Nada Tarkhan Master of Design Studies- Energy and Environments 2016 Harvard Graduate School of Design
B.Sc Architectural Engineering American University in Cairo
B.Sc Architectural Engineering
Nada Tarkhan ntarkhan@alumni.harvard.edu / tarkhan.nada@gmail.com +1 (857) 253-8028 Date of Birth: Oct 13 1990 Nationality: Egyptian
01
02
03
04
05
06
07
Thermo-Structural Design Location: Luxor, Egypt
Living Office Location: New Delhi, India
Visitor Center Location: Aswan, Egypt
Quantitative Aesthetics: Illuminus Techology Installation Location: Boston, USA
Real Time Analysis of Shell Structures
Active Architecture: Thermal Panel
Daylighting in Schools Location: Rwanda
Location: Cambridge, USA
Location: Cambridge, USA
08 Net-Zero Design Location: Cambridge, USA
09
10
11
12
13
14
Eco-Tourism School Location: Western Desert Egypt
Structural Synchrony Location: Cairo, Egypt
EXPO Milano 2015: Bio Mediterranean cluster Location: Milan, Italy
Solar Decathlon Location: Datong, China
Magnetic Order Business Hotel Location: Cairo, Egypt
Sustainable Rehabilitation of Bath house Location: Cairo, Egypt
01 Location: Aswan, Egypt
Thermo-Structural Design
Designing the coupling Energy-based Designof structural tectonics and thermal flows This thesis explores the feedback loop that can be created between a structural system and a thermal scheme in order to develop a deeper understanding of the synergies and clashes between both systems. This project also investigates a multi-topology design language that capitalizes on an existing structural network to carry out selective thermal exchanges in a hot desert climate. The intention here is to tune loading distribution to thermal opportunities on several scales and merge the concerns of thermal and structural design. Multi-scale optimization is carried out to address the architectural implications of the union of both these fields. The tested design proposition works with a “less-mass� system, to tune the inosculation of flows in a thermal resistance scheme.
30% material Removal
60% material Removal
EXTRACTED TOPOLOGY 90% material Removal
A rectangular unit was studied, representing a single habitation. The form above displays the optimum form for load support by material removal
7
TESTING SAMPLE
STRUCTURAL-tHERMAL WALL
WALL PERFORATIONS
FINAL WALL DESIGN
The designed wall uses structural analysis and a thermal insulation model to combine both systems in a perforated wall assembly
8
SCHEMATIC DESIGN OPTIONS Possible Coupling of Structural and Thermal Systems on the scale of a single unit of habitation
Extracted Stress Diagram showing where material needs to be concentrated for stress minimization
ROOF SOLAR RADIATION
CELL SIZE CAN BE SMALLER AT BASE TO SUPPORT LOADS
POROUS STRUCTURE USED TO MAXIMIZE THERMAL RESISTANCE,
FIN GEOMETRY CROSS-SECTIONTO INCREASE DISSIPATION
OPPORTUNITY FOR LARGER CELL SIZES OR OPENINGS
HEAT EXCHANGER
STRUCTURAL INSULATION CHANNELS COMBINED WITH VENTILATION SCHEME
STRUCTURE AS HEAT EXCHANGER
STRUCTURE AS INSULATION
STRUCTURE AS VENTILATION (CHANNELS)
The conductive matrix that is an integral part of design for structural purposes is being assigned a thermal function The circulated water is used to dissipate the accumulated heat in the day. Different heat exchanger functions can be assigned on different sides- depending on orientation
Cellular porous geometry is used to maximize thermal resistance. Where the material needs to be allocated, the cell size is smaller. The challenge is in finding the right cell size for insulation power and stiffness. Decreasing cell size works better structurally because of the increase in material- whilst more material means higher conductance since insulation performance relies on increasing air volume
Spacing and sizing of channels for natural ventilation. Wind driven stacks integrated in faรงade Solar activated buoyancy channels for flushing out heat
STEP ONE Comparative strength analysis of honeycomb and triangle geometries
Maximum Stress : 1.5616e+6 Median Stress: 98314.214072 Average Stress: 199509.316333
Maximum Stress : 728466.849067 Median Stress: 144170.032783 Average Stress: 212754.885999
Maximum Stress : 916331.523283 Median Stress: 191905.487632 Average Stress: 238380.579992
Maximum Stress : 1.2162e+6 Median Stress: 121915.726789 Average Stress: 188592.130058
STEP TWO Optimum honeycomb cell size
Maximum Stress : 1.5106e+6 5cm cell size
Maximum Stress : 2.1523e+6 10cm cell size
Maximum Stress : 2.638e+6 15cm cell size
Maximum Stress : 3.5479e+6 20cm cell size
STEP THREE Optimum redistribution of material to strategically locate material for structural performance and minimize material for thermal resistance performance.
First stepping: Target material reduction= 30%
Second stepping: Target material reduction= 40%
Third stepping: Target material reduction= 40%
Optimization Penalization: 0.5
Optimization Penalization: 2.0
Optimization Penalization: 3.0
DESIGNING A STRUCTURAL INSULATING WALL Structural Analysis carried out on geometry, scale and distribution
Maximum Stress : 4.8725e+6 25cm cell size
3
CASTED PANEL
Wind/ Dead Load: 1/10
2
RUBBER MOLD AND FRAME
Wind/ Dead Load: 1/1
1 FOAM FORMWORK
FABRICATION A 1:1 cellular wall sample was fabricated for thermal testing Scaled Wall schemes were also constructed showing different load/force diagrams (wind and dead load)
1:1 Panel for Testing
THERMAL EXPERIMENT SETUP: HOT BOX U-VALUE MEASUREMENT The paenls thermal resistance was tested through u-value measurement. This was cross referenced to the calculated u-value for both one panel and 2 panels. The u-value decreased (and thermal resistance increased) as more layers were added. Using heat flux sensors the u-value of the solid concrete portion and the void (air) portion were calculated separately.
FABRICATION A 1:1 cellular wall sample was fabricated for thermal testing Scaled Wall schemes were also constructed showing different load/force diagrams (wind and dead load)
7
INNER TRANSLUCENT CONCRETE STRUCTURAL CELLULAR CORE
POLYCARBONATE SEPARATOR
STRUCTURAL CELLULAR CORE
OUTER TRANSLUCENT CONCRETE FOR LIGHT
ARCHITECTURAL REPLICABILITY: LIGHTWEIGHT HIGH-RISE CONSTRUCTION The same analysis technique could be used to design a cellular facade that both resists heat and suppports structural loads
02 Location: New Delhi, India July 2015 Group Work
Living Office: Designing a Ventilation Scheme IBPSA (International Building Performance Simulation Association) Competition Entry The aim of this project is to design and test a mixed mode ventilation strategy for an office building located in New Delhi, India. In order to reduce energy consumption and mitigate effects of high pollution rates, we chose to focus on a ventilation scheme that both operates naturally and filters the incoming air. Lighting design, airflow assessment and overall energy usage become integral indicators for design features such as façade design, interior arrangement, program distribution and material selection. The design needs to demonstrate that all these features operate under the ventilation scheme while reducing the overall energy demand. Simulation tools are used to test complex synergies of an idea in a practical scenario. Using these tools in their appropriate limitations, together in a comprehensive methodology, opens up possibilities of creativity in Design, not only functionality. Our explorations are in pursuit of a symbiosis between simulation and design.�
Building Design
Chimney: Buoyancy driven ventilation by introducing a ‘glass box’ as an ex tension of the existing shaft to maximize solar gains’ potential as pulling force.
18 people total
Lower occupancy in top levels as there are already high heat gains from solar radiation
24 people total
28 people total
Furniture materials and layout:Interior layout designed to balance side the spaces. The design, mate rial selection as well as placement of furniture is done so as to achieve a path of minimum resistance in the
Chimney: Optimized for maximizfor buoyancy driven ventilation performance
Sectional perspective with macro scheme
Construction: Using Rat-Trap bond construction technique for increased insulation and 30% material reduction. Glass type used is double low-e Ar-
Buffer Space: Layering of facade elements creates a permeable buffer from extreme hot and cold winds.
Facade: Titanium Di-oxide coated facade with native planters and climbers for naturally purifying incoming air from particu lates and harmful active gases.
Facade Scheme Multi-functional facade system. Serves as: shading device, green layer, pollution reducer, thermal buffer and for aesthetics. The resulting facade is a system of vertical porous members with increased surface area coated with Titanium Di-oxide paint along with a system of season-adjustable planters acting also as movable shading element. Titanium dioxide in the presence of UV light component of daylight reduces harmful polluting Nitrates and Sulphates into water and oxygen.
A’
A
ADMINISTRATION
CONVERTIBLE MEETING
PANTRY
VOID
Opening to chimney
proposed distribution points for mechanical ventilation
In order to assess the effectiveness of the ventilation scheme, an airflow CFD (computational Fluid Dynamics) model was created. This is shown above in a sectional cut through the office space. Higher speeds can be found near the openings and the solar chimney. This is an indication that buoyancy flows are in action.
2
03 Location: Aswan, Egypt December 2014 Group Work
Abu Simbel: Visitor Center Energy-based Design
Climate Analysis
Located in the South of Egypt, next to the temple of Abu Simbel, this visitor center capitalizes on the site‘s potentials to achieve a reduced energy load. The temple constructed in 1264 BC is a very significant monument that rests on a large stone mound. Many challenges are faced in this region, where high summer temperatures result in high cooling loads. Our evidence-based design strategies focused on ways to maximize solar intake in colder months while minimizing overheating in the summer. Energy, Daylighting and Ventilation Simulaations were all part of the design process.
Solar Path Latitude: 24 North
Temple of Ramses II
Wind Rose 24
Temple of Nefertari
18
N
Hrs 12 6 0
Division of Temples
Temperature Range
Recessed Inner water channels
Overhang for shading
Recessed doublelayered facade
Overhang for shading
Pool for evaporative cooling
Terracotta shading mashrabiya screen
Pool for evaporative cooling
Spine Circulation
Site Strategy
Berming to reduce energy consumption
Ramped Access
Shadow and Access Studies
Ventilation Outlets and Water Bodies
5
Energy Simulation Iterations Using Design Builder an assessment tool, different forms were modeled in order to reach the lowest EUI (Energy Use Intensity). Moreover, the temple mass was modeled to factor in the shadow cast on the building. The result was a bermed mass, where the surface area exposed to direct sunlight was reduced. This reduced the cooling load significantly. and helped in reducing the overall energy consumption. Other design stratgegies implemented included the use of evaporative cooling, clerestorey windows and local stone walls as thermal mass.
Evaporative Cooling Strategy
Lighting Analysis and Water Network
In order to optimize the daylighting strategy, DIVA daylighting simulations were caried out. The pink areas above represent overlit areas, while the blue represent under-lit spaces. Using clerestory windows resulted in a more even distribution of light within the space while the roof skylights were not as effective.
04 Location: Boston, USA Illuminus Light and Technology Festival October 2015
Quantitative Aesthetics: Real-Time CFD An Interactive Light and Technology Installation This project sets out to investigate the visualization of airflow based on computational fluid dynamics methods (CFD). The aim was to augment a sense, or rather bring forth an experience of airflow that is both highly visual and inaccessible to our senses. CFD uses numerical methods to both analyze and predict air flows in a steady state condition. Objects and people in a field disturb flow and create collisions and flow convergence. Energy driven designs use CFD as a tool to understand air and fluid behavior in space. Such methods are slowly materializing in the design discipline but are being deterred due to complexity and extensive computing time. These visualizations are also static and isolate themselves from the physical realm of interaction. Hence, we set out to bring this experience of flow to people through light. Our intention for this project was to bring forth intrinsic qualities of a CFD model and manifest them in three dimensional space such that they have a sensorial dimension. Instead of using complex simulation engines, we utilized coding to have access to the root equations governing fluid flow. The Installation was part of the Illuminus Light and Technology Festival in Boston and was exhibited in both Fenway Park and Boston House of Blues.
Installation in Boston House of Blues
Observers, objects
Kinect
CFD visualization Visualization varies with number of occupants
Experience of flow
Technological Setup
Installation in Fenway Park
Turtle: Real Time Analysis of Shell Structures
05
Interactive Structural Analysis
The aim of this project is to enhance the ability of designers to visualize and compute structural analysis within a short period of time. As a real time interactive tool, its intention is to familiarize people with everyday shell structures as well as assist in early stage form finding. Based on loading conditions that are inputted by the user, the shell structure is analyzed within the modeling interface and the user can mold the outcome as they wish to achieve the most optimal outcome. The loading conditions are inputted in the beginning of the analysis using color detection. The Kinect picks up this data as well as the modeling process and maps the analysis in real time on the object.
Location: Cambride, USA December 2015 Group Work
PROJECTOR
PROJECTOR
KINECT SENSOR
KINECT SENSOR
ANALYSIS GRID
ANALYSIS GRID
SHELL DETECTION REGION
SHELL DETECTION REGION
SUPPORTS
OBJECT FOR ANALYSIS
OPTION TABS
TENSION COMPRESSION ANALYSIS PROJECTED ON SURFACE
OPTION TABS
SETUP
ANALYSIS
Surface shell analysis, material selections and different colors assigned to wood, clay (modify thickness and material, modify the form to have less stress points and deflection) using Millipede- a structure analysis plugin developed by Panagiotis Michalatos and Sawako Kaijima
SHELL STRUCTURES The objects to be modeled are fabricated in advance before the analysis is projected. A few iterations of the same form family can be prepared
CONTROL PAD The control pad allows users to switch between the view type for display. For minimum information the nodes can be diplayed without the color gradient showing the structural analysis.
OPTIMIZED STRUCTURAL FORM After the kinect sensor picks up the depth data and form of the shell, an optimized is displayed here where the deflection of the structure is at its minimum value
3-D ANALYSIS VISUALIZATION The compression and tension analysis is displayed here in 3-D view. The user can rotate to view the shell structure from several angles
ANALYSIS GRID This grid is intended to project the analysis on the obbject as the user models in real time. Through color detection the sensor picks up the supports (red) and the loads (green)
levels of interactive visualizations: Structural Analysis: A color gradient is assigned to the detected surface based on the stress distribution both in plan view. The amount of stress is computed based on load conditions(quantity and position) and support conditions inputted in the system and is mapped on the object. Two main interactions can happen: - Adding loads - Removing loads by color detection 3D Deflection visualization: Based on the support conditions and computed stress, the system outputs a visualization of the potential/exaggerated deflection of the shell structure analyzed. This appears alongside the main plan view analysis. Stress Distribution: The analysis has an overlay of vectors that represent the stress vectors on every quad of the structure. This part of the analysis assists in narrowing down the areas that have a high concentration of stress and the direction of stress vectors. Optimization: Providing instructional assistance, this visualization computes the optimal shell shape based on the support locations, material and thickness inputted by the user. This is calculated once and is intended to provide hints for the user during the modeling process.
Analysis of Shell
Final form constructed using thermo-plastic
06
Active Architecture: Thermal Panel An experiment in Adaptive Regulation The aim of the project is to create a structural panel that exhibits thermal response and helps to regulate the indoor environment. This application focuses on a ÂŹflooring system that incorporates a structurally supportive geometry (honeycomb) and a phase change material that responds to temperature change. The metallic conductivity on the metal helps retain the temperature and aids in the stabilization of the phase change material. This enhances the energy storage capacity (in hotter temperatures) and energy emitting (in colder temperatures). The panel is calibrated based on the comfort range of 18C- 24 C of indoor environments. Through a series of tests, the substance and geometry was optimized. The project aims to have a visual dimension where changes in temperature and slab activation can be visible through thermochromic dye that changes color through temperature. That way the inhabitants can be more aware of their environments.
Location: Cambridge, USA November 2015
Cold Condition
Hot Condition- Panel shows change in color
Activated Slab changes color
13
Cell size= 2”
T= 5 mins
T= 10 mins
T= 15 mins
T= 20 mins
Cell size= 1”
PROCESS OF PHASE CHANGE
Thermal Experiemnts for Sructural and Thermal Optimization
6
07
08 Location: Cambridge, USA December 2014 Group Work
Net-Zero Design: Housing Re-trofit Energy-based Design
The re-design was carried out in the aim of upgrading the building’s envelope to both achieve significant energy reductions and perform better in terms of climate response. Existing buildings in the US represent a big portion of energy consumption. The challenge becomes in providing upgrades for exiting construction, rather than just new buildings where architects must be well-aware of a building’s performance. In order for this to be carried out effectively, it is necessary to evaluate all changes in terms of impact, benefits and quantifiable cost savings versus initial construction expenditure. The existing design was first analyzed and simulated to identify problems and potentials for improvement. Following this, strategies for improvement and assessments that inform the design decisions are carried out. Daylighting and energy simulations are used calculate predicted energy consumption and generation.
SUMMARY OF STRATEGIES
Daylight Availability Scores
Basement- 1.64 %
Annual Radiation Map
DAYLIGHTING
First Floor- 36.57%
Second Floor- 23.95%
Third Floor- 9.14%
Summer Operation
Winter Operation
During the summer months the Southern Double skin facade is opened to flush out the accumulated heat
During the winter months, the Southern sunlight is absorbed by the double skin facade. The double skin facade is closed to trap this heated air and help warm the house, reducing the heating load. An outlet to the interior circulates this heated air in the slabs.
The accumulated heat absorbed by the inner facade is re-used via a heat exchanger located below the foundation of the house
VENTILATION SCHEME
09 Location: Western Desert, Egypt Spring 2012 5th Year Individual Graduation Project
EcoTourism: Desert School Extrapolated growth of a desert node In a country utilizing only 5.5% of its land, the move to the desert in Egypt has been long overdue. A successful desert settlement must be established to set an example of what the future of urban planning can become in Fayoum Oasis. This project aims to use an Eco touristic site resource to provide an educational platform that would in turn offset the growth of a community and plant the seed for a much needed sustainable desert development. The school becomes the embryo of the community, connecting the two attractions, Wady Al Rayan and Lake Qarun. These connections become growth axis, opening up channels for agricultural development and making it the dominant mode of growth whilst forming an attachment to the arable 'desert island'. Within this agricultural expanse, the school acts as a medium for production and a catalyst for future development. The school aims to combine the three goals of Ecotourism; enhancing social welfare, raising environmental awareness and creating job opportunities. The program includes a range of composting and recycling spaces. Natural heritage and communal learning plazas act as pockets that stimulate social learning.
PROBLEM DEFINITION:
Environment
Building Fabric
Natural Ventilation Stack Effect Green Roofs Agricultural Land
Building Technology Cooling pads in walls Solar collectors Grey water system for irrigation/drainage underfloor clooling heating distribution systems
Stone for thermal Mass Interior courts Double paneled glass Wooden sheds Absorber surfaces Skylights Air outlets
Shading Devices North orientation Narrow plan Underground levels
ENVIRONMENTAL PLAN
Shaded Network of sheds
Agriculture Land extension of composting space
Deciduous Trees direct Natural Ventilation Shaded interior spaces
North Orientation maximizes exposure Ceiling Outlets daylight and Ventilation
Roof gardens cool spaces Below
Excessive immigration to Cairo Shale Stone obtained from site
PROPOSED SOLUTION
Consolidate eco-tourism in Western desert,Fayoum, to limit potential immigration
ARCHITECTURAL INTERVENTION
Initiate ecotouristic learning through school
Contextual Analysis: Fayoum Oasis, Western Desert, Egypt
Hawarra Pyramid
Qasr Qarun
Historical Learning
Qatrani Mountain
Whale Valley
Al Rayan Valley
Cultural and Social Learning
Lake Qarun
Environmental Learning
Eco-Touristic Development
Agriculture
Ecology Strip individual Rooms Natural Heritage Community learning
FLORA-LOW WATER CONSUMPTION
Halfa
MATERIALS
Level 2: Extrapolation of Existing growth axis (roads)
SITE VEGETATION
Level 1: New Community established between two main attractions
URBAN LEVEL
Lecture hall
Level 3: Planting planned node of development
tamarix
SHADING
palm weave
Permeability Studies: Axis/ Channels by which the design can be accessed.
wooden screen
MEDICINAL PLANTS
Palm trees
caraway (aromatic) INSULATION
strawboard
AGRICULTURAL/FOOD PLANTS
Aniseed
wall cooling pads
Fig trees
Olive trees
PRIMARY BUILDING MATERIALS
shale stone
rammed earth
Lower Ground experience: The design aims to introduce an unobtrusive feel to the surrounding setting by taking the students under ground rather than above. The lower ground level is supposed to expose the students to the whole project expanse while simultaneously opening them up to the whole surrounding environment. There are five plazas in the project that act as pockets of social interaction. They are connected through a network of circulation, linking all green spaces. Daylighting is maximized through this arrangement- those pockets dug underground also infiltrate the light into the project spaces. Shading analysis has proven that building height would not over shade and obstruct this lighting.
Daylight infiltration in underground level
Lower court
Social learning Plaza
Under bridge Platforms
Lower ground (-3m)
Ground Floor
Main Section A-A
First Floor
Sectional Studies summer
South Facade
East Facade Library study rooms
Roof vegetation Wooden Bridge Lower Level Study Zone
10 Location: New Cairo, Egypt Spring 2011 4th Year Individual Design Studio
Structural Synchrony: Hall of the People Transitional Dualities create Human Progress Based on literature analysis, this project merges text and architecture. Through the several analogies drawn, a statement was developed and manifested in a structural entity that guided the design of the "Hall of the People". This statement was a result of recognizing the dualities discussed in the studied text and how they shape behavior and alter motives- thus creating human progress. The idea of the hall of the people focused on themes that are in transition. In order to acquire knowledge on an individual level one must start off with physical individualism. We then progress into mental and social individualism untill we reach ultimate individualism- the spiritual Individual. The experience in each component was analysed and experiential models were constructed based on the degrees of enclosure and exposure desired in the space. The implications of structural response through a space frame system were tested.
2
The ground floor plan was designed as the base for the complex's experiential path. Inside, the user is exposed to the space frame members in various spatial applications. Hence the user becomes one with the building and all it has to offer from experiences.
First Floor Plan (Repeated)
Ground Floor Plan
Third Floor Plan
Knowledge
Exposed vs. hidden members
Nature
Collective
scale 1:10
The structure modules act as units of progression as the user enters the complex. The four keywords represent four stages of self actualization and represent different dimensions of individualism. Starting with Knowledge, a library becomes the first experience where the user interacts with learning.
The second learning experience is compromised of different social spaces within a Collective setting. Interaction with others brings forth the exchange of ideas and a type of growth on its own.
Individual
The third stage is where the user interacts with Natural elements, in the outdoor garden. This experience is key to spiritual development in the process of self actualization.
Reaching the highest point of the project, spiritual individualism is manifested in the form of Individual yoga and meditation room.
Experiential Models
The lowest level is where the auditorium is situated. Reaching the ground level, the library, cafeteria and offices can be found.
The First and second floor represent a mixture of experiences where the individual is placed in a more educational collective environment.
The Ground level is where the gardens and outdoor spaces are housed. This represents the height of social interaction.
The third level represents the height of individualism and is composed of individual meditation rooms.
11 Location: Milan, Italy Group Workshop September-October 2012
Expo Milano 2015: Cluster Design Feeding the Planet Energy for Life Cluster Design: The cluster aims to replicate and recreate a micro-Mediterranean city. Feelings, colors and flavors all merge together to create a unique cultural experience that is imprinted in the visitor’s memory. The design emphasizes on the elements of comfort and being at home where cultural boundaries are erased and reformed in the light of the newly merged cultural fabric. Materials: During the six month duration of the exhibition, a set of materials with both durable and aesthetic qualities are be selected. Concerning the units, a double skin system will be used. This will consist of an upper section composed of perforated metal panels and a lower section with polycarbonate installations. The upper perforated part will have the patterns of the units, creating an interesting composition of light within the interior space. Role in Project: - Designed Pavilion environmental “skin� - Presented project to expo jury as main team representatve - Collaborated in concept formulation The design was selected to represent the Bio-Mediterranean out of the three designed schemes and was built in September 2015
Expo Masterplan
Central court surrounded by pavilions
Cluster Arrangement
The skyline of the pavilions was designed to replicate the irregularities seen in mediterranean city skylines. The pavilion is double skinned to allow for the circulation of air between the unit layers. In almost all Mediterranean architecture, pattern becomes behavior, responding to the needs of occupants and controlling light. In this case, the facade permeability creates a unique interplay of light and caters to the ventilation needs of the pavilion.
O
“ ne can offset this excessive compulsion toward the spectacular with a return to simplicity� -Rem Koolhaas
Customizable Skin Pattern
Longitudinal Section
12 Location: Egypt, China 4th-5th year Group Project 2013- Research Assistant Position: Technical Coordinator and Project Manager
Solar Decathlon China 2013: Matchbox House An application of environmental response through parametric movable screens As an entry to the Solar Decathlon Competition in China, a house was designed by the team at the American University of Cairo. The competition challenges 22 teams world wide to design and build a solar powered house that can compete in all areas of design on an international level. This design was formulated under the name SLIDE-S (Sustainable, Livable, Interactive, DESign) and operates under a sliding matchbox configuration.This was done in the aim of optimising the building skin layers. Role in Project: Phase 1: Co-heading architecture team in formulating project concept and architectural design. Phase 2: - Leading team in Design and Project Scheduling - Coordinating Mechanical, Electrical and Plumbing designs - Conducting market analysis and contacting sponsors for equipment. - Communicating MEP developments to architectural team. - In charge of monitoring and and tracking all submissions - Main team Representative in China Workshop and Sponsorhip Presentations
CHINA 2013 WORKSHOP, DATONG
STEEL STRUCTURE FABRICATION,CAIRO
COMPETITION SITE-VILLA SOLAR-DATONG
PRESENTING DESIGN,CHINA
2
Structural Voronoi System
Screen-Sliding Mechanism
Screen-Egyptian Inspiration
Matchbox Configuration
Interior Shots
Parametric facade formulation
Project Drawings Weather Analysis-Datong, China Modeled to Datong China, August 2013
Average temperature: August temperature ranges from 25-30 degrees
Prevailing wind: North western orientation with an average temperature of 25 degrees
The Design was devised under an open plan configuration. All spaces spill into each other with a kitchen island located in the center. The Egyptian home has both public and private spaces, for this reason the bedroom area was elevated in order to enclose it as a more private space. The Living room area is adjacent to the screen opening, this gives the added option of creating an outdoor extension to the living room, semi-enclosed within the shed space. Solar Position Diagram: Aided in optimum solar panels location
Energy and Environmental Analysis Lighting Analysis
Average Daylight factor of the house for Datong,China. Under overcast sky conditions; the bedroom, study area and bathroom are not receiving sufficient daylight.
Thermal Analysis
Open screen configuration: Incident Solar Radiation. Artificial Lighting: Plan view of SLIDE-s artificial lighting illuminance at a reference plan height of 0.85m
Open screen configuration:Representation of 3D daylight luminance. Artificial lighting should be added and internal partitions should have high reflectivity values.
Luminance distribution: Artificial lighting compensates for areas where natural lighting was not sufficient.
Results:
Software:
The analysis above simulated the day lighting in the case of the open matchbox configuration (open screen) and the closed one. The Areas most exposed were the living room and the central kitchen area. The bathroom and bedroom however, were in need of artificial lighting. The second simulation represents the lighting condition after addition of artificial lighting.
ECOTECT RELUX PRO/RELUX Energy
Closed screen configuration: Incident Solar Radiation. Screen is especially effective during summer (June to August)
Open screen:Percentage shading
Daylight retrace, August 12:20pm
Closed screen:Percentage shading
Energy Institute Awards: London, England As an extension to the Solar Decathlon Project, the systems of the house were further analyzed. Several experimentations were carried out on the sliding screen structure, with regards to pattern, material and environmental quality. The entry was nominated for Environmental Excellence in the Energy Institute Awards in England and was chosen as one of the finalists for the award. Prorotypes of these screens were applied to facades in settlements in Egypt.
Screen Material Experimentation In collaboration with Sepia Textile Institute, Germany
In
Matchbox screen
Weave
In
Winter
Summer
Conical Weave
Tapestry Weave
The structural layer is composed of steel frames measuring 10cmx5cm. The frame has been modeled and digitally fabricated to follow the parametric “voronoi� diagram. Optimization has been carried out to ensure allignment with cells of the voronoi and desired house openings (doors and windows).
The sliding screen covers about 3/4 of the South facade and 1/4 of the north facde (in accordance to sun exposure). The screen is double layered so as to create two sliding entities- adding more flexibility to light control.
out
The susbstructure is fixed to allow for the insertion of the panels. Two kinds of materials will be used as infill; fiber cement panels and a new tested material that has been developed. The material is composed of agmen (a natural binding material) mixed with recycled straw bale.
In
out
The outer screen conforms to the same voronoi divisions and expanding circular perforations. The sections (above and below) represent the different scenarios and degrees of sun light achieved by different allignments between the 2 screens
out
In
out
Insulation must be used to shield the solid part of the house from heat gains during summer and heat loss during winter. VIP (Vacum insulated Panels) are an effective way to cater to the insulation needs of the house.
The open house plan allows for ease of air distribution. Ceiling exhausts will be used and will be housed within the false celing. Absorption chiler technology will be used to cool the house.
The glass segment of the house will be shielded by the perforated screen layer. However during winter months, the screen will be opened and the glass will be exposed. In order to optimize internal temperature, triple glazing will be used.
A grey water system will be used to treat water and reuse it in the toilet and irrigation deck network. Vegetation wil be installed within the deck landscape modules. The tank will be integrated within the outdoor wooden deck.
13
Magnetic Order: Business Hotel Shaping social spaces
Topography Configuration Location:6th of october, Sheikh Zayed, Cairo, Egypt 3rd Year Individual Design Studio
As a business hotel, this project aims to fuse a professional setting with a more open contextual experience. The concept of magnetism is adopted to shape the project elements and view circulation and negative space as a "field of interaction"- defining the scope of social behaviour. A desert climate also mandates an environmentaly conscious design-optimizing lighting performance, materials selection and internal environment. Surface analysis as well as interior path analysis is conducted to enhance the performance of all open spaces.
Streamlining topography allowed for easier integration with the building forms. The land lines intersect and shape the internal project platforms and levels-forming a seamless merge between site and mass.
Magnetism and block interplay
magnetism concept:
Magnetic Zones
Resultant fields of interaction
Platforms connecting sports & Business Center
Vertical Core
Eastern Elevation Roof Terrace
Ground floor experience
Core-central Platforms
Topography Lines intersect project levels
Main Entrance
The orientations of the individual blocks were designed to respond to light and wind as well as optimize the view from the bedrooms. 11
13
12 8 9
First Floor
7
10
4 5th Floor (typical Top BLock)
5 6
3
1 2 3 4 5 6 7 8 9 10 11 12 13
1 2
Ground Floor
2nd Floor (typical Middle BLock)
Lobby Seating Area Shops Restaurant Cafeteria Toilets Conference rooms Multi Purpose Hall Toilets Central Court and Platforms Shaded Outdoor Seating Sports Complex Surrounding Garden
(Ground Floor Plan)
Environmental optimization
Structural vierendeel truss System Overhang
- 8 Floors - 3 complexes-Hotel, Business Center,Sports center - Location:Cairo - Date: 1 July (hottest day)
Horizontal Shading Louvers
Shading Analysis
Seating Area Enclosure
9 am
12:00
3:00 pm
Roof Terrace
6:00 pm
Surface Analysis Annual Percentage Shading
Result: Pathway is shaded at all times and does not appear to be problematic.
Outdoor Garden
South Facade Ramps Connect levels
Main Circulation Zone
1.Wall Enclosure
Exposed zone
2. Shed Structure
1. This zone acts as a main circulation route and therefore needs to be adequately shaded.The above chart shows that annual shading doesnt fall below 40%.To enhance comfort two solutions are analyzed to limit direct sunlight.
2.
According to the above results, the wall enclosure (1) seems to be more successful in limiting direct sun exposure. It also offers a necessary enclosure to the project activities.
14
Thank you
Nada Tarkhan ntarkhan@alumni.harvard.edu / tarkhan.nada@gmail.com +1 (857) 253-8028 Date of Birth: Oct 13 1990 Nationality: Egyptian
gnireenignE larutcetihcrA cS.B