THE FLIP Layering - Bending Dynamic Adaptation in an Environment KADK - CITAstudio 2013 -TEK 5: Climate Adaptation - Emanuele Naboni
TEK 5: Climate Adaptation: Finding the relationships for parametric design development Group members: Mattias Lindskog (stud5518), Lyn Poon (stud5636), Karoline WĂŚringsaasen (stud5641), Thyge WĂŚhrens (stud4023)
FLIP on a new perspective Adapting to promote optimal comfort for the public
Group members: Mattias Lindskog (stud5518), Lyn Poon (stud5636), Karoline WĂŚringsaasen (stud5641), Thyge WĂŚhrens (stud4023)
KADK - CITAstudio 2013 -TEK 5: Climate Adaptation - Emanuele Naboni
Dynamic and adaptive to provide: Comfort: Views: Activities
Group members: Mattias Lindskog (stud5518), Lyn Poon (stud5636), Karoline WĂŚringsaasen (stud5641), Thyge WĂŚhrens (stud4023)
KADK - CITAstudio 2013 -TEK 5: Climate Adaptation - Emanuele Naboni
Adaptive Environments
Group members: Mattias Lindskog (stud5518), Lyn Poon (stud5636), Karoline Wæringsaasen (stud5641), Thyge Wæhrens (stud4023)
KADK - CITAstudio 2013 -TEK 5: Climate Adaptation - Emanuele Naboni
The Flip Dynamic Material Component Study Material study and performance qualities The project began with the research and understanding of material properties for a selected sample of materials. The project brief required the investigation to be focused on the interaction with light. Inspiration and interests for this project study was driven by the reflection of light and the diffusion of light through the properties of a material; hence the choice to work with the plastic and mirror material was selected. The rigid properties of the sheets of plastic material lead us to use inspiration from the ammophila plant leaf. The rigid nature of the leaf meant it is able to hold its upright position but when flaccid it held a different position. This behaviour was similar to the plastic sheets and so the aim was to worked to develop this proposal. For this project the system requirement was a dynamic motion; for this requirement our aim was not to limit the results to either extremes of close or open. The desire was to create a system that provided a full range of experiences; it would adapted with the continually changing conditions so that each experience was unique. This flexible range of results was aimed to generate different experiences for the audience.
Ammophila plant
Sheet plastic and mirror material study
9.80665
Acetate
Acetate + 3m
100mm
100mm
9.80665 297mm
297mm
Understanding a mechanism to activate The understanding of a mechanical systems to activate the components individually and as an aggregate was the next part of the process of investigation. Keeping this system simple was a key focus for the project, as this would create greater efficiency in the longevity in the mechanical system and energy input to activate. The method of ‘minimal input for maximum output’ became a key target as this would guide the project for greater performance in sustainability and efficiency.
9.6mm
7.56mm
9.6mm 20mm
Average 0.84N
7.56mm
20mm 9.6mm
9.6mm
15mm
Average7.5N
15mm 7.56mm
7.56mm
Analysis of how material behaviours
Dynamic Relaxation Grasshopper simulations
Aggregation of components The flexibility of applying our components to any surface and situation was a driving focus. The system should be full adaptable. The possibilities to arrange the layout and create different effects was key to our understanding and development of our components and eventually the arrangement. Dynamic Relaxation Grasshopper simulations
Physical testing and data collection
Group members: Mattias Lindskog (stud5518), Lyn Poon (stud5636), Karoline Wæringsaasen (stud5641), Thyge Wæhrens (stud4023)
Example of possible aggregation of components
KADK - CITAstudio 2013 -TEK 5: Climate Adaptation - Emanuele Naboni
PROGRAM Location and Aspirations Climate 1°16’54.84”N, 103°51’15.80”E Singapore - Marina Bay 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:
• Tropical Rainforest climate • Relatively high humidity • Strong solar intervals • Cloud cover high
Singapore’s National Climate Change Strategy
• Regular rainfall March-May: Heavy early evening showers June-Sept: Strong Morning winds Oct-Nov: Evening storms Dec-Mar: Heaviest rainfall
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). 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 -TEK 5: Climate Adaptation - Emanuele Naboni
<=
PROGRAM Location and Aspirations Olygyay Graph
Climate 1°16’54.84”N, 103°51’15.80”E 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
24.60
23.40
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%).
In comparison Helsinki also has a relatively high humidity levels but require more sun exposure. The climate here is also out of the comfort zone during the whole year.
Group members: Mattias Lindskog (stud5518), Lyn Poon (stud5636), Karoline Wæringsaasen (stud5641), Thyge Wæhrens (stud4023)
Singapore’s climate is located out of the comfort zone, as shown in the graph. It requires: • Air flow • Shading • Very humid and hot
KADK - CITAstudio 2013 -TEK 5: Climate Adaptation - Emanuele Naboni
PROGRAM Location and Aspirations Public realm and climate Referring to the Singapore’s National Climate Change Strategy, improving the public realm strategy has determined our program for our initiative.
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 -TEK 5: Climate Adaptation - Emanuele Naboni
PROGRAM 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 -TEK 5: Climate Adaptation - Emanuele Naboni
PROGRAM 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 -TEK 5: Climate Adaptation - Emanuele Naboni
PROGRAM Location and Aspirations Typological arrangements to adapt to the climate data in Singapore Singapore tends to experience around 80 to 100% cloud cover all year round. As a result direct illumination and radiations levels are not as high, however this causes high humidity levels. Global horizontal levels tend to be higher in Singapore due to the cloud cover and pollution obstructions.
Direct Normal Radiation Wh/m2
Vegetation
Ventilation
24:00
High sun
Cloudy/Low light rainy conditions
Arcade 00:00
Plaza January
February
March
April
May
June
July
August
September
October
November
Wh/m2 923.00<= 830.70 738.40 646.10 553.80 461.50 369.20 276.90 184.60 92.30 <=0.00
December
Global Horizontal Radiation Wh/m2
Wh/m2 1040.00<= 936.00 728.00 624.00 520.00 416.00 312.00 206.00 104.00 <=0.00
24:00
00:00
January
February
March
April
May
June
July
August
September
October
November
December
tenth 10.00<= 9.00 8.00 7.00 6.00 5.00 4.00 3.00 2.00 1.00 <=0.00
Total Cloud Cover tenth 24:00
00:00
January
February
March
April
May
June
July
August
Group members: Mattias Lindskog (stud5518), Lyn Poon (stud5636), Karoline WĂŚringsaasen (stud5641), Thyge WĂŚhrens (stud4023)
September
October
November
December
KADK - CITAstudio 2013 -TEK 5: Climate Adaptation - Emanuele Naboni
PROGRAM Location and Aspirations Typological arrangements to adapt to the climate data in Singapore 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. Our goal to encourage and promote public realm activity meant we had to focus on comfort levels. Thus we decided to focus our analysis on; wind for air flows, radiation to reduce heat gain, and illuminance to maximise light levels on cloudy days within our spaces. Ventilation
Annual Wind 0800-0900
1200-1300
1600-1700
Arcade
Wind Speed m/s
m/s 26.20<= 23.58 20.96 18.34 15.72 13.10 10.48 7.86 5.24 2.62 <=0.00
24:00
00:00
January
February
March
April
May
June
July
August
Group members: Mattias Lindskog (stud5518), Lyn Poon (stud5636), Karoline WĂŚringsaasen (stud5641), Thyge WĂŚhrens (stud4023)
September
October
November
December
KADK - CITAstudio 2013 -TEK 5: Climate Adaptation - Emanuele Naboni
PROGRAM Site Shadow analysis Site N
March
Lack of shading at noon on the site
June
Morning shadows can provide a cooler space for exercise classes December
In the morning to facilitate morning exercise classes the aim would be to maximise light entering the shelter - this could be achieved using the open arrangement of the fins and the reflective qualities of the fins
At noon when the space is aimed to facilitate lunch time activities, to create shade from the high sun, the fins would opt for a closed position to create shadows.
Group members: Mattias Lindskog (stud5518), Lyn Poon (stud5636), Karoline WĂŚringsaasen (stud5641), Thyge WĂŚhrens (stud4023)
In the early evening where there is overcast shadows from the surrounding buildings, the shelter could opt for an open fin arrangement to optimise light entering and reflections.
KADK - CITAstudio 2013 -TEK 5: Climate Adaptation - Emanuele Naboni
Directing wind flow PROGRAM Directing wind flow
Directing wind flow
Performance aims Typological strategies for conditioning mirco environments
Directing windadapting flow passively controlled micro climate to encourage an active public space for use all year round Providing a dynamic Directing air flows
Radiation and convection currents Radiation Radiationand andconvection convectioncurrents currents
Radiation
convection UsingRadiation radiation onand surfaces to generatecurrents convection currents and stack effect to promote air flows
sea breeze sea breeze sea breeze
Group members: Mattias Lindskog (stud5518), Lyn Poon (stud5636), Karoline WĂŚringsaasen (stud5641), Thyge WĂŚhrens (stud4023) sea breeze
sea breeze sea breeze sea breeze
sea breeze 2013 -TEK 5: Climate Adaptation - Emanuele Naboni KADK - CITAstudio
PROGRAM Performance aims Applying theories for conditioning the environment to our site and program schedule 0800-0900
1200-1300
1600-1700
Aim
Aim
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
N wind Low morning light
g
N wind
Low morning light
N wind
N wind
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
High solar gain 60 -80% humidity Wind speed 3-5m/s Lunch break
Open structure to maximise Closed arrangement of light components to maximise shading
S wind Closed arrangement of Reflect radiation and sun components to maximise Reflection of light shading Noon sun
Component configuration directs and speeds up wind flows
Closed strucutre to provide wind and rain protection when necessary
Morning exercise class
Afternoon
Component configuration directs and speeds up wind flows
Component configuration directs and speeds up wind flows
Noon sun
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
Noon sun
Closed arrangement of components to maximise shading of Closed arrangement
Afternoon
High solar gain 60 -80% humidity Morning light Wind speed 3-5m/s High humidity Low wind speed 2-5m/s Lunch break
S wind
S wind Reflection of light Open structure to maximise light Reflect radiation and sun
Morning
Noon sun
Component configuration directs and speeds up wind flows
Reflect radiation and sun
Closed arrangement of components to maximise shading
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
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
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
KADKEvening - CITAstudio 2013 -TEK 5: Climate Adaptation - Emanuele Naboni
Evening
PROGRAM
Vegetation
Ventilation
Spacial arrangement
High sun
Cloudy/Low light rainy conditions
Spacial transitions and public occupancy of areas
Arcade Plaza
A B
C
N
D
Transitional spaces -Inside/outside Final Proposal of program Plaza -Intimate concerts
Sqaure
Visual connection to main road
-Markets -Gathering
Evening light
Arcade
-Morning yoga -Evening concerts
Visual connection Marina Bay attractions 9m
5m
3m
Group members: Mattias Lindskog (stud5518), Lyn Poon (stud5636), Karoline WĂŚringsaasen (stud5641), Thyge WĂŚhrens (stud4023)
KADK - CITAstudio 2013 -TEK 5: Climate Adaptation - Emanuele Naboni
3m
PROGRAM
maximise cross ventilation
Arcade profile N
Spacial arrangement Section profiles
Application of fin components on profiles
Increase height stack effect 3m capture north winds/sea breeze Arcade profile
maximise cross ventilation
N
9m
encourage air movement - convection currents
Morning Yoga
Plaza profile
N
N
Increase height stack effect
Section A
capture north winds/sea breeze 9m
capture south winds 3m
encourage air movement - convection currents
Plaza profile
5m
N
maximise cross ventilation
Arcade profile
Afternoon Markets N
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
5m
9m
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 -TEK 5: Climate Adaptation - Emanuele Naboni
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
DESIGN PERFORMANCE ADAPTATION Component Matrix Conditions for applying the component variations to data simulations Component variation
Wind
Illuminance Data on tested on profile
Radiation Application of components
Data on tested on profile
Application of components
High ground illuminance
Reduce illuminance on ground
High radiation on roof
Reduce radiation on ground
Low ground illuminance
Increase ground illuminance
Low ground radiation
Increase radiation on ground
Group members: Mattias Lindskog (stud5518), Lyn Poon (stud5636), Karoline WĂŚringsaasen (stud5641), Thyge WĂŚhrens (stud4023)
KADK - CITAstudio 2013 -TEK 5: Climate Adaptation - Emanuele Naboni
DESIGN PERFORMANCE ADAPTATION Component Matrix August 01-31 at 1200
Illuminance
Radiation
Component variation
75% Reduction Condition suited for intimate concerts
50% Reduction Condition suited for markets
30% Reduction Condition suited for Yoga Group members: Mattias Lindskog (stud5518), Lyn Poon (stud5636), Karoline Wæringsaasen (stud5641), Thyge Wæhrens (stud4023)
70% Reduction Condition suited for midday and large gatherings
55% Reduction
27% Reduction Condition suited for cooler days KADK - CITAstudio 2013 -TEK 5: Climate Adaptation - Emanuele Naboni
DESIGN PERFORMANCE ADAPTATION Proposal outcome assessment against performance goals Wind analysis Final Proposal 0800-9000
1200-1300
1600-1700 The target was to redirect the wind around the structure or for the wind to come into contact with our structure as our aim is to use the component element of our proposal as out secondary stage of adapting to the environment. Allowing the structure to interfere with the wind flow the fins would capture and redirect the air flows into our shelter when desired, or vice versa if wind flows are strong the fin components would opt for a closed position and direct air flows around the structure. Our goal for our shelter to interfere with the main north and south winds is achieved.
March
Shelter interrupts air flows
June
Morning
Afternoon / evening
Air flows redireceted
Lunch
10x10 (m) Views
December Group members: Mattias Lindskog (stud5518), Lyn Poon (stud5636), Karoline WĂŚringsaasen (stud5641), Thyge WĂŚhrens (stud4023)
KADK - CITAstudio 2013 -TEK 5: Climate Adaptation - Emanuele Naboni
DESIGN PERFORMANCE ADAPTATION Proposal outcome assessment against performance goals Illuminance analysis Final Proposal 0800-9000
1200-1300
1600-1700 Although the priority is to create areas of shading; due to the high percentage of cloud cover in Singapore, finding opportunities of maximise illuminance level is also studied.
Shelter is creating shading March
Luminance levels are higher on the peaks
June
Morning
Afternoon / evening
Lunch
10x10 (m) Views
December Group members: Mattias Lindskog (stud5518), Lyn Poon (stud5636), Karoline WĂŚringsaasen (stud5641), Thyge WĂŚhrens (stud4023)
KADK - CITAstudio 2013 -TEK 5: Climate Adaptation - Emanuele Naboni
DESIGN PERFORMANCE ADAPTATION Proposal outcome assessment against performance goals Radiation analysis Final Proposal 0800-9000
1200-1300
1600-1700 Lowering the height of the structure decreased the radiation on the roof surfaces. Although we require some radiation effect to assist stack ventilation and convection currents, we did not want our shelter to gather too much radiation raising the ambient temperature too much. By sloping the sides more vertically we are able to reduce the radiation effect on the side.
Shelter is creating shading March
Radiation levels are higher on the peaks Radiation levels are reduced on verticle slope walls
June
Morning
Afternoon / evening
Lunch
10x10 (m) Views
December Group members: Mattias Lindskog (stud5518), Lyn Poon (stud5636), Karoline WĂŚringsaasen (stud5641), Thyge WĂŚhrens (stud4023)
KADK - CITAstudio 2013 -TEK 5: Climate Adaptation - Emanuele Naboni
ADAPTATION RESPONSIVE DESIGN Adapting the component Optimsing the components to respond to specific conditions - Wind Response National Parade Day 9th August (Data range 4th -14th Aug) 0800-9000 1200-1300
1600-1700
Site Due to the stronger southern wind the structure assists the air flow to flow over the structure and if necessary the fins can open and capture the air flows.
N
The more vertically sloped northern face has been orientated to create a greater surface area for direct conflicts with wind flows to capture lower air flows.
Final Proposal Profile
The gentle sloping south facade helps disapate the stringer south winds
Components applied to profile
The fin components help direct the air flows into the structure
Group members: Mattias Lindskog (stud5518), Lyn Poon (stud5636), Karoline WĂŚringsaasen (stud5641), Thyge WĂŚhrens (stud4023)
KADK - CITAstudio 2013 -TEK 5: Climate Adaptation - Emanuele Naboni
ADAPTATION RESPONSIVE DESIGN Adapting the component Optimsing the components to respond to specific conditions - Illuminance Response National Parade Day 9th August (Data range 4th -14th Aug) 0800-9000 Site
1200-1300
1600-1700
Final Proposal Profile By applying a structure to the site, shaded areas are generated however as a result at certain times this also reduces the illumination levels.
Illumination levels are low when the fins are closed, by opening the fins illumination levels can be increased Components applied to profile Using the adaptation of our fin components, illumination levels can be customised to suit the desired illumination. For example in the mornings for yoga classes more illumination is required and thus the fins can be optimised to an open position Group members: Mattias Lindskog (stud5518), Lyn Poon (stud5636), Karoline WĂŚringsaasen (stud5641), Thyge WĂŚhrens (stud4023)
KADK - CITAstudio 2013 -TEK 5: Climate Adaptation - Emanuele Naboni
ADAPTATION RESPONSIVE DESIGN Adapting the component Optimsing the components to respond to specific conditions - Radiance Response National Parade Day 9th August (Data range 4th -14th Aug) 0800-9000
1200-1300
1600-1700
Site
Final Proposal Profile
High points capture more radiation level assisting with the stack effect for air movement By applying a structure to the site, lowering the radiation levels on the ground plane is reduced desired to help create a cooler environment. When desired the fins can be opened to increase the radiation levels inside the structure.
Radiation levels on more vertical slope are reduced Radiation of the roof panels is also desired at this can help assist the movement of air flows based on stack effect and convection current principles. Generating air movement is important to our shelter as this is to aid dissipating the hot humid air.
Components applied to profile
N
Group members: Mattias Lindskog (stud5518), Lyn Poon (stud5636), Karoline WĂŚringsaasen (stud5641), Thyge WĂŚhrens (stud4023)
KADK - CITAstudio 2013 -TEK 5: Climate Adaptation - Emanuele Naboni
ADAPTATION RESPONSIVE DESIGN Program Adaptation Matrix August 01-31
Program Schedule Yoga classes - mornings
Illuminance
Radiation Annual Average
0900
10% Reduction Markets - midday
Intimate concerts - early evening
Firework Displays - late evening
50% Reduction
1200
60% Reduction
80% Reduction
75% Reduction
80% Reduction
50% Reduction
68% Reduction
1600
1900
Group members: Mattias Lindskog (stud5518), Lyn Poon (stud5636), Karoline Wæringsaasen (stud5641), Thyge Wæhrens (stud4023)
KADK - CITAstudio 2013 -TEK 5: Climate Adaptation - Emanuele Naboni
The Flip Dynamic Environments 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 -TEK 5: Climate Adaptation - Emanuele Naboni
The Flip Dynamic Environments 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 -TEK 5: Climate Adaptation - Emanuele Naboni
The Flip Dynamic Environments 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 -TEK 5: Climate Adaptation - Emanuele Naboni
The Flip Dynamic Environments 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 -TEK 5: Climate Adaptation - Emanuele Naboni
PROCESS PROCESS PROCESS PROCESS Methodology Methodology Methodology Methodology
PROCESS Methodology
PROCESS PROCESS
Workflow within the design process
Component Component Design Design Component Design Methodology Methodology
Component Design
Component Design
Component Component Design Design Physical component
Physical Testing Simulation in Grasshopper Physical component Physical component Physical Physical component Testing Physical Testing Physical Testing Simulation in in Simulation Application in Application to Application toSimulationtoin PhysicalSimulation component Physical Testing Grasshopper GrasshopperGrasshopper Rhino model Rhino model Rhino model Grasshopper
Physical Physical component component
Physical Physical Testing Testing
Proposal Design Proposal Design Proposal Design
Simulation Simulation in in Grasshopper Grasshopper
Application to Rhino model
Application to Rhino model
Application Application to to Rhino Rhino model model
Proposal Design
Proposal Proposal Design Design
Design Development Application of com App of cM Data Analysis Data Analysis Data Analysis Grasshopper GrasshopperData Grasshopper Simulation on Rhino on Simulation Rhino Optimise on Rhinodesign Optimise design Optimise Simulation design Simulation on design on Simulation design Mapdesign on results design Map intoresults inputMap into input results into input Analysis Simulation Grasshopper Simulation on Rhino Optimise Simulation onApplication design Map results into input data Application of components to Data Analysis Grasshopper Simulation on Rhino model Optimise design Simulation on design ponents toponents structure to struc pone model model model data for grasshopper data forstructure grasshopper databased for grasshopper model d for grasshopper script for on data input based on data based input on data base in script for components script for components script for components s Application Application of of com com Data Data Analysis Analysis Grasshopper Grasshopper Simulation Simulation on on Rhino Rhino Optimise Optimise design design Simulation Simulation on on design design components Map Map results results into into input input model model
Group members: Mattias Lindskog (stud5518), Lyn Poon (stud5636), Karoline WĂŚringsaasen (stud5641), Thyge WĂŚhrens (stud4023)
data data for for grasshopper grasshopper script script for for components components
ponents ponents to to structure structure based based on on data data input input
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