Al bahar

T
Twinkal JambuStudent at G. c patel institute of architecture
AL-BAHR TOWERS ABU DHABI.
AL-BAHAR ABU-DHABI,UAE ARCHITECT: Aedas Architects CONSTRUCTION COMPANY: Al-Futtaim Carillion FOUNDER: Council Investment Abu Dhabi YEAR OF DESIGN: 2008 YEAR OF CONSTRUCTION: 2009-2012 ROOF HEIGHT: 145.1 m TOP FLOOR HEIGHT: 120.0 m FLOORS: 27 + 2 basement levels LAND AREA: 100.080 m² FLOOR AREA: 56.000 m² 1
LOCATION: ABU DHABI, UNITED ARAB EMIRATES N CLIMATE: HOT DESERT CLIMATE HIGHEST TEMP:120 F 2
SITE ANALYSIS N Entry/Exit SITE PLANNING: TWO TWIN OFFICE TOWERS FACING SOUTH ARE PLACED ON SITE CONNECTED BY SKYWALK. SITE CONDITION :VERY HOT CLIMATE SO NEED TO CONTROL TEMP., TOWERS PLACED FACING SOUTH FOR MAXIMUM UTILISATION OF SOLAR ENERGY PRESENT IN ABUNDENCE. 3
PRINCIPLES • DESIGN PRICNCIPLE IS TO ACHIEVE A PERFORMANCE ORIENTED, CULTURALLY RELEVANT, TECHNOLOGICALLY ADVANCED, AND AESTHETICALLY INTRIGUING BUILDING. PLANNING • BASED ON SIX TANGENTIAL ARCS,TAKEN FROM THREE INTERSECTING CIRCLES • A PATTERN WHICH FORMS THE BASIS OF NEARLY ALL GEOMETRIC CONFIGURATIONS KNOWN TO THE REGION. 4
CONCEPT • THE DESIGN CONCEPT IS BASED ON THE FUSION BETWEEN BIO-INSPIRATION, REGIONAL ARCHITECTURE, AND PERFORMANCE-BASED TECHNOLOGY. • CIRCLES AND ORBITS ARE USED TO REFLECT THE CONCEPT OF UNIFICATION AND UNITY EVIDENT IN NATURE. • THE DESIGN IS DRIVEN FROM ITS CONTEXT, TAKING INTO ACCOUNT ENVIRONMENT, TRADITION, AND TECHNOLOGY • THIS INITIAL SKETCH ILLUSTRATES THE INTEGRATION OF THESE ELEMENTS. WHILE EACH DESIGN FEATURE OF THE AL-BAHR TOWERS IS INFUSED WITH THIS BALANCE, THIS ARTICLE WILL FOCUS ON THE DYNAMIC FACADE. • PETER OBORN DESCRIBES THE BEGINNING OF THE AL-BAHR TOWERS DESIGN: “WE WANTED TO CREATE A BUILDING WHICH WOULD SET NEW STANDARDS OF ENVIRONMENTAL RESPONSIBILITY, AND BEGAN TO EXPLORE THE EMERGING FORM IN ORDER TO STUDY WHICH PARTS OF THE BUILDING WOULD REQUIRE THE HIGHEST LEVELS OF SOLAR PROTECTIONWITH THE INTENTION THAT WE WOULD THEN DESIGN SOME FORM OF ‘MASHRABIYA’ TO SCREEN THESE AREAS BIO-INSPIRATION • “TO ABSTRACT IDEAS FROM BIOLOGY AND TURN THEM INTO PRACTICAL ENGINEERING SOLUTIONS REQUIRES ALL DISCIPLINES TO CONTRIBUTE.” (JOHN, CLEMENTS-CROOME & JERONIMIDIS, 2004) • TO GATHER AN INTERDISCIPLINARY TEAM AROUND COMMON DESIGN IDEAS WE FOUND REFERENCES IN NATURE TO WHICH WE COULD ALL RELATE. FROM EARLY ON THE INTENTION WAS SET TO EXPLORE BIO- INSPIRATION. • GUIDINGEXAMPLES WERE DRAWN FROM THE FORMS OF CACTUS, PINEAPPLES, FLOWERS AND OTHER NATURAL SYSTEMS. • A CACTUS HAS UMBRELLA-LIKE FEATURES TO PROTECT ITS DELICATE WEATHER-TIGHT SKIN. FLOWERS OPEN AND CLOSE IN RESPONSE TO CHANGING WEATHER CONDITIONS. THE PINEAPPLE’S HEXAGONAL ENVELOPE COVERS A DOUBLE-CURVED SURFACE EFFICIENTLY. WE SOUGHT TO EMBODY THESE ATTRIBUTES IN THE DESIGN OF THE TOWERS. 5
6
• THE DESIGN IS BASED ON THE CONCEPT OF ADAPTIVE FLOWERS AND THE "MASHRABIYA" - A WOODEN LATTICE SHADING SCREEN •A DYNAMIC AND SENSITIVE SHADING SCREEN ACTING AS' MASHRABIYA “ •SECONDARY SKIN FILTERS THE LIGHT AND REDUCES GLARE. •POWERED BY RENEWABLE ENERGY DERIVED FROM PHOTOVOLTAIC PANELS. •WRAPS GIANT LATTICE ALMOST TWO TOWERS COMPLETELY EXCEPT FOR THE AREA NORTH-FACING FACADES. SCREENS AL- BAHR TOWER SCREEN’S MODULE DESIGN ELEMENTS 7
•THE DESIGN FOR THE PROJECT BEGAN WITH TWO SIMPLE CYLINDERS, BECAUSE THE CIRCULAR PLAN GIVING THE MOST EFFICIENT FLOOR AREA USAGE WHILE ALSO CREATING THE GREATEST VOLUME WITH THE LEAST SURFACE AREA WHICH WILL HIGHLY REDUCE THE SUN EXPOSURE SURFACE AREA . FORM STRUCTURE ENVELOPE ADAPTIVE SOLUTION INTEGRATION STRUCTURE 8
Roof mounted Photovoltaic cells Translucent Mashrabiya appears cool and crystalline Sky Garden provides natural cooling effect Sky garden located in area of Max. exposure to reduce heat gain Sky garden reflects courtyard treatment provideing amenities space for users Hexagonal geometry – Islamic Architecture Mashrabiya - Makrana Islamic device creates a new Vernacilar Natural Optimised form Water feature to maximise evaporate cooling Shading effect similar to the form of nature Photovoltaic slopes southwards to maximise solar gain like leaf
• THE TOWERS FEATURE A DYNAMIC, TRANSLUCENT FACADE THAT OPENS AND CLOSES IN RESPONSE TO THE SUN'S MOVEMENT, REDUCING SOLAR GAIN ON THE FACADE BY UP TO 50%. • THE FACADE IS INSPIRED BY "MASHRABIYA", A FORM OF WOODEN LATTICE SCREEN USED IN ISLAMIC ARCHITECTURE AS A MEANS OF RETAINING PRIVACY WHILE SIMULTANEOUSLY REDUCING GLARE AND SOLAR GAIN. • TRANSLUCENT, UMBRELLA-LIKE COMPONENTS MAKE UP THE FACADE; THERE ARE 2,000 OF THESE "MASHRABIYA" COMPONENTS ON EACH TOWER. THE INSPIRITION FOR THE FACADE 10
THE FACADE ACCORDING TO THE SUN PATH HALF OPENFULLY CLOSED FULLY OPEN GRADIENT BASED ON SUN PATH11
•AS THE SUN RISES IN THE MORNING IN THE EAST, THE MASHRABIYA ALONG THIS SIDE OF THE BUILDING WILL BEGIN TO CLOSE, AND WHEN THE SUN MOVES AROUND THE BUILDING, ALL VERTICAL STRIP MASHRABIYA MOVE WITH THE SUN. •AT NIGHT ALL SCREENS FOLD, ALLOWING MORE OF THE FACADE. AL BAHR TOWER IN DAY TIME AL BAHR TOWER AT NIGHT OPERATION 12
Towers Al Bahar have implementation of advanced detection system designed to integrate the building with its cultural context and respond directly to the needs of the region's climate. ”Mashrabiya" in Al Bahar Towers has a number of components transparent umbrella that open and close in response to the sun's path. The effects of this system are comprehensive: reduced glare, improved daylight penetration, less reliance on artificial lighting, and over 50% reduction in solar gain, which results in a reduction of CO2 emissions by 1,750 tones per year. 13
• THE AL BAHAR TOWERS TOOK INSPIRATION FROM TRADIONAL ISLAMIC MOTIF TO DESIGN AN INOVATIVE AND VISUALLY INTERESTING EXTERNAL AUTOMATED SHADING SYSTEM. • THE DYNAMIC FAÇADE HAS BEEN CONCIEVED AS A CONTEMPORARY INTERPRETATION OF THE TRADIONAL ISLAMIC “ MASHRABIYA”( A POPULAR FORM OF WOODEN LATTICES SCREEN USED AS DEVICE FOR ACHIEVING PRIVACY WHILE REDUCING GLARE AND SOLAR GAIN. • CLOSED STATE PROVIDING SHADING TO THE INNER GLAZING SKIN. AS THE SUN MOVES AROUND THE BUILDING EACH • MASHRABIYA UNIT WILL PROGRESSIVELY OPEN. BUILDING WITHOUT SHADING SYSTEM BUILDING WITH SHADING SYSTEM (FINS) BUILDING WITH DYNAMIC SHADING SYSTEM14
TORRES - "COCOON BUILDINGS" • BASED ON A PRE-RATIONALIZED GEOMETRIC SHAPE, TUNED VIA PARAMETRIC DESIGN TOOLS TO ACHIEVE THE OPTIMAL RATIO OF SURFACE BETWEEN THE WALLS AND FLOOR. • FORM OF THE TOWERS IS OPTIMIZED TO COMPLEMENT THE SHADING SYSTEM. •THE DESIGN STARTED WITH TWO SIMPLE CYLINDERS, CIRCULAR, YIELDING THE MOST EFFICIENT IN TERMS OF "AREA-TO-FLOOR WALL", CREATING MORE VOLUME WITH LESS SURFACE. •THEN, A CIRCULAR SHAPE IS DIVIDED BASED ON A COMBINATION OF CIRCULAR GEOMETRIES TO REDUCE SOLAR EXPOSURE, AND IT STARTED TO GENERATE A NATURAL ORIENTATION. •THE SHAPE OF THE TOWERS WAS THEN SCULPTED AROUND THE CORE, NARROWER AT THE BASE AND AT THE TOP, WIDER AROUND THE INTERMEDIATE FLOORS. EVOLUTION 15
• EACH UNIT COMPRISES A SERIES OF PANELS STRETCHED PTFE (POLYTETRAFLUOROETHYLENE) AND IS DRIVEN BY A LINEAR ACTUATOR TO PROGRESSIVELY OPEN AND CLOSE ONCE PER DAY, IN RESPONSE TO A PRE- PROGRAMMED SEQUENCE THAT IS CALCULATED TO AVOID DIRECT SUNLIGHT TO FROM THE MOMENT IT HITS THE FACADE . • COMPUTER-CONTROLLED, • OPERATES AS A CURTAIN WALL, • READY TO TWO METERS OF THE EXTERIOR FACADE OF BUILDINGS, IN A SEPARATE FRAME. • EACH TRIANGLE IS COATED WITH MICRO FIBERGLASS • PROGRAMMED TO RESPOND TO THE MOVEMENT OF THE SUN. • IT IS AN ANCIENT TECHNIQUE USED IN A MODERN WAY • THE WHOLE SYSTEM IS PROTECTED BY A VARIETY OF SENSORS THAT OPEN THE UNITS IN CASE CONDITIONS CHANGE, OR RAISE TO CLOUD WINDS. • GEOMETRIC PATTERNS THAT MAKE UP THIS GIANT SCREEN INCLUDE MORE THAN 1,000 MOBILE ELEMENTS THAT CONTRACT AND EXPAND DURING THE DAY, DEPENDING ON THE SUN POSITION. ENGINEERING 16
PHOTOVOLTAIC CELLS • ROOFS FACING SOUTH EACH TOWER INCORPORATE PHOTOVOLTAIC CELLS. • GENERATING APPROXIMATELY FIVE PERCENT OF THE TOTAL ENERGY REQUIRED RENEWABLE ENERGY SOURCES, USED FOR HEATING WATER. • THE TOWERS HAVE BEEN ONE OF THE FIRST BUILDINGS IN THE GULF THAT RECEIVED A LEED SILVER RATING. • A BESPOKE APPLICATION WAS DEVELOPED USING JAVASCRIPT AND ADVANCED PARAMETRIC TECHNOLOGIES TO SIMULATE THE MOVEMENT OF THE FAÇADE IN RESPONSE TO THE SUN’S PATH. • THE PERFORMANCE CRITERIA AND GEOMETRY BUILD-UP OF THE SYSTEM DESIGN WERE CONVEYED USING A UNIQUE PROJECT SPECIFIC, GEOMETRY CONSTRUCTION & PERFORMANCE MANUAL. • THIS FREED THE DESIGN-TO-CONSTRUCTION PROCESS FROM LOCKING IT DOWN TO CERTAIN PLATFORMS AND COMPUTER TECHNOLOGIES AND OFFERED A UNIVERSAL DATA EXCHANGE LANGUAGE, ENABLING ALL PARTIES TO COMMUNICATE MORE EFFECTIVELY. DAYLIGHT ANALYSIS FOR SCREENS IN DIVA AND GRASSHOPPER 17
• IT IS ESTIMATED THAT THE SCREEN REDUCES SOLAR GAIN IN MORE THAN 50% AND REDUCES THE NEED FOR AIR CONDITIONING. • SCREENS ABILITY TO FILTER LIGHT HAS ALLOWED TO BE MORE SELECTIVE IN THE CHOICE OF GLASS. • THIS ALLOWS US TO USE MORE NATURALLY TINTED GLASS, WHICH ALLOWS MORE LIGHT INSIDE AND LESS NEED FOR ARTIFICIAL LIGHT. • THE INTELLIGENT FACADE, TOGETHER WITH SOLAR THERMAL PANELS FOR HOT-WATER HEATING AND PHOTOVOLTAIC PANELS ON THE ROOF, MINIMIZE THE NEED FOR INTERNAL LIGHTING AND COOLING, ALTOGETHER REDUCING TOTAL CARBON DIOXIDE EMISSIONS BY OVER 1750 TONS PER YEAR. • FOR THE PROJECT’S SUSTAINABLE ENGINEERING AND SENSITIVE CULTURAL AND URBAN APPROACH, THE TOWERS WERE AWARDED THE 2012 TALL BUILDING INNOVATION AWARD. EFFICIENCY 18
Wind A SERIES OF WIND-TUNNEL TESTS WERE CONDUCTED AT VARIOUS SCALES TO ANTICIPATE THE COMBINATION OF LOADS EXERTED ON THE BUILDING GENERALLY AND ON THE MASHRABIYA LOCALLY. BOTH SMALL AND FULL-SCALE MODELS WERE TESTED ACCORDINGLY. THE TESTS REVEALED THAT THE FLUID FORM OF THE BUILDING GENERATED RELATIVELY LOW +VE AND -VE PRESSURES, AVERAGING 1.5 kPa UP TO A MAXIMUM OF 3.5 kPa. A SINGLE DYNAMIC UNIT WAS LATER SUBJECTED TO VERY HIGH WIND SPEEDS UP TO 90 m/s, DEPLOYED IN DIFFERENT OPENING POSITIONS,WHERE THE RESULTING PRESSURES DID NOT EXCEED THE MAXIMUM FIGURES APPLIED ON THE BUILDING AS A WHOLE – DUE TO THE FLUID AERODYNAMIC GEOMETRY OF THE BUILDING FORM AND DYNAMIC MASHRABIYA SYSTEM. 19
Energy models evaluated the towers’ solar gains without external shading screens (Fig. 34). Theoretically, a shading screen should completely wrap the tower as direct solar rays hit the curtain-wall from all directions, especially during summer. The north face experiences direct solar rays only for a short time in the morning and later in the afternoon, i.e. before and after working hours. Shading units in the North zone was therefore unnecessary. Shading studies were used to explore the impact on energy performance of different Mashrabiya configurations. This figure illustrates the facade opening and resulting improvement in energy performance during mid-season at 9:00 am. CLIMATIC RESPONSE 20
MATERIAL EACH OF THE DRIVERS PLAYED A ROLE IN THE CHOICE OF MATERIALS FOR THE BUILDING ENVELOPE. • 1.4462 DUPLEX STAINLESS STEEL: ALL MAIN-FIXED SUPPORTING COMPONENTS LIKE CANTILEVER ARMS, YSTRUCTURE ARMS, AND BRACKETS CONNECTING THE SYSTEM BACK TO THE MAIN STRUCTURE ARE MADE OF DUPLEX STAINLESS STEEL, DUE TO ITS HIGH STRENGTH AND CORROSION RESISTANCE. ALL EXPOSED/VISIBLE COMPONENTS HAVE SHOT-PEEN FINISH, SIMILAR TO SAND BLASTING. THIS CAMOUFLAGES DUST AND SAND PARTICLES THAT SETTLE ON THE STEEL SURFACE. • PVDF COATED ALUMINIUM: ALL CURTAIN-WALL AND FABRIC MESH FRAMES ARE MADE OF EXTRUDED ALUMINIUM PROFILES. THESE ACHIEVE A FINER LEVEL OF DETAIL THAN POSSIBLE WITH STEEL. IT IS ROBUST, LIGHTWEIGHT, AND CORROSION RESISTANT, AND ELEGANT LOOKING WHEN FINISHED, IN THIS CASE IN A CHAMPAGNE COLOUR, AS IT RESEMBLES THE BEIGE COLOUR OF LOCAL SAND. • GLASS: CURTAIN-WALL VISION GLASS IS MADE OF DGU OF 40% VISIBLE LIGHT TRANSMISSION, 0.28 G-VALUE AND 18% EXTERNAL LIGHT REFLECTANCE. • TEFLON: ALL BEARINGS AND JOINTS SEPARATORS ARE MADE OF MARINE-GRADED TEFLON COMPONENTS. • SILICON: ALL SEALANTS/GASKETS ARE MADE OF BLACK SILICON – ESPECIALLY HIGHLY RESISTANT TO UV RAYS AND OTHER WEATHERING FACTORS. NOTE: THE SOLAR GAIN AND ENERGY STUDIES WERE INTENTIONALLY LEFT UNINFLUENCED BY THE MASHRABIYA. THE GEOMETRIC DEFINITION AND OPENING CONFIGURATIONS WERE THEN OPTIMIZED TO IMPROVE LIGHTING AND VISIBILITY. 21
AS GENERAL RULE OF THUMB, A SHADING ELEMENT IS MOST EFFICIENT WHEN IT FACES SOLAR RAYS DIRECTLY I.E. ORTHOGONALLY. • A SHADING ELEMENT MUST CAST SHADOW OF ALL ITS EDGES ONTO THE ADJACENT SHADING ELEMENT TO AVOID DIRECT SOLAR RAYS LANDING ON THE VISION GLASS BEHIND IT. • ON ONE HAND, HOWEVER, THE MOVING SUNLIGHT RESULTS IN SOLAR RAYS LANDING ON THE CURTAIN-WALL AT INFINITE ANGLES. • ON THE OTHER HAND, NOT ALL DIRECT SOLAR RAYS TRAVELLING INSIDE THE BUILDING AFFECT THE OVERALL PERFORMANCE OF THE ENVELOPE AS LONG AS THEY ARE LIMITED TO A BUFFER ZONE AROUND THE PERIMETER OF EACH FLOOR-PLATE WITHOUT LANDING ON THE WORKING DESK LEVEL AND IN THE EYES OF OCCUPANTS (FIG. 29). BOTH EXPERIENCE AND EARLY SHADING STUDIES USING VARIOUS OPENING CONFIGURATIONS OF THE MASHRABIYA SCREEN RESULTED IN DEVELOPING THE FOLLOWING PRINCIPLES TO CONTROL THE SHADING ELEMENTS PERFORMANCE:- • THE CONFIGURATION OF THE SHADING IS BASED ON OPTIMIZED CATEGORISATION OF SOLAR RAYS. • GENERAL SOLAR RAYS LANDING AT ANGLES BETWEEN 0 AND 79 DEGREES ONTO THE CURTAIN-WALL SURFACE REQUIRING FULL FRONT-COVER OF THE CURTAIN-WALL .THIS IS ACHIEVED BY AN UN-FOLDED CONFIGURATION. • INTERMEDIATE SOLAR RAYS LANDING AT ANGLES BETWEEN 80 AND 83 DEGREES ONTO THE CURTAIN-WALL SURFACE REQUIRING PARTIAL FRONT-COVER OF THE CURTAIN-WALL ALLOWING PARTIAL UNOBSTRUCTED VIEWS – THIS IS ACHIEVED BY A MIX-FOLDED CONFIGURATION. •HIGH SOLAR RAYS LANDING AT ANGLES HIGHER THAN 83 DEGREES ONTO THE CURTAIN-WALL SURFACE REQUIRING NO FRONT-COVER OF THE CURTAIN-WALL ALLOWING MAXIMUM UNOBSTRUCTED VIEWS – THIS IS ACHIEVED BY A FULLY-FOLDED CONFIGURATION. SHADING PRINCIPLES 22
THE AL-BAHR TOWERS CURTAIN-WALL AND HONEYCOMB STRUCTURE WERE DEFINED BY THE LINKING OF NODES GENERATED FROM THE INTERSECTION OF TANGENTIAL CIRCLES AND THE EXTRUSION OF THE UNDERLYING RADIAL GRID. 23
THIS DIAGRAM SHOWS THE 800 MM-CURTAIN-WALL/FLOOR-PLATE PERIMETER BUFFER ZONE WHERE DIRECT SOLAR RAYS ARE ALLOWED TO LAND INSIDE THE BUILDING. SUCH CONDITION ONLY OCCURS DURING LIMITED HOURS OF THE DAY DURING THE SUMMER WHERE SOLAR RAYS LAND ON THE CURTAIN-WALL SURFACE AT AN ANGLE HIGHER THAN 83 DEGREES. SOLAR RAYS THAT TRAVEL DEEPER THAN THE IDENTIFIED BUFFER-ZONE WILL BE BLOCKED BY THE DYNAMIC MASHRABIYA SOLAR SCREEN SYSTEM BY DEPLOYING MASHRABIYA UNITS IN A SUITABLE OPTIMIZED OPENING CONFIGURATION. 24
PROBLEMS • GLASS SKYSCRAPERS HAVE BECOME THE TRADEMARK IN THE GULF. HOWEVER, BUILDINGS IN THE GULF SUFFER FROM THE FOLLOWING ISSUES: • HEAT AND GLARE FROM THE SUN CAN WARM UP THE EXTERIOR OF THE BUILDINGS TO UP TO 50ºC (CNN, 2012) • THE CONSTANT INCREASE IN PRICE OF ELECTRICITY TARIFFS. • THE INTERNATIONAL ROYAL HOTEL (TIRH), WILL EMPLOY A DYNAMIC SHADING SYSTEM; SIMILAR TO THE ONE USED IN AL-BAHAR TOWERS IN ABU DHABI. HOWEVER, WE WILL MODIFY AL-BAHAR TOWERS TO ACHIEVE HIGHER POWER EFFICIENCY USING SOLAR PANELS. SOLUTIONS • GEOGRAPHIC LOCATION: • DOWN TOWN DUBAI IS THE LOCATION OF TIRH. • THE FAÇADE WILL BE FREE FROM OBSTACLES THAT WILL BLOCK THE SUN. • SOLAR PANELS WILL HAVE MAXIMUM EXPOSURE TO SUNLIGHT. • STRUCTURAL DESIGN AND CONSTRUCTION OF MATERIAL: • 145 METERS HIGH. • 40 EXTERIOR COLUMNS. • CYLINDRICAL (REFER TO FIGURE 1) • REINFORCED CONCRETE. SOLAR POWERED BUILDING WITH DYNAMIC SHADING SYSTEM 25
QUANTITATIVE BENEFITS THE FOLLOWING ARE MEASURABLE BENEFITS OF THE INNOVATIVE FACADE SYSTEM. • 50% ENERGY SAVINGS FOR OFFICE SPACES ALONE, AND UP TO 20% FOR THE BUILDING OVERALL • 20% REDUCTION IN CARBON EMISSION WITH UP TO 50% FOR OFFICE SPACES USE ALONE • 15% REDUCTION IN OVERALL PLANT SIZE AND CAPITAL COST • 20% REDUCTION IN MATERIALS AND OVERALL WEIGHT DUE TO THE HIGHLY FLUID, RATIONAL AND OPTIMIZED DESIGN QUALITATIVE BENEFITS THE FOLLOWING ARE NON-MEASURABLE BENEFITS OF THE INNOVATIVE FACADE SYSTEM: • IMPROVEMENT OF USER-COMFORT AND IMPROVED PHYSICAL AND PSYCHOLOGICAL WELL-BEING OF OCCUPANTS 204 A. KARANOUH AND E. KERBER / INNOVATIONS IN DYNAMIC ARCHITECTURE • THE OVERALL ICONIC IDENTITY OF THE BUILDING • BETTER NATURALLY LIT SPACES THROUGH BETTER ADMISSION OF NATURAL DIFFUSED LIGHT (FIG. 22) • BETTER VISIBILITY OF EXTERNAL NATURAL VIEWS, LESS USE OF OBSTRUCTIVE AND PSYCHOLOGICALLY TRAPPING BLINDS (FIG. 23) • IMPROVED COMFORT BY REDUCING HEAVY AIR CONDITIONING LOADS AND AIR DRAFT • PROVIDE THE BUILDING WITH A UNIQUE IDENTITY, ROOTED TO LOCAL HERITAGE AND ENVIRONMENT • PROVIDE A UNIQUE AND ENTERTAINING FEATURE BOTH TO OCCUPANTS AND PASSING-BY PUBLIC. BENEFITS OF THE DYNAMIC FACADE SYSTEM 26
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Tallest building-project for building material construction technology

T
Twinkal JambuStudent at G. c patel institute of architecture

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Al bahar

  • 2. AL-BAHAR ABU-DHABI,UAE ARCHITECT: Aedas Architects CONSTRUCTION COMPANY: Al-Futtaim Carillion FOUNDER: Council Investment Abu Dhabi YEAR OF DESIGN: 2008 YEAR OF CONSTRUCTION: 2009-2012 ROOF HEIGHT: 145.1 m TOP FLOOR HEIGHT: 120.0 m FLOORS: 27 + 2 basement levels LAND AREA: 100.080 m² FLOOR AREA: 56.000 m² 1
  • 3. LOCATION: ABU DHABI, UNITED ARAB EMIRATES N CLIMATE: HOT DESERT CLIMATE HIGHEST TEMP:120 F 2
  • 4. SITE ANALYSIS N Entry/Exit SITE PLANNING: TWO TWIN OFFICE TOWERS FACING SOUTH ARE PLACED ON SITE CONNECTED BY SKYWALK. SITE CONDITION :VERY HOT CLIMATE SO NEED TO CONTROL TEMP., TOWERS PLACED FACING SOUTH FOR MAXIMUM UTILISATION OF SOLAR ENERGY PRESENT IN ABUNDENCE. 3
  • 5. PRINCIPLES • DESIGN PRICNCIPLE IS TO ACHIEVE A PERFORMANCE ORIENTED, CULTURALLY RELEVANT, TECHNOLOGICALLY ADVANCED, AND AESTHETICALLY INTRIGUING BUILDING. PLANNING • BASED ON SIX TANGENTIAL ARCS,TAKEN FROM THREE INTERSECTING CIRCLES • A PATTERN WHICH FORMS THE BASIS OF NEARLY ALL GEOMETRIC CONFIGURATIONS KNOWN TO THE REGION. 4
  • 6. CONCEPT • THE DESIGN CONCEPT IS BASED ON THE FUSION BETWEEN BIO-INSPIRATION, REGIONAL ARCHITECTURE, AND PERFORMANCE-BASED TECHNOLOGY. • CIRCLES AND ORBITS ARE USED TO REFLECT THE CONCEPT OF UNIFICATION AND UNITY EVIDENT IN NATURE. • THE DESIGN IS DRIVEN FROM ITS CONTEXT, TAKING INTO ACCOUNT ENVIRONMENT, TRADITION, AND TECHNOLOGY • THIS INITIAL SKETCH ILLUSTRATES THE INTEGRATION OF THESE ELEMENTS. WHILE EACH DESIGN FEATURE OF THE AL-BAHR TOWERS IS INFUSED WITH THIS BALANCE, THIS ARTICLE WILL FOCUS ON THE DYNAMIC FACADE. • PETER OBORN DESCRIBES THE BEGINNING OF THE AL-BAHR TOWERS DESIGN: “WE WANTED TO CREATE A BUILDING WHICH WOULD SET NEW STANDARDS OF ENVIRONMENTAL RESPONSIBILITY, AND BEGAN TO EXPLORE THE EMERGING FORM IN ORDER TO STUDY WHICH PARTS OF THE BUILDING WOULD REQUIRE THE HIGHEST LEVELS OF SOLAR PROTECTIONWITH THE INTENTION THAT WE WOULD THEN DESIGN SOME FORM OF ‘MASHRABIYA’ TO SCREEN THESE AREAS BIO-INSPIRATION • “TO ABSTRACT IDEAS FROM BIOLOGY AND TURN THEM INTO PRACTICAL ENGINEERING SOLUTIONS REQUIRES ALL DISCIPLINES TO CONTRIBUTE.” (JOHN, CLEMENTS-CROOME & JERONIMIDIS, 2004) • TO GATHER AN INTERDISCIPLINARY TEAM AROUND COMMON DESIGN IDEAS WE FOUND REFERENCES IN NATURE TO WHICH WE COULD ALL RELATE. FROM EARLY ON THE INTENTION WAS SET TO EXPLORE BIO- INSPIRATION. • GUIDINGEXAMPLES WERE DRAWN FROM THE FORMS OF CACTUS, PINEAPPLES, FLOWERS AND OTHER NATURAL SYSTEMS. • A CACTUS HAS UMBRELLA-LIKE FEATURES TO PROTECT ITS DELICATE WEATHER-TIGHT SKIN. FLOWERS OPEN AND CLOSE IN RESPONSE TO CHANGING WEATHER CONDITIONS. THE PINEAPPLE’S HEXAGONAL ENVELOPE COVERS A DOUBLE-CURVED SURFACE EFFICIENTLY. WE SOUGHT TO EMBODY THESE ATTRIBUTES IN THE DESIGN OF THE TOWERS. 5
  • 7. 6
  • 8. • THE DESIGN IS BASED ON THE CONCEPT OF ADAPTIVE FLOWERS AND THE "MASHRABIYA" - A WOODEN LATTICE SHADING SCREEN •A DYNAMIC AND SENSITIVE SHADING SCREEN ACTING AS' MASHRABIYA “ •SECONDARY SKIN FILTERS THE LIGHT AND REDUCES GLARE. •POWERED BY RENEWABLE ENERGY DERIVED FROM PHOTOVOLTAIC PANELS. •WRAPS GIANT LATTICE ALMOST TWO TOWERS COMPLETELY EXCEPT FOR THE AREA NORTH-FACING FACADES. SCREENS AL- BAHR TOWER SCREEN’S MODULE DESIGN ELEMENTS 7
  • 9. •THE DESIGN FOR THE PROJECT BEGAN WITH TWO SIMPLE CYLINDERS, BECAUSE THE CIRCULAR PLAN GIVING THE MOST EFFICIENT FLOOR AREA USAGE WHILE ALSO CREATING THE GREATEST VOLUME WITH THE LEAST SURFACE AREA WHICH WILL HIGHLY REDUCE THE SUN EXPOSURE SURFACE AREA . FORM STRUCTURE ENVELOPE ADAPTIVE SOLUTION INTEGRATION STRUCTURE 8
  • 10. Roof mounted Photovoltaic cells Translucent Mashrabiya appears cool and crystalline Sky Garden provides natural cooling effect Sky garden located in area of Max. exposure to reduce heat gain Sky garden reflects courtyard treatment provideing amenities space for users Hexagonal geometry – Islamic Architecture Mashrabiya - Makrana Islamic device creates a new Vernacilar Natural Optimised form Water feature to maximise evaporate cooling Shading effect similar to the form of nature Photovoltaic slopes southwards to maximise solar gain like leaf
  • 11. • THE TOWERS FEATURE A DYNAMIC, TRANSLUCENT FACADE THAT OPENS AND CLOSES IN RESPONSE TO THE SUN'S MOVEMENT, REDUCING SOLAR GAIN ON THE FACADE BY UP TO 50%. • THE FACADE IS INSPIRED BY "MASHRABIYA", A FORM OF WOODEN LATTICE SCREEN USED IN ISLAMIC ARCHITECTURE AS A MEANS OF RETAINING PRIVACY WHILE SIMULTANEOUSLY REDUCING GLARE AND SOLAR GAIN. • TRANSLUCENT, UMBRELLA-LIKE COMPONENTS MAKE UP THE FACADE; THERE ARE 2,000 OF THESE "MASHRABIYA" COMPONENTS ON EACH TOWER. THE INSPIRITION FOR THE FACADE 10
  • 12. THE FACADE ACCORDING TO THE SUN PATH HALF OPENFULLY CLOSED FULLY OPEN GRADIENT BASED ON SUN PATH11
  • 13. •AS THE SUN RISES IN THE MORNING IN THE EAST, THE MASHRABIYA ALONG THIS SIDE OF THE BUILDING WILL BEGIN TO CLOSE, AND WHEN THE SUN MOVES AROUND THE BUILDING, ALL VERTICAL STRIP MASHRABIYA MOVE WITH THE SUN. •AT NIGHT ALL SCREENS FOLD, ALLOWING MORE OF THE FACADE. AL BAHR TOWER IN DAY TIME AL BAHR TOWER AT NIGHT OPERATION 12
  • 14. Towers Al Bahar have implementation of advanced detection system designed to integrate the building with its cultural context and respond directly to the needs of the region's climate. ”Mashrabiya" in Al Bahar Towers has a number of components transparent umbrella that open and close in response to the sun's path. The effects of this system are comprehensive: reduced glare, improved daylight penetration, less reliance on artificial lighting, and over 50% reduction in solar gain, which results in a reduction of CO2 emissions by 1,750 tones per year. 13
  • 15. • THE AL BAHAR TOWERS TOOK INSPIRATION FROM TRADIONAL ISLAMIC MOTIF TO DESIGN AN INOVATIVE AND VISUALLY INTERESTING EXTERNAL AUTOMATED SHADING SYSTEM. • THE DYNAMIC FAÇADE HAS BEEN CONCIEVED AS A CONTEMPORARY INTERPRETATION OF THE TRADIONAL ISLAMIC “ MASHRABIYA”( A POPULAR FORM OF WOODEN LATTICES SCREEN USED AS DEVICE FOR ACHIEVING PRIVACY WHILE REDUCING GLARE AND SOLAR GAIN. • CLOSED STATE PROVIDING SHADING TO THE INNER GLAZING SKIN. AS THE SUN MOVES AROUND THE BUILDING EACH • MASHRABIYA UNIT WILL PROGRESSIVELY OPEN. BUILDING WITHOUT SHADING SYSTEM BUILDING WITH SHADING SYSTEM (FINS) BUILDING WITH DYNAMIC SHADING SYSTEM14
  • 16. TORRES - "COCOON BUILDINGS" • BASED ON A PRE-RATIONALIZED GEOMETRIC SHAPE, TUNED VIA PARAMETRIC DESIGN TOOLS TO ACHIEVE THE OPTIMAL RATIO OF SURFACE BETWEEN THE WALLS AND FLOOR. • FORM OF THE TOWERS IS OPTIMIZED TO COMPLEMENT THE SHADING SYSTEM. •THE DESIGN STARTED WITH TWO SIMPLE CYLINDERS, CIRCULAR, YIELDING THE MOST EFFICIENT IN TERMS OF "AREA-TO-FLOOR WALL", CREATING MORE VOLUME WITH LESS SURFACE. •THEN, A CIRCULAR SHAPE IS DIVIDED BASED ON A COMBINATION OF CIRCULAR GEOMETRIES TO REDUCE SOLAR EXPOSURE, AND IT STARTED TO GENERATE A NATURAL ORIENTATION. •THE SHAPE OF THE TOWERS WAS THEN SCULPTED AROUND THE CORE, NARROWER AT THE BASE AND AT THE TOP, WIDER AROUND THE INTERMEDIATE FLOORS. EVOLUTION 15
  • 17. • EACH UNIT COMPRISES A SERIES OF PANELS STRETCHED PTFE (POLYTETRAFLUOROETHYLENE) AND IS DRIVEN BY A LINEAR ACTUATOR TO PROGRESSIVELY OPEN AND CLOSE ONCE PER DAY, IN RESPONSE TO A PRE- PROGRAMMED SEQUENCE THAT IS CALCULATED TO AVOID DIRECT SUNLIGHT TO FROM THE MOMENT IT HITS THE FACADE . • COMPUTER-CONTROLLED, • OPERATES AS A CURTAIN WALL, • READY TO TWO METERS OF THE EXTERIOR FACADE OF BUILDINGS, IN A SEPARATE FRAME. • EACH TRIANGLE IS COATED WITH MICRO FIBERGLASS • PROGRAMMED TO RESPOND TO THE MOVEMENT OF THE SUN. • IT IS AN ANCIENT TECHNIQUE USED IN A MODERN WAY • THE WHOLE SYSTEM IS PROTECTED BY A VARIETY OF SENSORS THAT OPEN THE UNITS IN CASE CONDITIONS CHANGE, OR RAISE TO CLOUD WINDS. • GEOMETRIC PATTERNS THAT MAKE UP THIS GIANT SCREEN INCLUDE MORE THAN 1,000 MOBILE ELEMENTS THAT CONTRACT AND EXPAND DURING THE DAY, DEPENDING ON THE SUN POSITION. ENGINEERING 16
  • 18. PHOTOVOLTAIC CELLS • ROOFS FACING SOUTH EACH TOWER INCORPORATE PHOTOVOLTAIC CELLS. • GENERATING APPROXIMATELY FIVE PERCENT OF THE TOTAL ENERGY REQUIRED RENEWABLE ENERGY SOURCES, USED FOR HEATING WATER. • THE TOWERS HAVE BEEN ONE OF THE FIRST BUILDINGS IN THE GULF THAT RECEIVED A LEED SILVER RATING. • A BESPOKE APPLICATION WAS DEVELOPED USING JAVASCRIPT AND ADVANCED PARAMETRIC TECHNOLOGIES TO SIMULATE THE MOVEMENT OF THE FAÇADE IN RESPONSE TO THE SUN’S PATH. • THE PERFORMANCE CRITERIA AND GEOMETRY BUILD-UP OF THE SYSTEM DESIGN WERE CONVEYED USING A UNIQUE PROJECT SPECIFIC, GEOMETRY CONSTRUCTION & PERFORMANCE MANUAL. • THIS FREED THE DESIGN-TO-CONSTRUCTION PROCESS FROM LOCKING IT DOWN TO CERTAIN PLATFORMS AND COMPUTER TECHNOLOGIES AND OFFERED A UNIVERSAL DATA EXCHANGE LANGUAGE, ENABLING ALL PARTIES TO COMMUNICATE MORE EFFECTIVELY. DAYLIGHT ANALYSIS FOR SCREENS IN DIVA AND GRASSHOPPER 17
  • 19. • IT IS ESTIMATED THAT THE SCREEN REDUCES SOLAR GAIN IN MORE THAN 50% AND REDUCES THE NEED FOR AIR CONDITIONING. • SCREENS ABILITY TO FILTER LIGHT HAS ALLOWED TO BE MORE SELECTIVE IN THE CHOICE OF GLASS. • THIS ALLOWS US TO USE MORE NATURALLY TINTED GLASS, WHICH ALLOWS MORE LIGHT INSIDE AND LESS NEED FOR ARTIFICIAL LIGHT. • THE INTELLIGENT FACADE, TOGETHER WITH SOLAR THERMAL PANELS FOR HOT-WATER HEATING AND PHOTOVOLTAIC PANELS ON THE ROOF, MINIMIZE THE NEED FOR INTERNAL LIGHTING AND COOLING, ALTOGETHER REDUCING TOTAL CARBON DIOXIDE EMISSIONS BY OVER 1750 TONS PER YEAR. • FOR THE PROJECT’S SUSTAINABLE ENGINEERING AND SENSITIVE CULTURAL AND URBAN APPROACH, THE TOWERS WERE AWARDED THE 2012 TALL BUILDING INNOVATION AWARD. EFFICIENCY 18
  • 20. Wind A SERIES OF WIND-TUNNEL TESTS WERE CONDUCTED AT VARIOUS SCALES TO ANTICIPATE THE COMBINATION OF LOADS EXERTED ON THE BUILDING GENERALLY AND ON THE MASHRABIYA LOCALLY. BOTH SMALL AND FULL-SCALE MODELS WERE TESTED ACCORDINGLY. THE TESTS REVEALED THAT THE FLUID FORM OF THE BUILDING GENERATED RELATIVELY LOW +VE AND -VE PRESSURES, AVERAGING 1.5 kPa UP TO A MAXIMUM OF 3.5 kPa. A SINGLE DYNAMIC UNIT WAS LATER SUBJECTED TO VERY HIGH WIND SPEEDS UP TO 90 m/s, DEPLOYED IN DIFFERENT OPENING POSITIONS,WHERE THE RESULTING PRESSURES DID NOT EXCEED THE MAXIMUM FIGURES APPLIED ON THE BUILDING AS A WHOLE – DUE TO THE FLUID AERODYNAMIC GEOMETRY OF THE BUILDING FORM AND DYNAMIC MASHRABIYA SYSTEM. 19
  • 21. Energy models evaluated the towers’ solar gains without external shading screens (Fig. 34). Theoretically, a shading screen should completely wrap the tower as direct solar rays hit the curtain-wall from all directions, especially during summer. The north face experiences direct solar rays only for a short time in the morning and later in the afternoon, i.e. before and after working hours. Shading units in the North zone was therefore unnecessary. Shading studies were used to explore the impact on energy performance of different Mashrabiya configurations. This figure illustrates the facade opening and resulting improvement in energy performance during mid-season at 9:00 am. CLIMATIC RESPONSE 20
  • 22. MATERIAL EACH OF THE DRIVERS PLAYED A ROLE IN THE CHOICE OF MATERIALS FOR THE BUILDING ENVELOPE. • 1.4462 DUPLEX STAINLESS STEEL: ALL MAIN-FIXED SUPPORTING COMPONENTS LIKE CANTILEVER ARMS, YSTRUCTURE ARMS, AND BRACKETS CONNECTING THE SYSTEM BACK TO THE MAIN STRUCTURE ARE MADE OF DUPLEX STAINLESS STEEL, DUE TO ITS HIGH STRENGTH AND CORROSION RESISTANCE. ALL EXPOSED/VISIBLE COMPONENTS HAVE SHOT-PEEN FINISH, SIMILAR TO SAND BLASTING. THIS CAMOUFLAGES DUST AND SAND PARTICLES THAT SETTLE ON THE STEEL SURFACE. • PVDF COATED ALUMINIUM: ALL CURTAIN-WALL AND FABRIC MESH FRAMES ARE MADE OF EXTRUDED ALUMINIUM PROFILES. THESE ACHIEVE A FINER LEVEL OF DETAIL THAN POSSIBLE WITH STEEL. IT IS ROBUST, LIGHTWEIGHT, AND CORROSION RESISTANT, AND ELEGANT LOOKING WHEN FINISHED, IN THIS CASE IN A CHAMPAGNE COLOUR, AS IT RESEMBLES THE BEIGE COLOUR OF LOCAL SAND. • GLASS: CURTAIN-WALL VISION GLASS IS MADE OF DGU OF 40% VISIBLE LIGHT TRANSMISSION, 0.28 G-VALUE AND 18% EXTERNAL LIGHT REFLECTANCE. • TEFLON: ALL BEARINGS AND JOINTS SEPARATORS ARE MADE OF MARINE-GRADED TEFLON COMPONENTS. • SILICON: ALL SEALANTS/GASKETS ARE MADE OF BLACK SILICON – ESPECIALLY HIGHLY RESISTANT TO UV RAYS AND OTHER WEATHERING FACTORS. NOTE: THE SOLAR GAIN AND ENERGY STUDIES WERE INTENTIONALLY LEFT UNINFLUENCED BY THE MASHRABIYA. THE GEOMETRIC DEFINITION AND OPENING CONFIGURATIONS WERE THEN OPTIMIZED TO IMPROVE LIGHTING AND VISIBILITY. 21
  • 23. AS GENERAL RULE OF THUMB, A SHADING ELEMENT IS MOST EFFICIENT WHEN IT FACES SOLAR RAYS DIRECTLY I.E. ORTHOGONALLY. • A SHADING ELEMENT MUST CAST SHADOW OF ALL ITS EDGES ONTO THE ADJACENT SHADING ELEMENT TO AVOID DIRECT SOLAR RAYS LANDING ON THE VISION GLASS BEHIND IT. • ON ONE HAND, HOWEVER, THE MOVING SUNLIGHT RESULTS IN SOLAR RAYS LANDING ON THE CURTAIN-WALL AT INFINITE ANGLES. • ON THE OTHER HAND, NOT ALL DIRECT SOLAR RAYS TRAVELLING INSIDE THE BUILDING AFFECT THE OVERALL PERFORMANCE OF THE ENVELOPE AS LONG AS THEY ARE LIMITED TO A BUFFER ZONE AROUND THE PERIMETER OF EACH FLOOR-PLATE WITHOUT LANDING ON THE WORKING DESK LEVEL AND IN THE EYES OF OCCUPANTS (FIG. 29). BOTH EXPERIENCE AND EARLY SHADING STUDIES USING VARIOUS OPENING CONFIGURATIONS OF THE MASHRABIYA SCREEN RESULTED IN DEVELOPING THE FOLLOWING PRINCIPLES TO CONTROL THE SHADING ELEMENTS PERFORMANCE:- • THE CONFIGURATION OF THE SHADING IS BASED ON OPTIMIZED CATEGORISATION OF SOLAR RAYS. • GENERAL SOLAR RAYS LANDING AT ANGLES BETWEEN 0 AND 79 DEGREES ONTO THE CURTAIN-WALL SURFACE REQUIRING FULL FRONT-COVER OF THE CURTAIN-WALL .THIS IS ACHIEVED BY AN UN-FOLDED CONFIGURATION. • INTERMEDIATE SOLAR RAYS LANDING AT ANGLES BETWEEN 80 AND 83 DEGREES ONTO THE CURTAIN-WALL SURFACE REQUIRING PARTIAL FRONT-COVER OF THE CURTAIN-WALL ALLOWING PARTIAL UNOBSTRUCTED VIEWS – THIS IS ACHIEVED BY A MIX-FOLDED CONFIGURATION. •HIGH SOLAR RAYS LANDING AT ANGLES HIGHER THAN 83 DEGREES ONTO THE CURTAIN-WALL SURFACE REQUIRING NO FRONT-COVER OF THE CURTAIN-WALL ALLOWING MAXIMUM UNOBSTRUCTED VIEWS – THIS IS ACHIEVED BY A FULLY-FOLDED CONFIGURATION. SHADING PRINCIPLES 22
  • 24. THE AL-BAHR TOWERS CURTAIN-WALL AND HONEYCOMB STRUCTURE WERE DEFINED BY THE LINKING OF NODES GENERATED FROM THE INTERSECTION OF TANGENTIAL CIRCLES AND THE EXTRUSION OF THE UNDERLYING RADIAL GRID. 23
  • 25. THIS DIAGRAM SHOWS THE 800 MM-CURTAIN-WALL/FLOOR-PLATE PERIMETER BUFFER ZONE WHERE DIRECT SOLAR RAYS ARE ALLOWED TO LAND INSIDE THE BUILDING. SUCH CONDITION ONLY OCCURS DURING LIMITED HOURS OF THE DAY DURING THE SUMMER WHERE SOLAR RAYS LAND ON THE CURTAIN-WALL SURFACE AT AN ANGLE HIGHER THAN 83 DEGREES. SOLAR RAYS THAT TRAVEL DEEPER THAN THE IDENTIFIED BUFFER-ZONE WILL BE BLOCKED BY THE DYNAMIC MASHRABIYA SOLAR SCREEN SYSTEM BY DEPLOYING MASHRABIYA UNITS IN A SUITABLE OPTIMIZED OPENING CONFIGURATION. 24
  • 26. PROBLEMS • GLASS SKYSCRAPERS HAVE BECOME THE TRADEMARK IN THE GULF. HOWEVER, BUILDINGS IN THE GULF SUFFER FROM THE FOLLOWING ISSUES: • HEAT AND GLARE FROM THE SUN CAN WARM UP THE EXTERIOR OF THE BUILDINGS TO UP TO 50ºC (CNN, 2012) • THE CONSTANT INCREASE IN PRICE OF ELECTRICITY TARIFFS. • THE INTERNATIONAL ROYAL HOTEL (TIRH), WILL EMPLOY A DYNAMIC SHADING SYSTEM; SIMILAR TO THE ONE USED IN AL-BAHAR TOWERS IN ABU DHABI. HOWEVER, WE WILL MODIFY AL-BAHAR TOWERS TO ACHIEVE HIGHER POWER EFFICIENCY USING SOLAR PANELS. SOLUTIONS • GEOGRAPHIC LOCATION: • DOWN TOWN DUBAI IS THE LOCATION OF TIRH. • THE FAÇADE WILL BE FREE FROM OBSTACLES THAT WILL BLOCK THE SUN. • SOLAR PANELS WILL HAVE MAXIMUM EXPOSURE TO SUNLIGHT. • STRUCTURAL DESIGN AND CONSTRUCTION OF MATERIAL: • 145 METERS HIGH. • 40 EXTERIOR COLUMNS. • CYLINDRICAL (REFER TO FIGURE 1) • REINFORCED CONCRETE. SOLAR POWERED BUILDING WITH DYNAMIC SHADING SYSTEM 25
  • 27. QUANTITATIVE BENEFITS THE FOLLOWING ARE MEASURABLE BENEFITS OF THE INNOVATIVE FACADE SYSTEM. • 50% ENERGY SAVINGS FOR OFFICE SPACES ALONE, AND UP TO 20% FOR THE BUILDING OVERALL • 20% REDUCTION IN CARBON EMISSION WITH UP TO 50% FOR OFFICE SPACES USE ALONE • 15% REDUCTION IN OVERALL PLANT SIZE AND CAPITAL COST • 20% REDUCTION IN MATERIALS AND OVERALL WEIGHT DUE TO THE HIGHLY FLUID, RATIONAL AND OPTIMIZED DESIGN QUALITATIVE BENEFITS THE FOLLOWING ARE NON-MEASURABLE BENEFITS OF THE INNOVATIVE FACADE SYSTEM: • IMPROVEMENT OF USER-COMFORT AND IMPROVED PHYSICAL AND PSYCHOLOGICAL WELL-BEING OF OCCUPANTS 204 A. KARANOUH AND E. KERBER / INNOVATIONS IN DYNAMIC ARCHITECTURE • THE OVERALL ICONIC IDENTITY OF THE BUILDING • BETTER NATURALLY LIT SPACES THROUGH BETTER ADMISSION OF NATURAL DIFFUSED LIGHT (FIG. 22) • BETTER VISIBILITY OF EXTERNAL NATURAL VIEWS, LESS USE OF OBSTRUCTIVE AND PSYCHOLOGICALLY TRAPPING BLINDS (FIG. 23) • IMPROVED COMFORT BY REDUCING HEAVY AIR CONDITIONING LOADS AND AIR DRAFT • PROVIDE THE BUILDING WITH A UNIQUE IDENTITY, ROOTED TO LOCAL HERITAGE AND ENVIRONMENT • PROVIDE A UNIQUE AND ENTERTAINING FEATURE BOTH TO OCCUPANTS AND PASSING-BY PUBLIC. BENEFITS OF THE DYNAMIC FACADE SYSTEM 26