge Wæhrens (stud4023)

KADK - CITAstudio 2013 -Material Dynamics Project

THE FLIP Aggregation Aggregation of components Shelter, Pavilion, Installation Studies exploring different scales of application and layering effects.

Small scale components aggregated on rails

Large scale components aggregated as an installation Group members: Mattias Lindskog (stud5518), Lyn Poon (stud5636), Karoline WĂŚringsaasen (stud5641), Thyge WĂŚhrens (stud4023)

KADK - CITAstudio 2013 -Material Dynamics Project

THE FLIP Dynamic Relaxation Physical Testing Physical simulations Using a controlled forced application testing machined, the deflection of the acetate sheets could be recorded. Test 06 - Acetate on clamp heads with rig

Test 08 - acetate with 3M on clamp heads with rig Acetate

Acetate

Acetate + 3M Acetate

Acetate + 3m 16

100mm

Acetate + 3m

100mm

15 8

297mm

Time(s) 0.8238 1.6488 2.4738 3.2988 4.1238 4.9488 5.7738 6.5988 7.4238 8.2488 9.0738 9.8988 10.7238 11.5488 12.3738 13.1988 14.0238 14.8488 15.6738 16.4988 17.3238 18.1488 18.9738 19.7988 20.6238 21.4488 22.2738 23.0988 23.9238 24.7488 25.5738 26.3988 27.2238 28.0488 28.8738 29.6988 30.5238 31.3488 32.1738 32.9988 33.8238 34.6488 35.4738 36.2988 37.1238 37.9488 38.7738 39.5988 40.4238 41.2488 42.0738 42.8988 43.7238 44.5488 45.3738

-2

Time (s) 0.6492 1.299 1.9488 2.5992 3.249 3.8988 4.5492 5.199 5.8488 6.4992 7.149 7.7988 8.4492 9.099 9.7488 10.3992 11.049 11.6988 12.3492 12.999 13.6488 14.2992 14.949 15.5988 16.2492 16.899 17.5488 18.1992 18.849 19.4988 20.1492 20.799 21.4488 22.0992 22.749 23.3988 24.0492 24.699 25.3488 25.9992 26.649 27.2988 27.9492 28.599 29.2488 29.8992 30.549 31.1988 31.8492 32.499 33.1488 33.7992 34.449 35.0988 35.7492

Load (N)

-5

Load (N)

The mirrored 3M material required more load to initiate the movement. The strip also experienced the same flip motion towards the end.

Displacement (mm)

The results show that initial force is greater to initiate the start of the bending. The dips in the graph occurred towards the end of the motion when the strip very quickly flipped up. This snap motion could be controlled potentially by reduced the load the applied to create a smoother action.

Displacement (mm)

9.6mm

7.56mm

9.6mm 20mm

Average 0.84N

7.56mm

9.6mm

9.6mm Average 0.84N

20mm 9.6mm

9.6mm

Average7.5N

Group members: Mattias Lindskog (stud5518), Lyn Poon (stud5636), Karoline WĂŚringsaasen (stud5641), Thyge WĂŚhrens (stud4023)

7.56mm

9.6mm

7.56mm 20mm

7.56mm

9.6mm

15mm

Average7.5N

20mm

15mm 7.56mm

15mm

15mm 7.56mm

7.56mm

KADK - CITAstudio 2013 -Material Dynamics Project

THE FLIP Dynamic Relaxation Grasshopper ‘Dynamic Relaxation’ - Julien Nembrini Computational simulations Using the physical simulation data gathered we simulated the motion using Grasshopper and the ‘Dynamic relaxation’ script. With this script there were some problems as the program was intended for modelling members. Since our material study was a sheet we opted to model the sheet as a series of members composed to represent a sheet material.

Surface

Subdivide the surface

Planes that orient to the curvature of the surface

Decide point to attach and orientation

Dynamic Relaxation Grasshopper simulations

From the simulations the component behaviours could then be applied to a overall model Group members: Mattias Lindskog (stud5518), Lyn Poon (stud5636), Karoline Wæringsaasen (stud5641), Thyge Wæhrens (stud4023)

Planes attached to surface on rails linked to the mechanism

KADK - CITAstudio 2013 -Material Dynamics Project

THE FLIP Dynamic Relaxation Grasshopper ‘Dynamic Relaxation’ - Julien Nembrini Computational simulations

Calibrating the model to behaviour similarly to the physical simulations

Group members: Mattias Lindskog (stud5518), Lyn Poon (stud5636), Karoline Wæringsaasen (stud5641), Thyge Wæhrens (stud4023)

KADK - CITAstudio 2013 -Material Dynamics Project

THE FLIP

Vegetation

Ventilation

Program + Site

High sun

Cloudy/Low light rainy conditions

Public Realm The chosen location for the project is Singapore, as the location has the potential for a dynamically changing system within a daily time frame. Although there is little seasonal changes due to the location on the equator, creating a system that is more sensitive to the daily fluctuations in the environment could generate an immediate changing results for investigation. This could also generate a very apparent changing dynamic system that provides an immediate visible effect. Due to the relatively high temperatures all year round and high humidity levels, Singapore suffers from a lack of public space occupancy and has introduced environmental control target for the coming years. This is highlighted in the following:

Arcade Plaza

Singapore’s National Climate Change Strategy 2.14. Measures that can lower ambient temperature include increasing the amount of greenery in the city (e.g. city parks, rooftop gardens, vertical greening in buildings) and modifying building layouts and designs (e.g. using building materials with better thermal properties, lighter-coloured building surfaces, designing building interiors and exterior building layouts for better ventilation and maximising the wind tunnel effect).

Bee culture

Urban farming

Direct wind funnelling

Biodiversity

Markets

Aids cool environment

Vegetation Concerts

Public interaction

Arcade

Shelter

Exercise classes

Public Realm

Gathering/Learning spaces

Pergola Promenade

Plaza Pavilions

Journey/path

Group members: Mattias Lindskog (stud5518), Lyn Poon (stud5636), Karoline Wæringsaasen (stud5641), Thyge Wæhrens (stud4023)

KADK - CITAstudio 2013 -Material Dynamics Project

THE FLIP Program + Site Urban strategy Study of the possible routes and paths linking public activities The intension to encourage public inhabitation outdoors, a study was made into the routes and paths that could have potential value in generating a journey that links key attraction points. Museums

Final Route Proposal

Outdoors facilities Shopping malls and resturants

Pavilions

Museums Pavilions

Existing route around Marina Bay Pavilions Plaza

Existing promenade route

Pavilions

Museums

Outdoors facilities Shopping malls and resturants

Group members: Mattias Lindskog (stud5518), Lyn Poon (stud5636), Karoline WĂŚringsaasen (stud5641), Thyge WĂŚhrens (stud4023)

KADK - CITAstudio 2013 -Material Dynamics Project

THE FLIP Location and Aspirations Precedent public activity and spaces - Marina Bay Esplanade Theatre

The Floating Platform

Merlion Park

Double Helix Bridge

Firework events

Art Science Museum,Shopping, Hotel

Sailing events

Gardens by the Bay CBD

The Lawn in CBD

Group members: Mattias Lindskog (stud5518), Lyn Poon (stud5636), Karoline Wæringsaasen (stud5641), Thyge Wæhrens (stud4023)

Site location

KADK - CITAstudio 2013 -Material Dynamics Project

THE FLIP Location and Aspirations Spacial qualities and atmospheres The desire is to promote group activities and create outdoor environments that provide an improved comfort level and encourage public interactions.

Vegetation

Ventilation

High sun

Cloudy/Low light rainy conditions

Arcade Plaza

The Site

Group members: Mattias Lindskog (stud5518), Lyn Poon (stud5636), Karoline WĂŚringsaasen (stud5641), Thyge WĂŚhrens (stud4023)

KADK - CITAstudio 2013 -Material Dynamics Project

THE FLIP Environment Climate Analysis

Olygyay Graph

• Tropical Rainforest climate • Relatively high humidity • Strong solar intervals

Singapore’s climate is located out of the comfort zone, as shown in the graph. It requires: • Air flow • Shading • Very humid and hot

• Cloud cover high • Regular rainfall March-May: Heavy early evening showers June-Sept: Strong Morning winds Oct-Nov: Evening storms Dec-Mar: Heaviest rainfall Dry Bulb Temperature 0C

0C 33.80<= 32.52 31.24 29.96 28.65 27.40 26.12 24.84 23.56 22.28 <=21.00

24:00

00:00

January

February

March

April

May

June

July

August

September

October

November

December

Relative Humidity %

% 100.00<= 94.30 88.60 82.90 77.20 71.50 65.80 60.10 54.40 48.70 <=43.00

24:00

00:00

January

February

March

April

May

June

July

August

Group members: Mattias Lindskog (stud5518), Lyn Poon (stud5636), Karoline Wæringsaasen (stud5641), Thyge Wæhrens (stud4023)

September

October

November

December

KADK - CITAstudio 2013 -Material Dynamics Project

THE FLIP Environment Climate 1°16’54.84”N, 103°51’15.80”E Singapore 19:00 18:00 17:00 16:00 15:00

14:00

13:00

12:00

11:00

10:00

09:00

08:00 07:00

ºC

33.00 <=

31.80

30.60

June July May

29.40

August April 28.20 September March 27.00 October February November January December

25.80

Links to main road

24.60

23.40

Potential extending routes

Maximising evening light into the structure

22.20

<=21.00

Sun-Path Diagram - Latitude: 1.37 Hourly Data: Dry Bulb Temperature ( ºC) SINGAPORE_SGP Conditional Selection Applied: 23<Dry Bulb Temperature<32 3738.0 hours of total 3980.0 sun up hours(93.93%).

Group members: Mattias Lindskog (stud5518), Lyn Poon (stud5636), Karoline Wæringsaasen (stud5641), Thyge Wæhrens (stud4023)

KADK - CITAstudio 2013 -Material Dynamics Project

THE FLIP Location and Aspirations Wind study Annual Wind 0800-0900

To provide greater comfort levels in the high humidity environment found in Singapore, the principle of promoting and generating air flows was investigated. Wind tends to be the strongest from the North and South directions. On a daily basis air flows tend to increases as the day progressed. Due to the higher humidity levels in the morning and lower air flows, adapting a design to increase air flows during this period would help create greater comfort levels.

Profile structure to maximise capturing north sea breeze winds

The shelter is designed to optimise the capturing of the natural air flows in the environment. This aims to encourage an improved comfort level within the spaces.

Shelter to interfere with air flows to capture the winds and direct accordingly into the spaces

1200-1300

Potential extending routes

1600-1700

Vegetation

Ventilation

Typological section of maximising air flows High sun

Group members: Mattias Lindskog (stud5518), Lyn Poon (stud5636), Karoline WĂŚringsaasen (stud5641), Thyge WĂŚhrens (stud4023)

Cloudy/Low light rainy conditions

KADK - CITAstudio 2013 -Material Dynamics Project

THE FLIP Performance aims Applying theories for conditioning the environment to our site and program schedule 0800-0900

1200-1300

1600-1700

Aim

Humidity

80%

Ventilate generate air flow

60-80%

Ventilate generate air flow

60-80%

Ventilate generate air flow

Illuminance

<20000 lux

Components open

60000-80000 lux

Deploy full shading - closed components

40000-60000 lux

Semi shading - Components semi open

Radiation

<158 Wh/m2

Components open

> 474 Wh/m2

Components close

316-474 Wh/m2

Components semi open

Wind

2-3m/s

Generate/capture air flows

3-4m/s

Generate/capture air flows

5-6m/s

Shelter or redirect air flows

N wind

N wind N wind

Low morning light

N wind Low Evening light

N wind

N wind Low morning light

N wind

Low morning light

N wind

Low morning light

S wind Low morning light Open components to maximise ventilation and allow daylight

Open structure to maximise Open components to light maximise ventilation and allow daylight

directs and speeds up wind flows

Afternoon Morning light High humidity Low wind speed 2-5m/s Morning exercise class

Reflect radiation and sun

Closed arrangement of components to maximise shading

High solar gain 60 -80% humidity Wind speed 3-5m/s Lunch break

S wind Closed arrangement of Reflect radiation and sun components to maximise Reflection of light shading

Open structure to maximise light Reflect radiation and sun

Open structure to maximise Closed arrangement of light components to maximise shading

Noon sun

Component configuration directs and speeds up wind flows

Closed strucutre to provide wind and rain protection when necessary

High solar gain 60 -80% humidity Morning light Wind speed 3-5m/s High humidity Low wind speed 2-5m/s Lunch break Morning exercise class

Afternoon

Noon sun

Component configuration directs and speeds up wind flows

Noon sun

Component configuration directs and speeds up wind flows

Closed strucutre to provide wind and rain protection when necessary

Component configuration to allow maximium light and ventilation due to high humidity Closed strucutre to provide wind and rain protection as wind speeds are higher in the evening

Reflection of light

components to maximise shading

Reflection of light

Evening Afternoon

Evening Evening light 60 -80% humidit Wind speed 5-9m/s

Evening light 60 -80% humidit Wind speed 5-9m/s 60 -80% humidity Evening exercise Wind speed 3-5m/s Concerts Lunch break

Closed strucutre to provide wind and rain protection when necessary High solar gain

Evening exercise Concerts

Afternoon

Compo Reflection of Closed strucutrelight to a provide wind and rain protection as wind speeds are higher in the evening

Reflectio

Group members: Mattias Lindskog (stud5518), Lyn Poon (stud5636), Karoline WĂŚringsaasen (stud5641), Morning Afternoon Thyge WĂŚhrens (stud4023)

Morning

S wind

Component configuration directs and speeds up wind flows

Closed arrangement of components to maximise shading of Closed arrangement

Afternoon

Morning

Noon sun

S wind Reflection of light

Open structure to maximise light Open structure to maximise light

light and ventilation due to high humidity

Reflect radiation and sun Component configuration to allow maximium light and ventilation due to high humidity Component configuration directs and speeds up wind flows

Closed strucutre to provide wind and rain protection when necessary

Component configuration directs and speedsComponent up wind flows configuration

S wind S windComponent configuration to allow maximium

Noon sun

Component configuration directs and speeds up wind flows

Open structure to maximise Component light configuration Open components to Closed arrangement of directs and speeds maximise ventilation and components to maximise up wind flows allow daylight shading

peeds s

orning

Open components to Reflect radiation and sun maximise ventilation and allow daylight

Open components S wind to maximise ventilation and allow daylight

Morning

S wind S wind

S wind

Low Evening light

S wind Reflect radiation and sun

S wind

Low Even

N wind

Evening

Closed strucutre to provide wind and rain protection when necessary

Evening

Closed strucutre to provide wind and rain protection as wind speeds are higher in the evening

Evening light 60 -80% humidit Wind speed 5-9m/s Evening exercise Concerts

Evening

KADK - CITAstudio 2013 -Material Dynamics Project

Evening

DESIGN PERFORMANCE ADAPTATION Performance Chart Conditions for orientation on site

Important Distance views Predominant North Winds

Mapping activity/ need of space

Radiation optimisation in sections of structure

Close intimate views

Sun Angle and positioning

Morning

Afternoon / evening

Red: Optimised directions of shape that allows maximum wind hitting surface Black: Surface that creates maximum wind interference

Lunch

Predominant South Winds

Group members: Mattias Lindskog (stud5518), Lyn Poon (stud5636), Karoline WĂŚringsaasen (stud5641), Thyge WĂŚhrens (stud4023)

10x10 (m) Views

KADK - CITAstudio 2013 -TEK 5: Climate Adaptation - Emanuele Naboni

THE FLIP Program + Site Marina Bay - Final Proposal

Wider Marina Bay views

Intimate view and relation to the water

Link to main road

Defined lawn areas

Lawn Markets

Transistional areas

Plaza

View into Marina Bay and attractions

Sightline to lawn plaza area in CBD Existing promenade route

Extended proposal

Group members: Mattias Lindskog (stud5518), Lyn Poon (stud5636), Karoline WĂŚringsaasen (stud5641), Thyge WĂŚhrens (stud4023)

KADK - CITAstudio 2013 -Material Dynamics Project

THE FLIP Program + Site Section profiles Final Proposal of program

Transitional spaces -Inside/outside

Plaza -Intimate concerts

Sqaure

Visual connection to main road

-Markets -Gathering

Evening light

Arcade

-Morning yoga -Evening concerts

Visual connection Marina Bay attractions 9m

Section D

Group members: Mattias Lindskog (stud5518), Lyn Poon (stud5636), Karoline WĂŚringsaasen (stud5641), Thyge WĂŚhrens (stud4023)

KADK - CITAstudio 2013 -Material Dynamics Project

THE FLIP

maximise cross ventilation

Arcade profile N

Program + Site Section profiles

Application of fin components on profiles

Increase height stack effect 3m capture north winds/sea breeze Arcade profile

maximise cross ventilation

encourage air movement - convection currents

Morning Yoga

Plaza profile

Increase height stack effect

Section A

capture north winds/sea breeze 9m

capture south winds 3m

encourage air movement - convection currents

Plaza profile

maximise cross ventilation

Arcade profile

Afternoon Markets N

Sqaure profile N

Section B

capture north winds/sea breeze

Increase height - winds capture south stack effect

Evening light

capture north winds/sea breeze

Section C

Intimate Concerts N

encourage air movement - convection currents

Sqaure profile N

capture north winds/sea breeze

Plaza profile N

Group members: Mattias Lindskog (stud5518), Lyn Poon (stud5636), Karoline WĂŚringsaasen (stud5641), Thyge WĂŚhrens (stud4023)

KADK - CITAstudio 2013 -Material Dynamics Project

THE FLIP Aggregation Proposal

Morning Yoga

Maximise light Generate air flows to dissipate high morning humidity

Group members: Mattias Lindskog (stud5518), Lyn Poon (stud5636), Karoline WĂŚringsaasen (stud5641), Thyge WĂŚhrens (stud4023)

KADK - CITAstudio 2013 -Material Dynamics Project

THE FLIP Aggregation Proposal

Afternoon Markets

Full Shading on roof - closed components on roof Ventilation and horizontal light - open side flaps

Group members: Mattias Lindskog (stud5518), Lyn Poon (stud5636), Karoline WĂŚringsaasen (stud5641), Thyge WĂŚhrens (stud4023)

KADK - CITAstudio 2013 -Material Dynamics Project

THE FLIP Aggregation Proposal

Intimate Concert Square

Lower light for atmosphere - closed roof components and top half Ventilation and air flow - open lower components

Group members: Mattias Lindskog (stud5518), Lyn Poon (stud5636), Karoline WĂŚringsaasen (stud5641), Thyge WĂŚhrens (stud4023)

KADK - CITAstudio 2013 -Material Dynamics Project

THE FLIP Aggregation Proposal

Evening Fireworks and Light shows

Focus attention and views at the light shows and fireworks - fully open roof components and semi open side components

Group members: Mattias Lindskog (stud5518), Lyn Poon (stud5636), Karoline WĂŚringsaasen (stud5641), Thyge WĂŚhrens (stud4023)

KADK - CITAstudio 2013 -Material Dynamics Project

THE FLIP

FLIP on a new perspective Adapting to promote optimal comfort for the public

Group members: Mattias Lindskog (stud5518), Lyn Poon (stud5636), Karoline Wæringsaasen (stud5641), Thyge Wæhrens (stud4023)

KADK - CITAstudio 2013 -Material Dynamics Project

The Flip Appendix

APPENDIX SECTION ONE Data collection and analysis from the physical simulation tests

Group members: Mattias Lindskog (stud5518), Lyn Poon (stud5636), Karoline Wæringsaasen (stud5641), Thyge Wæhrens (stud4023)

KADK - CITAstudio 2013 -Material Dynamics Project

The Flip Appendix Inspiration, Component Study, Proto-typing, Testing material acetate 100 x 297 x 0.3mm

Optimising Testing Machine

A initial acrylic two rail system was developed and tested as a rig for the physical simulation testing of the material properties of the component.

Test 01 - material clamped directly (material slipped)

Test 02 - material clamped with a rig (alignment problems)

Testing material acetate with 3M mirror layer 100 x 297 x 0.3mm

Test 03 preferred option - material clamped using the engineered clamp heads with a rig

Group members: Mattias Lindskog (stud5518), Lyn Poon (stud5636), Karoline WĂŚringsaasen (stud5641), Thyge WĂŚhrens (stud4023)

KADK - CITAstudio 2013 -Material Dynamics Project

The Flip Appendix Reflection outcomes

Acetate

3M Material layered on acetate

Group members: Mattias Lindskog (stud5518), Lyn Poon (stud5636), Karoline WĂŚringsaasen (stud5641), Thyge WĂŚhrens (stud4023)

KADK - CITAstudio 2013 -Material Dynamics Project

8.00

-2.00 Time (s) 0.5712 1.143 1.7148 2.2872 2.859 3.4308 4.0032 4.575 5.1468 5.7192 6.291 6.8628 7.4352 8.007 8.5788 9.1512 9.723 10.2948 10.8672 11.439 12.0108 12.5832 13.155 13.7268 14.2992 14.871 15.4428 16.0152 16.587 17.1588 17.7312 18.303 18.8748 19.4472 20.019 20.5908 21.1632 21.735 22.3068 22.8792 23.451 24.0228 24.5952 25.167 25.7388 26.3112 26.883 27.4548 28.0272 28.599 29.1708 29.7432 30.315 30.8868 31.4592

The Flip

Appendix

Test 01 - acetate on clamps no rig

Erection

Test01

16.00

14.00

12.00

10.00

A B

6.00

4.00

2.00

0.00

Load (N) Displacement (mm)

Group members: Mattias Lindskog (stud5518), Lyn Poon (stud5636), Karoline Wæringsaasen (stud5641), Thyge Wæhrens (stud4023) KADK - CITAstudio 2013 -Material Dynamics Project

Time(s) 0.5712 1.143 1.7148 2.2872 2.859 3.4308 4.0032 4.575 5.1468 5.7192 6.291 6.8628 7.4352 8.007 8.5788 9.1512 9.723 10.2948 10.8672 11.439 12.0108 12.5832 13.155 13.7268 14.2992 14.871 15.4428 16.0152 16.587 17.1588 17.7312 18.303 18.8748 19.4472 20.019 20.5908 21.1632 21.735 22.3068 22.8792 23.451 24.0228 24.5952 25.167 25.7388 26.3112 26.883 27.4548 28.0272 28.599 29.1708 29.7432 30.315 30.8868 31.4592

The Flip

Appendix

Test 02 - acetate on clamps no rig

Relaxing

Test02

-2

Load(N) Displacement(mm)

Group members: Mattias Lindskog (stud5518), Lyn Poon (stud5636), Karoline Wæringsaasen (stud5641), Thyge Wæhrens (stud4023) KADK - CITAstudio 2013 -Material Dynamics Project

Time (s) 0.5712 1.143 1.7148 2.2872 2.859 3.4308 4.0032 4.575 5.1468 5.7192 6.291 6.8628 7.4352 8.007 8.5788 9.1512 9.723 10.2948 10.8672 11.439 12.0108 12.5832 13.155 13.7268 14.2992 14.871 15.4428 16.0152 16.587 17.1588 17.7312 18.303 18.8748 19.4472 20.019 20.5908 21.1632 21.735 22.3068 22.8792 23.451 24.0228 24.5952 25.167 25.7388 26.3112 26.883 27.4548 28.0272 28.599 29.1708 29.7432 30.315 30.8868 31.4592

The Flip

Appendix

Test 03 - acetate with 3M on clamps with rig

Erection

Test05

Load (N)

Group members: Mattias Lindskog (stud5518), Lyn Poon (stud5636), Karoline Wæringsaasen (stud5641), Thyge Wæhrens (stud4023)

-2

Displacement (mm)

B KADK - CITAstudio 2013 -Material Dynamics Project

-2 Time (s) 0.5712 1.143 1.7148 2.2872 2.859 3.4308 4.0032 4.575 5.1468 5.7192 6.291 6.8628 7.4352 8.007 8.5788 9.1512 9.723 10.2948 10.8672 11.439 12.0108 12.5832 13.155 13.7268 14.2992 14.871 15.4428 16.0152 16.587 17.1588 17.7312 18.303 18.8748 19.4472 20.019 20.5908 21.1632 21.735 22.3068 22.8792 23.451 24.0228 24.5952 25.167 25.7388 26.3112 26.883 27.4548 28.0272 28.599 29.1708 29.7432 30.315 0 0

The Flip

Appendix

Test 04 - acetate with 3M on clamps with rig

Relaxing

Test04

Load (N)

Group members: Mattias Lindskog (stud5518), Lyn Poon (stud5636), Karoline Wæringsaasen (stud5641), Thyge Wæhrens (stud4023)

-4

Displacement (mm)

KADK - CITAstudio 2013 -Material Dynamics Project

Time (s) 0.5712 1.143 1.7148 2.2872 2.859 3.4308 4.0032 4.575 5.1468 5.7192 6.291 6.8628 7.4352 8.007 8.5788 9.1512 9.723 10.2948 10.8672 11.439 12.0108 12.5832 13.155 13.7268 14.2992 14.871 15.4428 16.0152 16.587 17.1588 17.7312 18.303 18.8748 19.4472 20.019 20.5908 21.1632 21.735 22.3068 22.8792 23.451 24.0228 24.5952 25.167 25.7388 26.3112 26.883 27.4548 28.0272 28.599 29.1708 29.7432 30.315 30.8868 31.4592

The Flip

Appendix

Test 06 - acetate on clamp heads with rig

Erection

Test06

-2

Load (N) Displacement (mm)

B - 38 sec flip speed up

Group members: Mattias Lindskog (stud5518), Lyn Poon (stud5636), Karoline Wæringsaasen (stud5641), Thyge Wæhrens (stud4023) KADK - CITAstudio 2013 -Material Dynamics Project

Time(s) 0.5598 1.122 1.6842 2.2458 2.808 3.3702 3.9318 4.494 5.0562 5.6178 6.18 6.7422 7.3038 7.866 8.4282 8.9898 9.552 10.1142 10.6758 11.238 11.8002 12.3618 12.924 13.4862 14.0478 14.61 15.1722 15.7338 16.296 16.8582 17.4198 17.982 18.5442 19.1058 19.668 20.2302 20.7918 21.354 21.9162 22.4778 23.04 23.6022 24.1638 24.726 25.2882 25.8498 26.412 26.9742 27.5358 28.098 28.6602 29.2218 29.784 30.3462 30.9078 31.47

The Flip

Appendix

Test 07 - acetate on clamp heads with rig

Relaxing

Test07

Load (N) Displacement (mm)

Group members: Mattias Lindskog (stud5518), Lyn Poon (stud5636), Karoline Wæringsaasen (stud5641), Thyge Wæhrens (stud4023) KADK - CITAstudio 2013 -Material Dynamics Project

Time (s) 0.5712 1.143 1.7148 2.2872 2.859 3.4308 4.0032 4.575 5.1468 5.7192 6.291 6.8628 7.4352 8.007 8.5788 9.1512 9.723 10.2948 10.8672 11.439 12.0108 12.5832 13.155 13.7268 14.2992 14.871 15.4428 16.0152 16.587 17.1588 17.7312 18.303 18.8748 19.4472 20.019 20.5908 21.1632 21.735 22.3068 22.8792 23.451 24.0228 24.5952 25.167 25.7388 26.3112 26.883 27.4548 28.0272 28.599 29.1708 29.7432 30.315 30.8868 31.4592

The Flip

Appendix

Test 08 - acetate with 3M on clamp heads with rig

Erection

Test08

-2

Load (N) Displacement (mm)

Group members: Mattias Lindskog (stud5518), Lyn Poon (stud5636), Karoline Wæringsaasen (stud5641), Thyge Wæhrens (stud4023) KADK - CITAstudio 2013 -Material Dynamics Project

Time (s) 0.5712 1.143 1.7148 2.2872 2.859 3.4308 4.0032 4.575 5.1468 5.7192 6.291 6.8628 7.4352 8.007 8.5788 9.1512 9.723 10.2948 10.8672 11.439 12.0108 12.5832 13.155 13.7268 14.2992 14.871 15.4428 16.0152 16.587 17.1588 17.7312 18.303 18.8748 19.4472 20.019 20.5908 21.1632 21.735 22.3068 22.8792 23.451 24.0228 24.5952 25.167 25.7388 26.3112 26.883 27.4548 28.0272 28.599 29.1708 29.7432 30.315 30.8868 31.4592

The Flip

Appendix

Test 09 - acetate with 3M on clamp heads with rig

Relaxing

Test09

-2

Load (N) Displacement (mm)

Group members: Mattias Lindskog (stud5518), Lyn Poon (stud5636), Karoline Wæringsaasen (stud5641), Thyge Wæhrens (stud4023) KADK - CITAstudio 2013 -Material Dynamics Project

The Flip Appendix Aggregation facade studies

Group members: Mattias Lindskog (stud5518), Lyn Poon (stud5636), Karoline WĂŚringsaasen (stud5641), Thyge WĂŚhrens (stud4023)

KADK - CITAstudio 2013 -Material Dynamics Project