Student Portfolio
ARCH 473/3522 - DIGITAL DESIGN STUDIO AND WORKSHOP Mehad Hanbal Fall 2022
The American University in Cairo (AUC)
School of Sciences and Engineering - Department of Architecture
ARCH 473/3522 - Digital Design Studio and Workshop (Fall 2022
Student portfolio documenting samples of work submitted along the course, including research, experimentation, 3D modeling, digital fabrication, parametric design and modeling, physical model realisation and analysis.
Student name: Mehad Hanbal Student ID: 900191879
© The American University in Cairo (AUC), September 2022
Mehad Hanbal Architecture Student
I’m a senior Architectural Engineering student at the American University in Cairo. I’m from Alexandria, Egypt yet I was born and raised in Doha, Qatar and moved to Egypt after my high school graduation. I have a hobby of drawing and painting, as I’ve painted a mural in the North Coast, Egypt that got viral during a certain period of time and another one in the indoor swimming pool of my high school, American School of Doha, Qatar. I painted decorative display boards for Starbucks in Doha Fesrtival City where my work was displayed. I customized Nike shoes for customers both in Egypt and Qatar through my startup business, Mehad Arts, that was initiated in Qatar. I was a student officer for a year and delegate for two years in the American School of Doha Model United Nations in which I formally re-
searched information under popular, global issues, practiced public speaking and negotiating around international students within the school. I also participated in two conferences in the Arabic Model United Nations in Qatar Academy where I would prepare speeches and discuss international issues in the Middle East and propose solutions in Arabic in a civilized, disciplined way. I was then a delegate for two years in the Hague International United Nations in Qatar in which I negotiated and debated over resolutions with other international students worldwide. As a General Manager of the Services committee in the Architecture Association for 2 years, I was able to create more than 250 student packs for the department as well as design and implement the co-working space at the AUC’s Architecture department. I also worked as a student teaching assistant for Digital Representation Tools for Architects (ARCH 273/1521) in which I helped students how to use Revit, Rhino, and Photoshop and was committed to attending 2.5 hours, twice a week, as well as offering extra help on Zoom. I also recently learned adults beginners ballet and took a Shoe Design course where I was committed to attending it 2.5 hours twice a week during the semester in which I learned how to design and create a shoe from scratch and work with local workers in the industry. I’ve also did a summer abroad in John Cabot University in NGO Consulting and I’m currently a research assistant.
First try in experimenting with fabric formwork by creating a cable net, timber frame, & fabric, inspired by a precedent
Project 1: Learning from Materiality
01
https://www.semanticscholar.org/paper/Design-process-for-prototype-concrete-shells-using-Veenendaal-Block/9ecb734bd541397e124e05208ca6ce84d783954a#paper-header
Fig. 1 Design process for prototype concrete shells using a hybrid cable-net and fabric formwork
Stage 1 Material Exploration Trial 1
History and Background
Fabric Formwork uses structural membranes as the main facing material for concrete molds, resulting in a highly flexible that can deflect or change its curvature shape under pressure.
In Roman times, the fabric was a result of the Industrial Revolution; when building cofferdams, retaining walls would be built by having them filled with clay in woven reed baskets, allowing for easy removal of the falsework after the concrete hardens. Fabric formwork reduces construction time and costs, the permeability of fabric reduces the number of air voids improving the overall durability.
Specific Fabrication Approach: Fabric Formwork
Precedents
For the first trial in the Material Exploration stage, I was inspired by the following examplesin Fig. 1, 2., and 3., that explain the design process for prototype concrete shells using a hyprid cable-net and fabric formwork (D. Veenendaal). The precedents demonstrate the creation of thin concrete panels: substructure of flexible wire mesh & a lining made of latex sheet which is what determined the panel’s final form.
https://www.holcimfoundation.org/projects/latex-formwork
Fig. 2 Latex Formwork
Chapter name Portfolio 2
Learning from Materiality
https://www.semanticscholar.org/paper/Design-process-for-prototype-concrete-shells-using-Veenendaal-Block/9ecb734bd541397e124e05208ca6ce84d783954a#paper-header
Process
Materials Used: Gypsum, Water, Bedsheet, Plastic Wrap, Wire, Nasebian, Tape, Cardboard Box, Glue Gun, Cardboard
Main Domain of Application: Plastic Roll
Second Domain of Application: Nasebian (for borders of formwork) Process: 1) Cut Cardboard Box Into Triangular Pieces for Creating “Frames”
Creating thin concrete panels: substructure of flexible wire mesh & a lining made of latex sheet determining panel’s final form. Learning from Materiality
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4) Add Domain of Application (Plastic Wrap for Separate Gypsum) & Nasebian to Prevent Gypsum from Sagging at Edges 5) Mix Gypsum With Water 6) Pour Gypsum on Formwork Learning from Materiality Portfolio 2) Insert Wire as “Cable Network” & Create Openings for Wire Insertion 3) Add Fabric Layer (Bedsheet Piece) Ratio 1:2
Result and Reflection:
There was a lot of cracks and although the nasebian idea did help have a smooth edge, it still wasn’t effective due to such cracks.
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Learning from Materiality Stage 1 Material Exploration Trial 2 Portfolio Materials Used: Tissue Rolls, Glue Gun Process 1) Cut Tissue Rolls Into Halves as Casting Formwork 2) Glue Them Together 3) Pour Gypsum with Water Ratio 1:2
Materials Used
New Technique
Result and Reflection: I missed the step of adding the plastic layer as a separator for gypsum. Gypsum & water connected well with this cast. Add plastic layer next time for removal to see actual effectiveness.
Creating thin concrete panels: substructure of flexible wire mesh & a lining made of latex sheet determining panel’s final form.
Specific Fabrication Approach:
Chapter name Portfolio 8 Precedent 2) Join Sticks Together in Triangular Form with Glue Gun Learning from Materiality Portfolio 3) Wrap Wires as “Cable Network” as Before Stage 1 Material Exploration Trial 3 https://www.sciencedirect.com/science/article/abs/pii/S0141029614003344
4 Design process for prototype concrete shells using a hybrid cable-net and fabric formwork
Fig.
the same objective
achieving the same result. Process 1) Wrap Wooden Sticks With Wire
Fabric Formwork As shown in Fig. 4, I was still inspired by the same precedent from Fig. 1 and thus I’ve used
of
Materials Used
4) Soak Bedsheet Piece (Fabric) in Gypsum with Water
Result and Reflection:
The support from the wire and the wooden sticks were a better improvement than the initial fabric formwork.
Overall Reflection:
I did three trials in this stage, experimenting with a strong objective at the start of creating a cable network before pouring the gypsum & water as a support, then diverting into a casting technique with no rigid idea in mind, and finally reverting back to fabric formwork techniques with soaking fabrics instead to create my final form.
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One of the last trials in experimentation with fabric formwork using gypsum, water, and the cable net technique
Project 1.2: Material Exploration
02
Chapter name Portfolio 12
Draw Shell Design on Foam Learning from Materiality Material Exploration 2) Use Cutter to Cut Shape of Shell & Pull Out Foam
2 Material Experimentation Trial 1 Specific Fabrication Approach: Casting Initial Thought Process Through Sketches Materials Used: Foam
thinner)
Precedents 1)
Stage
(aimed to have this part thicker) (aimed to have this part become gradually more
Student Name ARCH 473/3522 - Spring 2019 13 Foam Fall 2022 ARCH 473/3522 - Fall 2022 4) Smoothen Edges 3) Take Dimensions
Chapter name Portfolio 14 Material Exploration 6) Start Pouring Precedents Possible Justification As To Why Cracks Were Caused Here Since Pouring Wasn’t As Smooth In This Area (Very Weak Method of Pouring) 5) Begin Mixing Gypsum w/Water Ratio 1:2 7) Even/Spread Out/ Distribute Remaining Gypsum Along Surface for Flat Surface
Some Appearance of Air Voids
Interesting Texture of Foam Bubble Pattern
Result and Reflection:
The cracks were as expected due to the predicted air voids caused by the interference when pouring (evident at relatively thinner areas). I could’ve added slightly more gypsym for better hold and increased the depth to compensate for the thin areas to give more strength and hold.
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Technique Fall 2022 ARCH 473/3522 - Fall 2022
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Chapter name Portfolio 16 Material Exploration Learning from Materiality Stage 2 Material Experimentation Trial 2 Specific Fabrication Approach: Cable Net Materials Used: Light Silk on Heavy Silk Materials Used: Light Silk on Heavy Silk Process 1) Cut into Desired Shape 2) Make More Bendings to Shape As Desired for Different Heights / Boundaries / Restrictions 3) Mix Gypsum With Water (Increase Gypsum Due to Large Surface Area & To Allow Paste to Take Proper Shape) Material Exploration
Materials Used
4) A mess occurred as I didn’t know how to evenly distribute the paste without having to interfere myself as distribute it among the formwork manually.
...So I had to interfere and even out the paste with my hands, then shake the formwork slightly to balance it out (risking high chance of creating air voids and possible cracks).
I made sure the points (coordinates) touching the ground were strong enough to stay standing so it takes the proper concave shape.
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MaterialMaterialExplorationExplorationLearning from Materiality Portfolio
Result and Reflection:
I was Impressed by the result as the paste took shape of the silk quite well, yet I was questioning how pouring could’ve been improved to avoid some clumpiness.
Even this point stayed in same position as silk was strong enough (had proper support) to dry as such.
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Stage 2 Material Experimentation Trial 3
Material Exploration Portfolio
Specific Fabrication Approach: Casting Materials Used: Foam & Wooden Sticks
Random Exploration of Materials’ Relationships Change of Direction in Thought Process
20 Material Exploration
Creating a “Cascade” Effect
Materials Used No Boundary
I didn’t think enough of what I’ll do with the toothpicks I’ve put, after the paste would dry. I was trying to experiment something different, with boundaries at some areas, and others not to see the effect of putting restrictions. I wanted to create a somewhat dripping effect to capture “water effect in motion” like a waterfall/cascade.
Boundary No Boundary
Result and Reflection:
Overall Reflection:
I continued developing by uing the casting technique in trial 1, resulting in cracking due to interference with my hands when pouring. I then used a different technique using silk inspired by the previous cable net precedent, which resulted in the most smooth outcome. Lastly, the last trial was experimenting something without much thought or objective as I wanted to get slightly out of the box, resullting in a good shape with the proper restraints I created below, and formwork was successfully removed, yet there was no connections between the three small forms.
It took good shape after formwork was removed, there were no connections between the cast so it was a very weak idea. Fall 2022 Fall 2022
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Forming a Single Panel Design Using Different Alterations of Parameters
Project
Workflow Diagram
1.3: Parameters Deduced &
03
Setting Free
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Sketch of Concept on Selected Panel
Stage 3 Parameters Deduced & Workflow Diagram
Material Exploration & Concept
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Number of Concave Curves Distance Between Each Curve Curve Wavelength Width & Length of Surface Surface Thickness
Parameters Height of Curves
Chapter name Portfolio 28 C ea e a P ane Chang ng Numbe o Po nt Ve ca y & Ho zon a y O u t p u t s Spec ed Po n Spec f ed W dth Spec ed Length C eate a P ane Chang ng Numbe o Po n Ver ca y & Ho zonta y O u t p u t s Spec ed Po n Spec ed W dth Spec ed eng h Workflow Diagram Specified Width Specified Length Specified Point Specified Width Specified Length Create a Plane Changing Number of Points Vertically & Horizontal Larger Rectangle Size (X & Y) --> Narrower Curves Become Larger U/V Count (Greater Points in X and Y Direction) --> More Oscillations Curves) --> Greater Height of --> Shorter Wavelength Parameter Alteration: Width & Length of Surface Parameters Alteration: Curve Wavelength
Student Name ARCH 473/3522 - Spring 2019 29 Numbe o Po n s n X D ec on Numbe o Po n s n X D ec on Nu
(Greater Number of Direction) (Number of Curves Wavelength
Number of Points in X Direction Number of Points in Y Direction Domain Start (Minimum) Domain End (Maximum) Divide Surfaces into Points Create Curves by Altering Points Construct Domain Parameters Alteration: Height of Curves Parameters Alteration: Distance Between Each Curve Parameters Alteration: Number of Concave Curves (with void)
Greater Domain End (Constant Domain Start) ---> Less Wavelength (More Narrow) Greater Domain Start (Constant Domain End) --> Decrease in Curve Height
Translation of Workflow into Grasshopper
Parameters:
Surface Width & Length Curve Wavelength Curve Height Number of Curves Distance Between Curves Thickness of Surface
Additional Parameters:
Spacing/Opening Between Strips Number of Horizontal Strips Number of Vertical Strips Width of Strips
Initial Draft with Random Command (Random Points
Modified Code with “Setting Free” Inspiration as Objective
Step 2: Dividing the Surface Into Segments Step 3: Deconstruct
Step 1: Select Rhino Surface on Grasshopper
Experimenting With U Count
The less the U Count is, the less the number of horizontal strips there are.
Chapter name Portfolio 30
Points Extracted for Initial Experimentation)
Edge 1 Edge 2
I then used List Item and Random Command to extract random points from the surface constructed. Objective Instead of Random Points Segments Deconstruct Brep Step 4: Divide Curve into a number N of equal length segments are.
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Chapter name Portfolio 32
5: Line Continuation of Translation of Workflow into Grasshopper
6: Point on Curve
7: Scale The Greater the Value is, the Greater the Distance is Between Each Curve
8: Loft Step 9: Remap+ Making Spacing Between Each Strip Descending As They Get Closed to Solid Areas Similar to Objective (Sketch) More Restricted/Closed More Open (Setting Free)
Step
Step
Step
Step
The Greater the Factor is, the Thicker the Strip is and the Less the Opening/Spacing Between Them Is
Overall Reflection:
We were required to deduce the main parameters from our selected panels before applying them on Grasshopper. After identifying which parameters I will be altering, I experimented with changing each variable to see how it affected the output and how the mix between more than one variable creates a completely different form. I started with using a Rhino surface which prevented me from being able to change the parameters easily, and so I changed my code to make it entirely on grasshopper with having my main parameters of height of the curve, wavelength, number of curves, thickness of surface, distance between each curve, and width/lenght of surface.
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Forming a Cluster Using Different Alterations of the Single Panel Design
Project 1.4: Forming a Cluster
04
Different Iterations of Single Panel Design Grasshopper Code
Chapter name Portfolio 36
Altered Code from Using Rhino as Initial Surface to Surface Made from Code of Grasshopper Surface Without Random Command
from Grasshopper (to alter more from initial curves’ parameters)
Creating Strips on Surface (No Change from Previous Code)
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Different Iterations of Single Panel Design
Dissecting Each Part of
D i f f e r e n t I t e r a t i o n s
D i f f e r e n t I t e r a t i o n s
D i f f e r e n t I t e r a t i o n s
the Code
O r i g i n a l
O r i g i n a l
O r i g i n a l
1) I changed the values of one “multidimensional slider” while keeping other two constant but it was too subtle or “calm” for the concept I was aiming for of “encountering multiple obstacles on the way before setting free”. 1 ) I c h a n g e d t h e v a l u e s o f o n e " m u l t i d i m e n s i o n a l s l i d e r " w h i l e k e e p i n g o t h e r t w o c o n s t a n t b u t i t w a s t o o s u b t l e o r " c a l m " f o r t h e c o n c e p t I w a s a i m i n g f o r o f " e n c o u n t e r i n g m u l t i p l e o b s t a c l e s o n t h e w a y b e f o r e s e t t i n g f r e e "
1 ) I c h a n g e d t h e v a l u e s o f o n e " m u l t i d i m e n s i o n a l s l i d e r " w h i l e k e e p i n g o t h e r t w o c o n s t a n t b u t i t w a s t o o s u b t l e o r " c a l m " f o r t h e c o n c e p t I w a s a i m i n g f o r o f " e n c o u n t e r i n g m u l t i p l e o b s t a c l e s o n t h e w a y b e f o r e s e t t i n g f r e e "
1 ) I c h a n g e d t h e v a l u e s o f o n e " m u l t i d i m e n s i o n a l s l i d e r " w h i l e k e e p i n g o t h e r t w o c o n s t a n t b u t i t w a s t o o s u b t l e o r " c a l m " f o r t h e c o n c e p t I w a s a i m i n g f o r o f " e n c o u n t e r i n g m u l t i p l e o b s t a c l e s o n t h e w a y b e f o r e s e t t i n g f r e e "
4 c
A l t e r a t i o n
A l t e r a t i o n
A l t e r a t i o n
A l t e r a t i o n
A l t e r a t i o n
A l t e r a t i o n A l t e r a t i o n
Alteration Alteration Alteration
A l t e r a t i o n A l t e r a t i o n
2 ) I s t a r t e d a d d i n g m o r e " m u l t i d i m e n s i o n a l s l i d e r s " a n d c h a n g i n g t h e v a l u e s o f i t , d e m o n s t r a t i n g m o r e m o v e m e n t t o t h e s u r f a c e , w h i l e k e e p i n g o t h e r c u r v e s c o n s t a n t .
2 ) I s t a r t e d a d d i n g m o r e " m u l t i d i m e n s i o n a l s l i d e r s " a n d c h a n g i n g t h e v a l u e s o f i t , d e m o n s t r a t i n g m o r e m o v e m e n t t o t h e s u r f a c e , w h i l e k e e p i n g o t h e r c u r v e s c o n s t a n t .
2 ) I s t a r t e d a d d i n g m o r e " m u l t i d i m e n s i o n a l s l i d e r s " a n d c h a n g i n g t h e v a l u e s o f i t , d e m o n s t r a t i n g m o r e m o v e m e n t t o t h e s u r f a c e , w h i l e k e e p i n g o t h e r c u r v e s c o n s t a n t .
( i
4 c ( i
3 ) I a d d e d a 5 t h m u l t i - d i m e n s i o n a l s l i d e r a n d i t a l m o s t h a d t h e m o s t s u i t a b l e m o v e m e n t I w a s a i m i n g f o r t h a t w a s s t i l l s u b t l e a n d n o t t o o m a n y .
3 ) I a d d e d a 5 t h m u l t i - d i m e n s i o n a l s l i d e r a n d i t a l m o s t h a d t h e m o s t s u i t a b l e m o v e m e n t I w a s a i m i n g f o r t h a t w a s s t i l l s u b t l e a n d n o t t o o m a n y
3 ) I a d d e d a 5 t h m u l t i - d i m e n s i o n a l s l i d e r a n d i t a l m o s t h a d t h e m o s t s u i t a b l e m o v e m e n t I w a s a i m i n g f o r t h a t w a s s t i l l s u b t l e a n d n o t t o o m a n y
Chapter name Portfolio 38
2) I started adding more “multidimensional sliders” and changing the values of it, demonstrating more movement to the surface, while keeping other curves constant.
4 c
3) I added a 5th multi-dimensional slider and it almost had the most suitable movement I was aiming for that was still subtle and not too many.
4 ) I d e c r e a s e d t h e X a n d Y d i m e n s i o n s o f t h e s u r f a c e , w h i c h i n c r e a s e d t h e h e i g h t s o f t h e c u r v e s a n d r e d u c e d t h e i r w a v e l e n g t h s , m a k i n g i t t o o d y n a m i c f o r w h a t I w a s a i m i n g f o r .
4 ) I d e c r e a s e d t h e X a n d Y d i m e n s i o n s o f t h e s u r f a c e , w h i c h i n c r e a s e d t h e h e i g h t s o f t h e d d d t h i l t h k i n g i t t o o d y n a m i c f o r w h a t I w a s a i m i n g f o r .
4) I decreased the X and Y dimensions of the surface, which increased the heights of the curves and reduced their wavelengths, making it too dynamic for what I was aiming for.
O r i g i n a l
5 ) I i n c r e a s e d t h e U a n d V c o u n t o f t h e D i v i d e S u r f a c e , w h i c h a l s o d e c r e a s e d t h e w a v e l e n g t h s a n d i n c r e a s e d t h e h e i g h t o f t h e c u r v e w i t h a s h a r p e r e d g e .
5 ) I i n c r e a s e d t h e U a n d V c o u n t o f t h e D i v i d e S u r f a c e , w h i c h a l s o d e c r e a s e d t h e w a v e l e n g t h s a n d i n c r e a s e d t h e h e i g h t o f t h e c u r v e w i t h a s h a r p e r e d g e .
5) I increased the U and V count of the Divide Surface, which also decreased the wavelengths and increased the height of the curve with a sharper edge.
Alteration Original Original
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A l t e r a t o n
Alteration
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(5) I increased the domain start and end and this same form was also achieved by increasing the domain start to 1000.
( 5 ) I i n c r e a s e d t h e d o m a i n s t a r t a n d e n d a n d t h i s s a m e f o r m w a s a l s o a c h i e v e d b y i n c r e a s i n g t h e d o m a i n s t a r t t o 1 0 0 0 )
( 5 ) I i n c r e a s e d t h e d o m a i n s t a r t a n d e n d a n d t h i s s a m e f o r m w a s a l s o a c h i e v e d b y i n c r e a s i n g t h e d o m a i n s t a r t t o 1 0 0 0 )
O r i g i n a l A l t e r a t i o n
6 ) I n c r e a s i n g t h e V C o u n t o f t h e D i v i d e D o m a i n i n c r e a s e d t h e s t r i p e s a n d t h u s e s p a c i n g b e t w e e n t h e s t r i p s m a k i n g t h e m o o t h w h i c h f i t m o r e m y c o n c e p t o f e a s i l y
D o m a i n i n c r e a s e d t h e s t r i p e s a n d t h u s e s p a c i n g b e t w e e n t h e s t r i p s m a k i n g t h e c e d g a s o o e s m o o t h w h i c h f i t m o r e m y c o n c e p t o f e a s i l y t o b e i n g s e t f r e e
Alteration
O i i l A l t e r a t i o n
O r i g i n a l
O r i g i n a l
Original Original Alteration
W h i l e t h e d o m a i n e n d i n c r e a s e r e s u l t e d i n i t s i n v e r s e s h a p e
W h i l e t h e d o m a i n e n d i n c r e a s e r e s u l t e d i n i t s i n v e r s e s h a p e
While the domain end increase resulted in its inverse shape
A l t e r a t i o n
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6) Increasing the V Count of the Divide Domain increased the stripes and thus decreased the overall proportion of the spacing between the strips making the spacing descending transition more smooth which fit more my concept of easily transitioning to being set free.
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...or to make it more realistic or less “proper” similar to how the bird flies (it goes through multiple stages), one panel can be decreasing in its width while the second panel can be flipped so it’s increasing.
Propagation of Single Unit into Cluster of Panels
Thought Process
The plan for the cluster was initially supposed to either be a clean set (meaning straight flat edges for the overall cluster from the length (long side) while only the width is dynamic showing the decreasing curves as if the strips in them are “setting free” after their encountered obstacles.
...or the whole cluster can be dynamic in which the edges of the entire system is curvilinear instead of straight .
Chapter name Portfolio 40 Material Exploration Learning from Materiality
Local Parameters Global Parameters
Surface Width & Length
Curve Wavelength
Curve Height Number of Curves Distance Between Curves Thickness of Surface
Spacing/Opening Between Strips Number of Horizontal Strips Number of Vertical Strips Width of Strips
Rotation of Panel Scale of Panel Array Type (Rectangular, Polar, Etc) True/False in Panels Angle Count
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Fall 2022 Fall 2022 ARCH 473/3522 - Fall 2022
Student Name
41
Propagation of Single Unit into Cluster of Panels Grasshopper Code
Chapter name Portfolio 42
G r a s s h o p p e r D e f i n i t i o n
Additional Part of Code for Cluster Forming
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Propagation of Single Unit into Cluster of Panels
Dissecting Each Part of the Code
1) Grouped Objects, Created Bounding Box as Union Box (to determine panel area) & Rectangular Array
Original
Alteration
2) Changing True/False in Panels Changes Their Direction
Parameters Changed: X and Y Dimensions of Array (X and Y Count / Number of Panels in X and Y)
3) Create another Bounding Box from Cluster List
Chapter name Portfolio 44
Student Name ARCH 473/3522 - Spring 2019 45
Rotate Panels
Scaling
Use
Array
Array
Custom
this
4)
5)
Scale Few Panels - Factor of 1.5 6)
Polar
Instead of Rectangle
7)
Preview & Color Swatch for Materiality & Color (Variations of
type shown in next poster)
Cluster Design Polar Array Count
Change in Count (decreasing value) of Polar
Polar Array - Angle
Addition of Angle Value of 90 degrees (constant is count of 10)
Change Angle Value (constant is count of 10)
Change Count and Angle Value
Chapter name Portfolio 46
Polar Array - Plane
Addition of Plane
Polar Array - Combining Parameters
Change Count (constant plane & angle)
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Continuation of Cluster Design
Rectangular Array - True/False Panels
Personal Reflection:
All True - no change of panels (rotated)
I aimed at making an array in my code initially after the rectangle surface I created as I wanted to be able to alter the local parameters on a global cluster scale, yet I would’ve had to unflatten the points and normal in the Divide Surfaces command and that would’ve removed the curves in my code, so my only option was to include the array at the end of my code which didn’t give me enough flexibility for local alterations in the cluster or to start a new code which is what I aimed at doing yet didn’t continue as I would’ve had to repeat many steps to achieve same old similar single unit.
All False - all panels changed
Mix True/False - Mix Changes
Chapter name Portfolio 48
Chosen Cluster:
The reason for this selection is that the overlapping of the curves on top of each other as they’re laid out on the z axis using the plane as an input gives a “growing” which is similar to the “diverging” concept. The remaining overlapping of panels portray the obstacles they encounter, yet in a manner of rhythm & flow, meaning they’re “setting free”. This is the closest cluster that resembles my concept until I can redo the whole code using an array (for clustering) to be included in the beginning of the code.
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Divide Surface Command (Flattened) in Grasshopper Code That Prevented Me From Having Flexible Alterations
Continuation of Cluster Design
Future Suggestions
Starting a New Code for Greater Flexibility in Cluster Design as I Had in Initial Single
Structure Competition. General
Towers https://mymodernmet.com/modern-architecture-2/ https://hbottlefield.com/universitas/chapter-3/sea-shell-buildings.html
Panel “Blossoming Dubai” to the Zaabeel Park Tall Emblem
Shape is Used for
Chapter name Portfolio 52 Material Exploration Learning from Materiality
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This is a shot taken on Enscape of the facade during it’s process where was still not enough variety visible in the openings.
Project 2.1: The Parametric Facelift
05
Stage 1 Double Skin Facade Research
Basic Concepts & Approaches Related to Double Skin Façades
increases efficiency of using solar energy
Precedents
https://www.sciencedirect.com/topics/engineering/double-skin-facade
Fig. 5 Classified According to Type of DSF Building
A double skin façade system includes the most advanced states of direct passive systems for maximum use of solar energy for providing a heat load & preventing thermal energy loss in buildings. It lowers thermal energy waste, increases efficieny using solar energy, has good facade sound insulation levels, creates reduction in heating and cooling consumption, and has high protection against air pollution. Regarding the double skin facades, the different types are box-window, corridor, shaft-box, and multi-storey (Fig. 5).
https://www.sciencedirect.com/topics/engineering/double-skin-facade
Fig
6.
Type of Air Flow in Gap
Box windows have single glazed external skin and openings allowing ingress of fresh air & egress of vitiated air, ventilating intermediate space & internal rooms cavity commonly used in situations in high external noise levels. The corridor type of façade has a cavity separated storey by storey with bulkheads and air is exchanged either vertically at floor level, horizontally at corners of building, or both vertically & horizontally. The shaftbox has an intermediate space between inner & outer layers and is adjoined vertically & horizontally by number of rooms. Its ventilation occurs via large openings near ground floor & roof.
...creates a suitable thermal resistance between inner & outer environment of building, and heated air in middle part is naturally used by opening windows on inner skin. Learning from Materiality
Chapter name Portfolio 56 Material Exploration
Technique
During the heating period, the façade space closes at the top & bottom to optimise solar energy gains. The multi-storey type has a cavity that is not partitioned either horizontally or vertically, forming one large volume. It also has an outdoor façade that’s composed exclusively of pivoting louvers rather than traditional monolithic façade with openings. The double skin facades also vary dependent on the type of air flow in the gap (Fig. 6), in which type A (Open Natural Convection) is air circulated in the middle cavity due to buoyancy effect, the entrance of air is located in lower part of outer skin or on its lower surface, and the exit is located in the upper part of the outer skin or on its upper surface. This creates a suitable thermal resistance between inner & outer environment of building, and heated air in middle part is naturally used by opening windows on inner skin. Type B (Closed Natural Convection) works by natural convection, but the air is trapped in space between two crusts since thermal flows of inner & outer crust are different, air circulates naturally in middle gap. Natural ventilation does not happen in this method because of the closed middle cavity. The last type (Forced Convection) has air heated in the middle gap sent to room space or building entrance with a fan and the system acts as a preheater for the air.
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Stage 1 Double Skin Facade Research
Environmental Performance Especially in Hot Arid Climates
increases efficiency of using solar energy
Precedents
https://www.sciencedirect.com/topics/engineering/double-skin-facade
Fig. 7 Cold Climates
In hot climate, the double skin façades introduce excessive glare at certain times of day. The solutions are solar shading systems, louvers as a solar shading techniques, and horizontal louvers for providing solar shading in south facades (hot & Mediterranean climates). Double-skin façades are adaptable to cooler & warmer weather. It is this versatility that makes them so interesting: through minor modifications, such as opening or closing inlet or outlet fins or activating air circulators, the behavior of the façade is changed.
https://www.sciencedirect.com/topics/engineering/double-skin-facade
Fig. 8 Hot Climates
The affected design parameters are shape, position, size, inclination angle distance from facade, shape, color, & material. In cold climates (Fig. 7), the air buffer works as a barrier to heat loss. Sun-heated air contained in cavity heat spaces outside glass, reducing demand for indoor heating systems. In hot climates, cavity vented outside building to mitigate solar gain & decrease cooling load. There’s excess heat drained through chimney effect process (differences in air density create circular motion causing warmer air to escape). As air temp. in cavity rises, it’s pushed out, bringing breeze to surroundings while isolating against heat gain.
...creates a suitable thermal resistance between inner & outer environment of building, and heated air in middle part is naturally used by opening windows on inner skin.
Portfolio Learning from Materiality
Chapter name Portfolio 58 Material Exploration
Different Approaches for Design & Operation of Relevant Double Skin
Application in Own Design
In this example in Geneva, Switzerland, simulation results on photovoltaic power production & building energy consumption was extracted, achieving total energy savings of 56% compared to no shading case & 24% compared to fixed louvers case and a reduction in electricity consumption compared to fixed louvers case by 8.9%. The parameters used for the energy simulation inspired me to also put a set point of temperature in which my facade can close or open when it reaches this limit so the facade can be responsive to the temperature.
https://www.sciencedirect.com/science/article/pii/S2095263516300048#f0030
Approach 1:
The Adaptive Solar Facade Design Process
https://www.sciencedirect.com/science/article/pii/S2095263516300048#f0030
Mechanical Process & Simulation Results
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Precedents
https://www.sciencedirect.com/topics/engineering/double-skin-facade
System & Control Type: Light SensorsCentral Control Design Purpose: Shading by External Façade Elements Element Material: Metal Track & Sun Screen
Kinetic Strategy: rotational kinetic shading strategy via solar tracking movable sun screen that rotates around top floors of circular building, designed to be photovoltaic shade screen, & its motion is responsive to sun ray’s movement around building throughout the day.
Stage 1 Double Skin Facade Research
Relevant Examples and Precedents
This solar responsive facade has triangular forms of windows limit glazed area to 1/4 of wall surface keeps the heat in, while triangular-shaped openings let in light where needed most—near ceiling and adaptive ventilation, adaptive lighting, interactive heating and cooling systems, and effective daylighting. The Shari-f-ha House has its system & control type motorized mechanism & BMS control, the design purpose is building movement shading element and the structure is steel .
Sharifi-ha House, Iran
https://www.sciencedirect.com/topics/engineering/double-skin-facade
Chapter name Portfolio 60 Material Exploration
increases efficiency of using solar energy
Kuggen Building, Sweden
https://www.sciencedirect.com/topics/engineering/double-skin-facade
The kinetic strategy is that the building volume can open & close in response to solar radiation through movement of motorized sliding & rotating mechanism of three clarified rectangular blocks. Regarding the critique of affordances and limitations of double-skin facade systems, they have much higher initial cost of construction, space consumption, maintenance demand, may fail to function properly if context changes significantly (shading by other buildings, for instance), fire protection is an issue, reduction of rentable space, extra maintenance and operational costs, overheating issues, higher air flow velocity, more weight to structure, daylight hindrance, and acoustic insulation.
https://www.sciencedirect.com/topics/engineering/double-skin-facade
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Fall 2022
Precedents
Stage 1 Double Skin Facade Research
Basic Understanding of Relevant Technical Details
increases
efficiency of using solar energy
This double skin facade allows for stack ventilation and the concern tackled was to block sunlight in summer coming from east, south, west facades (and horizontal shaders to block south light) & allowing sunlight to enter from same facades in winter to warm up internal space..
Basic Analysis of Site Conditions & Environmental Factors
Most Needed Design Strategies:
Internal Heat Gain (32.2%)
Use of natural ventilation cooling (21.8%)
Passive solar direct gain high mass by 12.9%
Chapter name Portfolio 62 Portfolio Material
Exploration
https://www.sciencedirect.com/topics/engineering/double-skin-facade
Technique
In summer during September-May, primary wind direction is North & North West while secondary wind direction is North East. Primary wind speed is North/North West & secondary wind speed is South West
In winter, primary wind direction is North - North West & secondary wind direction is North West.
Insufficient sunlight in December & shading is needed during July, August, September, October & November. During Winter, sunlight is needed & during April, May and June, shade is needed due to amount of heavy sunlight. Increase in natural ventilation is needed & need to reduce heat gain, humidity, & direct sunlight.
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Fall 2022
Single Panel Original Design
Stage 1 Double Skin Facade Research
Conceptual Idea for Design of Double Skin Façade & Choice of Operational Mechanism of Facade (Static/Responsive)
Cluster Design
(recalling that for proper clustering with alterations of each single form/panel, new complex code should be done from scratch)
The height of curves can increase or decrease, allowing either more or less sunlight to enter the building. Curve can change directions towards needed wind (like in the first row) or change direction away from sun during summer (like in the second row) or change direction towards sun during winter (like in the third row).
Chapter name Portfolio 64
Responsive System Inspiration 1
The wavelength of curve can also decrease or increase depending on environmental surrounding if too much heat is sensed from outside during summer, wavelength can decrease to block heat gain if too much cold is sensed from outside during winter, wavelength can increase to allow in more heat that can be preserved.
Responsive System Inspiration 1
I was inspired by both inspirations and started creating this sketch in which the curve closes when the sun hits and opens during wind entering.
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Forming a Double Skin FacadeStatic or Responsive Design
Project 2.2: Parametric Design Strategy and Modeling
06
Stage 2 Derived Parameters, Rules, Relationships from Previous Experimentation
Specified Point Specified Width Specified Length
Create a Plane
Parameter Alteration: Width & Length of Surface
Changing Number of Points Vertically & Horizontally
Number of Points in X Direction Number of Points in Y Direction
Parameters Alteration: Curve Wavelength
Divide Surfaces into Points Create
Parameters Alteration: Height of Curves
Parameters Alteration: Distance Between Each Curve Parameters Number
If too much heat is sensed from outside during summer, wavelength can decrease to block heat gain.
If too much cold is sensed from outside during winter, wavelength can increase to allow in more heat that can be preserved.
Environmental Effect: Closing/Opening Curve for Less or More Heat
Parameters Alteration: Number of Strips
Parameters Number
Chapter name Portfolio 68
Domain Start (Minimum) Domain Start (Maximum) Specified Depth of Curve Curve Angle
Construct Domain
Curves by Altering Points
Parameters Alteration: Number of Concave Curves
Parameters Alteration: Curve Extrusion (Depth)
Parameters Alteration: Curve Rotation/Direction
Parameters Alteration: Number of Folded Curves at Given Point
Environmental Effect: More/Less Shade
Environmental Effect: Allowing/Blocking of Wind
The curve can change directions towards needed wind or change direction away from sun during summer or change direction towards sun during winter.
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Wind from North & North West
Curves will usually be opened here to allow for wind.
Extruded Curves During Hot Sun for Shade & Decreased Spacing During Hot Sun for Shade & Increased
Material Exploration Learning from Materiality
Portfolio 70
Chapter name
Stage 2 Specific Strategy Adopted for Para
metric & Generative Exploration Exercise Spatial Design from Inside
Student Name
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2019 71 Fall 2022
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to Allow Cool Air to Enter
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Increased Spacing
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Precedents
(Schinegger et al., 2012)
Stage 2 Achieving Variation & Complexity Via Selected Strategies
This double skin facade has 108 kinetic louvers supported at top and bottom edge of façad. The lamellae is glass fiber reinforced polymers (GFRP) (high tensile strength with low bending stiffness, creating large reversible elastic deformations. The louvers are moved by actuators on both upper & lower edge of GFRP blade which induce compression forces to create complex elastic deformation. (This is what I was inspired by in my design as I’ve did a simplified version of this structure though simple pipes on Grasshopper). They also reduce the distance between two bearings which then induce bending.
The actuator of the louvers are the screw spindle driven by a servomotor and there’s a computer controlled bus-system that allows the synchronization of actuators. Each lamella addressed individually within specific logic of movement shows different choreographies & operation modes. The technical concept consists of elastic deformation, adaptive pre-stress, and energy retrieval. The master control unit is navigated by the computer getting information related to wind data, choreography & interior lightning requirements (Schinegger et al., 2012).
(Schinegger et al., 2012)
Chapter name Portfolio 72 Material Exploration
One Ocean, Yeosu
Learning
Materiality Portfolio
from
(Schinegger et al., 2012)
(Schinegger et al., 2012)
(Schinegger et al., 2012)
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Stage 2 First Attempt in Grasshopper to Devise Logic of Facade
Parameters Experimented: Coordinates of Each Curve
Parameters Experimented: Boundaries of Curves Parameters Experimented: Number of Rows (Floors)
Parameters Experimented: Number of Rows (Floors) & Columns
Chapter name Portfolio 74 Learning from Materiality
Experimented: (Floors) & Columns
I have to go back to my old code and see what commands I used to create the descending spacing between the stripes to follow my original concept of “setting free” gradually through having the spaces increase gradually.
Parameters Experimented: Number of Vertical and Horizontal Divisions
Reflection:
Parameters Experimented: Cull Patterns (Space Between Each Strip as a Pattern Instead of Value or Range of Ascending/Descending Values
It felt like I was restricted at first to edit the slabs or heights of the building, however it turned out that we can change them based on our own facade design and thus in the next stage I was able to have my mind more open to that instead of having stacked rooms. So far I wanted my operational mechanism of the façade to be responsive yet I’m still experimenting with how that can be possible with my code and design. I still have the structure (actuators) kept in my mind as I want to also my facade attached from its top and bottom with a similar kind of structure.
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2019
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Double Skin Facade in Progress
At a Different Angle
Project 1.3: Parametric Modelling
07
Precedents
Stage 3 Spatial Concept in Progress & Grasshopper
We were required to demonstrate our attempts in Grasshopper to represent the full logic of the building façade skin and how we utilize our parametric strategy to propagate the initial design module/unit throughout the whole building façade. We are required to map this on the Rhino model of the existing building, which should also comprise our spatial/interior modifications to illustrate our overall intervention.
As shown in the diagrams, I re-designed the height of my spaces depending on their function, their privacy and what kind of noise level the user inside would prefer which would affect my decision of making them at a higher or lower floow level. I tried to relate this to my initial concept of “setting free” by making the floors become more double height as they go up. I focused mainly more on the spaces’ neeeds in these sketches more than the environmental connections.
Chapter name Portfolio 78 Material Exploration
Learning from Materiality
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Stage 2 Initial Form in Progress After Adding Stripess
For Further Improvement:
Increasing Strips in West (sun angles are low) Increasing Between Strips
Environmental Effect: Vertical Shading; allowing light, views, ventilation (while excluding sun)
Chapter name Portfolio 80
Student Name ARCH 473/3522 - Spring 2019 81 Improvement: Spacing Strips in West Decreasing Spacing Between Strips in South Environmental Effect: Shading (blocking of sun) due to high sun angle
Learning
Materiality Portfolio
Altering Domain Maximum of Remap Altering Domain Minimum of Remap
from
Domain of Application Stage 3 Initial Form in Progress After Adding Stripess Parameter 1 Changing Spacing Between Stripes
Plans
Changed Curve Locations to Reach Closest Current Outcome of More Vertical Louvers to West & Less Stripes to South
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Precedents
Domain of Application Stage 3 Continuation of Building Facade
Progress of Spatial Configurations, Sections, Plans
I was stuck in the phase of spatial configurations and it’s relationship with the environmental factors or at least one chosen main factor. I extracted sections from the South and the West to start beginning to see the effect of the facade shape on the inside to create further connections.
Suggestion to Self: shift surface to left to make curves attached to slabs with structure.
Chapter name Portfolio 84
Learning from Materiality
Closed Openings of Strips --> Private Meeting Rooms Gradually Descending Openings --> Less Private Conferences Increasing Openings --> More Public Spaces (ex: event hall) Increasing Openings --> More Public Spaces (ex: exhibition) Sun Blocking for Heat Loss in Summer Sun Allowing for Heat Gain in Winter Lighting Pattern (Interesting Shade on Interior Floor)
Reflection:
I did not know how to improve on my facade or how to diversify the slabs or even the actual complexity of the facade itself as I was thinking that it’s too simple with not even parameters to play with. Thus I attempted to think of more ideas such as”squinching” some strips to create one large opening between stripes when needed for extra daylight or heat. However, it wasn’t the greatest idea as it would’ve unnecessarily made the facade more complex for the sake of creating complexity rather than an actual justifcation. ARCH 473/3522 - Fall 2022
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West Section in Progress
Priv Meeting Rooms
Public Meeting Rooms Public Terrace
Cafeteria & Social Space (Normal Height due to closeness to unite people)
little opening between stripes to feel safe & semi-private --> comfortable
Precedents
Double Height Area Large Conference Room & Event Hall (a lot of sunlight and material lighting)
duct
Stage 3 Continuation of Building Facade
Section & Plans in Progress
Domain
Section
Reception & Lounge
curve near slab not allowing a lot of sunlight as not needed for duct location
West --> allowing in lots of sunlight
curve near slab not allowing a lot of sunlight as not needed for duct location
Reception & Lounge
I started importing my facade from Rhino to Revit as a mass so that I can start creating my slabs directly from Revit then exporting it back to Rhino as I was more flexible with this since I can easily select the outline of the facade where it touches the slab to help me in creating the exterior of the slab. However, I was still confused on how to make the plans look more diverse and have more variety. The west section included more annotations than the south section as I had already spent too much time working on one section (it was hard to extract ideas and connections at this phase).
Chapter name Portfolio 88
`
Level
Duct Duct curve near slab not allowing a lot of sunlight as not needed for duct location curve near slab not allowing a lot of sunlight as not needed for duct location 0.5 West > allowing in lots of sunlight suitable as a terrace due to shade in the morning in West Large Terrace Small Terrace Private Meeting Rooms Public Meeting Rooms facade here serving as a wall Cafeteria & Social Space (Normal Height due to closeness to unite people) little opening between stripes to feel safe & semi-private > comfortable Reception & Lounge Reception & Lounge
Technique Level 1 0.0 Level 2 3.1
5 12.3 Level 6 15.4 Level 7 18.4 Level 8 21.5
Learning from Materiality
South Section in Progress Reflection:
I creates openings for the entrances and started using importing the facade from Rhino as a mass to Revit, drew the outline of the facade in interior to either fit exactly the slab like a puzzle completing one another & have the facade be served as a wall, or have a curtain wall that’s offsetted from the facade, allowing for space to create terraces wherever suitable.
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of Application
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Entering the VR Lab with This View
Technique
Project 2.4: Final Stage
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93
“Before”
Stage 4 VR Shots
Small Terrace Slab Needs Structure With Facade
Double Height Attempt
Reflection:
The openings of the facade were too little and thus didn’t show enough variety, therefore it needed greater opening or at least the pattern of having descending voids between the strips at each concave curve can be more emphasized. The structure also needed to be added even though I’ve already made the code for it. I also needed to create a more interesting interior experience. The previous section I’ve done in the West also doesn’t seem to be applied during the VR shots, as it showed a way moroe simplified version of it that needs to be worked on.
Chapter name Portfolio 94
Learning
Materiality Portfolio
from
The curtain walls are not touching the roof (slab above) and the rectilinear language isn’t fitting with the curvilinear facade.
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Stage 4 Grasshopper Code for Environmental Analysis)
Chapter name Portfolio 96
Student Name ARCH 473/3522 - Spring 2019
Original Design
Stage 4 Environmental Analayses
Original design had openings well suited for such indirect lighting here. There is little solid area with few openings.
Sunlight Analysis
Using grasshopper, the number of hours of direct sunlight received by the facade using sun vectors from the sunPath component was studied. Black represents least amount of direct sunlight and white represents the most.
Precedents
Chapter name Portfolio 98 Learning from Materiality
Precedents
Automated Adjusted Design Based on Simulation (Increase in Openings at Lowest Radia
tion (Black) for More Indirect Sunlight
Automated design based on simulation made the facade more protruded inside which provided the same aspect as old design yet wasn’t as aesthetically pleasing.
More wider openings created based on simulation to allow for more indirect sunlight (as this area was black).
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Changing Design Manually
Stage 4 Environmental Analayses
I struggled to make the curves in my facade more customized on Grasshopper as I attempted to do a design that’s extracted automatically through Grasshopper based on the simulation of solar radiation, yet it didn’t effectively work on my facade.
Reflection:
This was another attempt to have the darkest areas from the Radiation analysis extracted as data and be used to allow for openings of my strips to increase at these areas, however although it worked, the design created could be further improved aesthetically and to fit the spatial requirements.
Chapter name Portfolio 100
Radiation Analysis
Wind Rose Sunlight Path
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Using Automated Adjusted Design & Original Radiation Analysis to Create Own Design Decisions
I increased the size of the openings to allow in more heat and lighting as they weren’t as visible before.
Reflection:
A suggestion is to perform this analysis also on the slabs to see how the sun is affecting the users from within the interior space itself (having the double skin facade the context in this case and the slabs as the geometry input).
Learning from Materiality
Chapter name Portfolio 102
I’ve played with the graphs that change the coordinates of the curves in order to have more closed openings where it’s more radiated (white) to prevent excess heat gain in building during Summer (June-August) and have more openings in the black areas.
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Fig. 1 Facade in Default Size (Millimeters)
Fig. 3 Facade After Enlargement
Stage 4 Fabrication
Fig. 2 Enlarging Facade to Reasonable Printing Size
I started the fabrication process by exporting the facade from Rhino as an “.stl” file and importing it in Ultimaker Cura. The facade was automatically imported in millimeters. as default (Fig. 1), even though the units in Rhino is in meters. When I sliced it, the process was listed as 9 minutes as the duration for the facade to 3D print, which was what made me realize that there is an issue with the size. Therefore, I enlarged the scale of the facade to 400% (Fig. 2) to create a reasonable, logical size for the final real life product (Fig. 3). The adjusted total time process was then 5 hours and 10 minutes. With that reason, I started rotating the facade to investigate how it can affect the time process.
Chapter name Portfolio 104
Learning
Materiality
from
I kept rotating my model to see in which rotation will my facade print in the shortest time and the shortest time was 4 hours and 3 minutes.
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Stage 4 Plans, Sections,
Form
suitable as terrace due to shade in morning in West
West Section
Chapter name Portfolio 106
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107
I struggled in extracting sections and plans as I was iinitially working on Revit and built walls and curtain walls in the interior spaces, however the black cut would never show even though I’ve always worked with importing masses and making them show the black section cut. So, I’ve just used the Clipping Plane command on Rhino to extract my plans even though they’re plain and although I’ve had already added funiture on my Revit plans. I’m not that satisfied with the outcome of the plans and sections as even the structure I spent working on didn’t show in these drawings.
Chapter name Portfolio 108
Grasshopper Code for Making the Structure Connection Between Slab and Facade
Overall Course Reflection:
I really loved and enjoyed this course to be honest and it helped me create my main structure in my Vertical A project. I’ve even used the same similar structure that represents a “rib” kind of structure in the previous code shown above like the one I used also in my Vertical A project so I cam up with that code on my own based on my experience already which was surprising to me personally as I would always feel the need to ask a TA for help in Grasshopper. Although I feel like I’ve done relatively good progress in Project 1, I could have done way better in Project 2, yet I spent stuck in a long time trying to figure out whether my facade should be static or responsive (which turned out to be static). I could have also spent more time explaining which parts of the facade respect to which environmental parameter like the temperature and wind which is there but didn’t deeply explain it. The wide openings let in indirect sunlight and cool wind while the closed openings block high heat. Overall, I really loved this course and I’m super grateful I had this opportunity to take it.
Student Name ARCH 473/3522 - Spring 2019 109
Biblography
• https://www.semanticscholar.org/paper/Design-process-for-protot ype-concrete-shells-using-Veenendaal-Block/9ecb734bd541397e124e05208ca6ce84d783954a#paper-header
• https://www.holcimfoundation.org/projects/latex-formwork
• https://www.sciencedirect.com/science/article/abs/pii/S0141029614003344
• https://www.etsy.com/au/listing/398262649/metal-bird-mobile-4-piece-kinetic-art-in
• https://mymodernmet.com/modern-architecture-2/
• https://hbottlefield.com/universitas/chapter-3/sea-shell-buildings.html
• https://www.sciencedirect.com/topics/engineering/double-skin-facade
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