RAMZI OMAR | ARCHITECTURE DESIGN PORTFOLIO V 2.0 | 2016

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EDUCATION

Sep 2014Mar 2016

Architectural Association School Of Architecture Master of Architecture & Urbanism (M.Arch) Design Research Laboratory (AADRL) London, UK

Sep 2006 July 201 1

M.S Ramaiah Institute Of Technology Bachelor of Architecture (B.Arch) Bangalore, India

Ramzi Omar

Architect | Designer | Researcher Nationality Indian Date of Birth 20|06|1988 Contact +971 526127366 (UAE) +91 9539812428 (IND) ar.ramziomar@gmail.com

WORK EXPERIENCE

July 2016 Present

Projects:

Silicon Oasis City Tower Dubai, UAE 341068

I am an experienced and skilled architect with a Master’s degree in Architecture and Urbanism (AADRL) from the prestigious AA School of Architecture, London, where I explored the ideas of digital prototyping, Material research and computational designs which gave me enormous experience and exposure to the use of latest design tools in architecture.

CV

Residential, Mixed Use. Mosque

Contributions: Conceptual Design, Design Development, 3D Modelling, Space Planning, Presentations, Illustrations

Aug 2011 Aug 2013

Thomas Associates Architects Project Architect Bangalore, India Projects: Gated Community, Hotel, Shopping Mall, Auditorium, Institution, Club House, Residential, Commercial, Retail & Office.

During my 3 years of professional experience as a Designer and an Architect, I was constantly involved in projects that dealt with incremental scales of design in both urban and rural contexts each of which demanded high level of standards starting from conceptual design to execution at site. The studios involved synthesis between the built and unbuilt, landscapes and structural systems. As an Architect I was responsible for Design where the design ideas were supplemented by strong background research at all stages, construction drawings, project execution, supervision and successfully involved in interacting with various parties including Clients, engineers and consultants. This experience has enriched me with better insight into planning process and management of professional relationships. Academically, I have contributed significantly to the formulation and investigation in the team’s research project and design thesis – both in empirical experimentation and digital exploration of design options, where I explored the use of combined technologies, spatial printing and robotic fabrication to transform the way spaces are designed and produced. This Knowledge is essential in the elaboration of design proposals concerned with the everyday, as it offers a deep understanding of material and social complexity in architecture and urbanism. My professional experience and academic background have contributed to my individual thought process, which helped me nurture my key strengths, giving me a mature approach to architecture and upgrading my capabilities with CAD programs and communicative skills. Architecture for me is not a subject to dip in and out of; I’m in it for the long run.

Bead Architects Architectural Designer Abudhabi, UAE

Contributions: Conceptual Design, Design Development, 3D Modelling, Space Planning, Presentations, Illustrations, Technical Drawings, Site Co-ordination, Project Supervision,

Aug 2009 Dec 2009

Design Studio Intern Architect Bangalore, India Projects: Hospital, Hotel, Residential, Interiors. Contributions: Conceptual Design, Design Development, 3D Modelling, Space Planning, Presentations, Illustrations, Technical Drawings, Project Supervision.


WORKSHOPS & RESEARCH Oct 2014Dec 2014

AADRL Material Workshop - Material Computation AADRL Computational Workshop - Generative Craft

SOFTWARE & PROTOTYPING SKILLS

3D MODELLING

Autodesk MAYA 3D Studio MAX Rhinocerous

Robotic fabrication - Robotic Prototyping Odico Formworks Robotics | Odense | Denmark

Grasshopper Sketch up

Apr 2015

Apr 2015

Statics-Aware Robotic Printing Structurally Sound, Spatial 3d Printing with Robots IAAC Institute of Architecture | Barcelona | Spain Workshop in Robotic Control ROBOTS.IO | ROBOFOLD | London | UK Tutor : Shajay Bhooshan, Alicia Nahmad, Tyson Hosmer, Pierandrea Angius, Asbjorn Sondergaard, Alexander Dubor.

2D DRAFTING

Rhinocerous ArchiCad

GRAPHICS & VISUAL MEDIA

Adobe Photoshop Adobe Illustrator Adobe Indesign Adobe Lightroom

AFFILIATIONS Council of Architecture India Registered Architect, License CA/2012/57966 Starting December 2012

Revit Autocad

Adobe AfterEffects Adobe PremierPro ANIMATION & RENDERING

Architectural Association Member Membership No. 1053027 Starting September 2014

Autodesk MAYA Sketchup KeyShot V-Ray Podium

HONOURS & AWARDS ROBOTICS

ABB RobotStudio KUKA prc

Awards for Excellence in Architectural Thesis Council of Architecture | National Institute of Advanced Studies in Architecture NIASA India Project: Automobile Design City - Sep 2011 Tutor: Arunachal Hombali

OFFICE

FABRICATION

MS Word Excel PPT

3D Printing

Laser Cutting

CNC Milling

Carpentry

Proficiency First Prize for Academic Excellence - 2011 Dharwad University Campus Design Competition - 2010 Won 3rd Prize

RESEARCH INTERESTS Parametricism Robotics Digital fabrication 3D Printing Agent Based Modelling Kinematics Generative & Algorithmic Design

LANGUAGES

English(Fluent), Hindi(Fluent), Arabic(Elementary) Malayalam(Native), Kannada & Tamil(Bilingual)

REFERENCES THEODORE SPYROPOULOS Director - Minimaforms Director - AADRL AA School of Architecture 36 Bedford Square London WC1B 3ES theo@minimaforms.com

SHAJAY BHOOSHAN TOM THOMAS Designer - Zaha Hadid Architects Director - Thomas Associates Course Master - AADRL 32/4 kasturba Road cross AA School of Architecture Bangalore 36 Bedford Square 560001 London WC1B 3ES thomas@ta-arch.com shajay.bhooshan@zaha-hadid.com



Postgraduate | M.Arch | Architecture and Urbanism

DESIGN RESEARCH LABORATORY

Architectural Association School of Architecture | London | UK


LOCI

MASTERS THESIS PROJECT RESEARCH TEAM Aditya Bhosle Lyudmyla Semenyshyn Ramzi Omar TUTOR Shajay Bhooshan The studio research agenda explores the use of combined technologies, robotic arms and 3d printing, in the architectural design. Nowadays, numerous investigations on materials and fabrication methods have been undertaken, in order to produce printed structures. The growing interest in material research and digital fabrication is challenging the conventional approach to architecture. This dissertation aims to analyze the possibilities and limitations of spatial 3d printing, through the use of robotic arms, to transform the way livable spaces are designed and produced. The conventional approach of layer-by-layer printing method is replaced by spatial extrusion. Thus, it is essential to design a 3d printer technology and define a particular external digital control system. This will be achieved through the customization of existing industrial robotic arm technology responding to the material’s properties.

THE MATERIAL

3D PRINTING FILAMENTS

IN C AR

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THE TOOL

THE DESIGN PROCESS


PROGRAMMABLE MATERIAL Fabrication test - tests were undertaken to understand how the roboti carm could be used to translate the virtual into physical models.

Printing Speed Test (micro) A good resolution of Material output Accurate tension for printing

Printing Process (macro) Based on material behaviour Network of member for stability Sequence of printing Temporary supports DETAIL

Scanning (Feedback) Feedback loop Connecting the digital and physical world

Material Behaviour The next step was to study how a network of strands respond to different bending strategies in order to obtain forms that respond to structural and aesthetic requirements

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ROBOTIC END-EFFECTORS

DESIGNING

A series of end effectors are designed through our research to automate the fabrication process based on the material behaviour and architectural intention For the customization of industrial robotic arm it is essential to design an end effector that allow the extrusion of the material following the requirements of resolution and time of printing. Furthermore, this robotic technology should be controlled through computational data. The material is meant to be extruded by the end effector also it should be able to print to at any angle. The images below show the design development of the end effector to achieve a fully automated and controlled printing tools.

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Multi nozzle manual extruder

Single nozzle manual extruder

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4

Multi-nozzle PLA extruder V.01

Multi-nozzle PLA extruder V.02

The multi-nozzle extruder is designed to print four filaments at the same time, it has a gear system which rotates the 4 nozzle to get a higher resolution output. The tool is designed to print at any angle in space, the print speed and the rotation to twist the material is controlled using Arduino board.

Structure printing

The extruder has a possibility to mount filament spools, with this particular design we are able to print a 12 m long member with a resolution of four filaments.

Exploded view


A SINGLE NOZZLE END-EFFECTOR was designed to operate on a sensor, the actuation of the printing is controlled by the proximity senor, the extruder only switches on when a strand within its scanning range. The nozzle is mounted with a proximity sensor, the sensor is controlled through an Arduino board.

Doodler Pen Proximity sensor attached

Doodler Pen Arduino board attached

Scanning the geometry

Scanned Points

CONSTRAINT STUDIES

DIGITAL ANALYSIS OF TENSION BENDING

Level of constraints Negative curvature

Level of constraints Negative curvature

Level of constraints Negative curvature

Level of constraints Negative curvature

Level of constraints Negative curvature

Level of constraints Negative curvature

Digital Process

Robotic arm in architectural research does not change the technology and mechanics of the arm instead how this tool can affect our fabrication process and built space. Robotic fabrication is thus used to address a system that is organised and entirely based on digital and material processes. Our proposal is to integrate robotic arm in our research which is based on 3D printing and material behaviour because of its inherent control, issue of zero tolerance and precision.

Spatial Process

Space

Considering all the advantages and limitation of this tool we intend to find its purpose in the field of architectural automation, and therefore generating a structurally stable 3D printed geometries leading to a built space.


DESIGNING THE PROTOTYPE

MATERIAL FABRICATION

Taking into account all the previous research on material behaviour and robotic fabrication, a prototype was designed. certain tests were performed in order to test the concept of bending, the anchor point, the control points of the material, and principally, the material integrity itself. The initial test performed at a large scale meant to prove whether the material composition of the system could actually behave as hypothesized. The conclusion achieved was to further develop the material inorder to attain more strength and stability which could be achieved by bundling. Top to Bottom approach was performed.

Fabrication Process


Fabrication Cell Design And Robotic Choreography After testing individual strand set-ups, a scaled-up networked version of those was fabricated using individual robotic arms. More precisely the length of the strands was set at 1 to 1.5m for the base segments., the length of secondary strands were set at slightly longer which is 1.4m to 1.9m. As the prototype further expands the length of primary and secondary strands increases according to the length of every individual segment. The secondary strands determines the shape of the structure. The addition of bracing in this experiment was of crucial importance due to structural performance issues. Therefore the initial setup had to be reconfigured for the reach of the robotic arm inorder to brace all the secondary members to its nearest primary member. robotic cell basic robotic setup movement in xyz plane by rails

Line Diagram

production of individual segemnt that forms primary structural elements using twisting and bracing end effector

expansion of each segment by bundling over the existing structural core

assembling all the different segments of the structure by fusing and bundling to form a unit or cell

Digital Simulation


Physical Models Material Behaviour

DESIGN PROCESS

In the earlier attempts to form a design process, several strategies that through trial and error formed the current design methodology were investigated. It is essential to point out the main goals of this research so as to make the concepts behind the current process more easily understood and also demonstrate the continuity of the research analysis. A series of physical models were generated, based on design intuition and observations on the material behavior. Starting from simple setups, the fundamental structural concept of bending active structures were studies, while the initial design concepts were being generated. Essential observations were made during this stage of the research. Such as the importance of the network in opposition to the structural behavior of single elements. In this phase, the use of experimental form finding methods led to the definition of the material constraints and liberations, as well as to the perception of the design potentials of the system. The latter formed the design tools that were used in the later research.

Design Approach

Digital Simulation

3 point split

3 point split

4 point split

4 point split

6 point split

6 point split

4 point multiple

4 point multiple

9 point multiple

9 point multiple

CONNECTION STUDIES

LOOPING FORMS

Form Finding Geometrical Definition


Low Poly

Low Poly

Linear Arrangement

Staggered

Radial Arrangement

Segmented Networks Low Poly

Low Poly

Linear Arrangement

Staggered

Radial Arrangement

SEGMENTED FORMS

Low poly

FLUID FORMS

Initial condition

Form finding

Structure generation through manipulation of a low resolution control polygon. Initial condition from 2 plane of references.

Fluid Networks

Fluid Networks


FORM FINDING PROCESS

PLANNING & INTERCONNECTION

The target is to apply all the concepts developed through material research, robotic fabrication and computational design process, to design a house. These case studies in the history of plastic architecture were looked upon analysing them based on construction, connections and expansion.

Pascal häusermann – domobiles,

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Cheneac– cellules amphores

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ICE

CT

RV

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SE S

The process shows the geometric evolution and the form finding process. A sequence of steps developed to achieve the geometrical possibilities. Using a unit as a form finding module. The images show how we can apply our structural system based on material behavior. The process of layer printing is used to create a surface as explained previously. The deflection analysis shows the area where the surface density need to be maximized. An aggregation of these individual modular unit results in the form finding process.

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DESIGN APPLICATION

Cheneac – Cellules polyvalentes

antti lovag palais bubble

monsanto house of future

FORM MODULAR UNITS

STRUCTURE AND SURFACE

EXPANSION


GEOMETRICAL EVOLUTION

INITIAL CONDITIONS

LOW POLY MESH

BEVEL EDGES

EXTRUDE SURFACES

SMOOTH MESH

OPENINGS

THE POD

SPACE

LOW POLY MESH

DESIGN HOUSE EVOLUTION

STRUCTURAL BASED ON MATERIAL BEHAVIOUR

DEFLECTION ANALYSIS

SURFACE

DEFLECTION ANALYSIS OF CLUSTEER

Structural analysis and assembly of units to form a space

EXTRUDED SURFACE

FINAL GEOMETRY


MODULAR UNIT DESIGN




PERSPECTIVE


WORKSHOP AADRL

GENERATIVE CRAFT

The workshop was based on C++ script and maya n-particles that would simulate the chemical reaction called reaction diffusion. The script was based on many parameters that would generate a particle animation which could be paused at any given moment. After choosing particular frames, when the particles forms an interesting shape, a point cloud would be exported and transformed into a polymesh. Based on these polymesh, a basic low poly geometry is modelled, and finally a sequence of transformations would be applied to it, to create a complex cohesive geometry. The intricacy of images such as the ones produced by Ernst Haeckel would serve as the initial inspiration. The final step was to evaluate them as printable objects, the choice here was a laser sintering method of additive manufacturing, because of the complexity, small scale and fragility of the models. Based on a printable volume 5x5x5cms in which the geometries would be fitted inside, they were then evaluated by the printing speed and amount of material used.

Particle Simulation

Particle Simulation - Initial Conditions

Point Cloud

Vertebra - Maya Low Poly Modelling


Initial Condition

Geometric Graph

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4 Gargoyle - Maya Low Poly Modelling

Initial Condition

Geometric Graph

Vehicle - Maya Low Poly Modelling











Professional

BEAD ARCHITECTS Abudhabi, UAE


BEAD RESIDENTIAL TOWER DESIGN TEAM Muhannad Assam Marta Krivosik Ramzi Omar Vineeth

The project at the plot SB-01 on the Al Maryah Island, Abu Dhabi is aiming to reflect high quality residential apartments compliant with the international standards and easily compete with neighbours. High quality shall mean not only the materials, systems and hardware applied, but generous spatial layouts, allowing high level functionality and extended comfort. BEAD Architects & Engineers understand the importance of the project`s highlighted position at the crossroad and next to entry point to Al Maryah Island from Al Reem Island, aiming to be one of the busies’t corners within the island towards the city. Therefore this future building shall: »» showcase the presence in quality and lifestyle of Al Maryah Abu Dhabi, »» act as a point of attraction of the development, »» interact with and enhance the surrounding city`s existing street life, »» ensure that the lower podium’s facilities and it`s lansdcaped front satisfy the requirements of MDG, improve on the connectivity between levels+3.00m ASL and +14.25m ASL and provide the Client with the best revenue from retail.


10th from Abu Dhabi

10th AlfromFalah Street Abu Dhabi

Al Falah Street

ramp up from SR-1 to P-1 ramp down from P-1 to SR-5

ramp down

road P-1

road p3

road P-3

ramp down from P-3 to SR-3

ramp down from P-3 to SR-3

+14.25 ASL

to reem

5

road sr-

Road / Service Roads Street System at

Access to Site Close up

ramp down from P-3 to SR-3

road sr-1

pedestrian

ramp up from SR-5 to P-3

road

5

public lift & staircase

ramp down

VEHICULAR PATH TO ACCESS SITE VEHICULAR PATH TO EXIT SITE PEDESTRIAN PATH

main public lift Vehicular pedestrian& staircase ser-

Access to Site SB01 at +3.0 m ASL

+3.00 ASL

road sr

5 +prom

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service access

+3.00 ASL

ramp down from P-3 to SR-3

road sr-3

road sr-

+14.25 ASL

Access to Site SB01 at +14.25 m ASL

ramp up ramp up from SR-5 to P-3 from SR-1 to P-1

+3.00 ASL

+14.25 ASL

road

ramp down from P-1 to SR-5

ramp down from P-3 to SR-3

road p3

VEHICULAR PATH TO ACCESS SITE VEHICULAR PATH TO EXIT SITE PEDESTRIAN PATH

to reem Island Road/Street System at +14.25 m ASL

road p2

ramp up from SR-5 to P-3

road

ramp up from SR-5 to P-3

road

main service

road sr road sr

promenade

Access to Site Close up

road system including vehicular, Service and pedestrian


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SOUTH-EAST FACADE

OVERHEATED FACADE MAXIMUM SHADING PROTECTION

NORTH-WEST FACADE

“COLD” FACADE MINIMAL SHADING PROTECTION

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06:00 - 20:00

06:00- 20:00

JANUARY - MARCH

APRIL - JUNE

06:00- 20:00

JULY - SEPTEMBER

06:00- 20:00

OCTOBER - DECEMBER

Solar Radiance


FIELD OF VIEW


sun path


DOUBLE SKIN FACADE

PROJECTED BALCONIES

RECESSED BALCONIES (COUNTED IN GFA)

ACTIVE/PASSIVE SHADING FINS

SERIES OF TERRACE

shading typology on towers


study models


study models




BEAD RESIDENTIAL TOWER DESIGN TEAM Muhannad Assam Marta Krivosik Ramzi Omar Vineeth

The Project is a Luxury Residential Tower located at Najmat Marina, on Plot RR2-C16. The design of the tower should reflect modern architecture and maximize the views of Najmat Marina.  Total plot area: 5,222 sqm  Total gross floor area: 40,000 sqm




1st FLOOR - RESIDENTIAL

HEALTHCLUB LEVEL

TYPICAL FLOORS




VIEW CANAL VIEW

BEAD

VIEW ANGLE

RESIDENTIAL TOWER

BUILDING VIEW ANGLE

DESIGN TEAM Muhannad Assam Marta Krivosik Ramzi Omar

SOUT H WINT ER

The Project is a Luxury Residential Tower located in AL Dana North, Al Raha Abudhabi. The 16 storey Apartment building which takes an advantage of the sight and utilise the 180 degree panoramic view of the island, which also creates a bold axis for the AlDar Headquarters. The design of the tower should reflect modern architecture and maximize the views of the island.

SUMMER

WEST EAST SIT E

 Total Gross Floor Area: 14,495 sqm  Total Built Up Area: 25,135 sqm maximum

NORT H

SUN PATH SOUTH / SSE WIND (DECEMBER-MARCH)

NORTH-WEST WIND (MARCH-DECEMBER) EAST WIND (JUNE-SEPTEMBER) SITE

WIND DIRECTION


16 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 G

16 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 G

3 bedroom 01

3 bedroom 04

2nd floor apt. mix studio apartments - 8nos.

13th floor (12TH TYPICAL FLOOR) apt. mix 2 bedroom - 6nos.

16th floor (14 & 15 TYPICAL FLOORS) apt. mix 3 bedroom - 4nos.

3 bedroom 02

3 bedroom 03


BASEMENT ENTRY/EXIT

CL-47.1M

VEHICULAR ACCESS

DR OP OF FA RE A

65.2M

CL-69M



BEAD RESIDENTIAL TOWER DESIGN TEAM Muhannad Assam Marta Krivosik Ramzi Omar

SITE ANALYSIS site urban ART Trail green ART Trail destinations

MARINA

C17B C16

Najmat Towers (2B + G + 2P + 28Floors)  Total Gross Floor Area: 40,000 sqm  Total Built Up Area: 74,766 sqm

MARINA

Client: Reem Developers Contributions: Pre concept Design, Concept Design, Form finding methodologies, Facade Design. Design Development, Space Planning, Presentations, Illustrations, Concept report preparation. Preparation of Project Data Matrix. This challenging project, designing for two plots RR2-C16 and RR2-C17b within the Al Reem Island Najmat Development, Abu Dhabi aims to reflect high quality hospitality and residential habitat compliant with the international standards which easily compete with its neighbors. High quality shall mean not only the materials, systems and hardware applied, but thoughtfully planned spatial layouts, allowing high level functionality and extended comfort to the end users so to become a unique and inspiring development. The facade of the towers are derived from micro-design features which interweave elements, such as bay windows and balconies into one continuous line. Intertwining lines and surfaces wrap the apartments, seamlessly incorporating sun screening where needed, whilst also ensure that the inner qualities of the apartments and the outer appearance of the building together form a unified whole. The buildings are similar in design, but each distinctive in itself, complementing each other to create a well-integrated development.

PUBLIC REALM DESTINATIONS UP TO 300 M

UP TO 140 M UP TO 130 M UP TO 120M

C16 RESIDENTIAL

CITY VIEWS HEIGHTS - THE BUIDLING TO BE SURROUNDED BY MUCH HEIGHER BUIDLINGS

VIEWS (BASED ON 300M DISTANCES)


apartments

serviced apartments

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offices / retail

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residential (TOWER) serviced apartments commercial (PODIUM)

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P

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APARTMENT VIEWS

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PUSH CORNERS OF THE BOX TO

CUT UNNECESSARY GFA

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cityscape

offices

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marina

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MARINA / CITYSCAPE

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HEALTH CLUB & TERRACES

retail

PODIUM ALONG URBAN ART TRAIL BUILDING CORES / CIRCULATION

TOWER DESIGN EVOLUTION

BUILDING FUNCTIONS


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(LVL +3.00 - +5.40M) SCALE

1:400

GROUND FLOOR PLAN PROJECT NAME:

A16-08 NAJMAT TOWER SERVICE & RESIDENTIAL APARTMENTS

GROUND FLOOR PLAN REV - 04 30/07/2017

PO. Box 62010 AD - UAE www.bead-architects.com info@bead-architects.com Tel.:+971 (0) 2 6668110 Fax:+971 (0) 2 6668115


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PROJECT NAME:

A16-08 A NAJMAT TOWER SERVICE APARTMENTS

N

SCALE 1:200

SERVICE APARTMENTS

2-6 TYPICAL FLOOR PLAN REV - 04 30/07/2017

SCALE 1:200 PO. Box 62010 AD - UAE www.bead-architects.com info@bead-architects.com Tel.:+971 (0) 2 6668110 Fax:+971 (0) 2 6668115

PROJECT NAME:

A16-08 NAJMAT TOWER RESIDENTIAL APARTMENTS

REGULAR APARTMENTS 2 -17 TYPICAL FLOOR PLAN REV - 04 30/07/2017

FLOOR PLANS

PO. Box 62010 AD - UAE www.bead-architects.com info@bead-architects.com Tel.:+971 (0) 2 6668110 Fax:+971 (0) 2 6668115


1st FLOOR LVL

PODIUM-02 LVL

PODIUM-01 LVL

GROUND FLOOR LVL RETAIL ENTRY @ MA

PROJECT NAME:

UPPER ROOF LVL

ROOF

LOWER ROOF LVL

LIFT MACHINE ROOM

LIFT LOBBY

HALLWAY

STUDIO UNITS

BALCONY

29th FLOOR LVL

LIFT LOBBY

HALLWAY

STUDIO UNITS

BALCONY

28th FLOOR LVL

LIFT LOBBY

HALLWAY

BATH

KITCHEN

MASTER BEDROOM

BALCONY

27th FLOOR LVL

LIFT LOBBY

HALLWAY

BATH

KITCHEN

MASTER BEDROOM

BALCONY

26th FLOOR LVL

LIFT LOBBY

HALLWAY

BATH

KITCHEN

MASTER BEDROOM

BALCONY

25th FLOOR LVL

LIFT LOBBY

HALLWAY

BATH

KITCHEN

MASTER BEDROOM

BALCONY

24th FLOOR LVL

LIFT LOBBY

HALLWAY

BATH

KITCHEN

MASTER BEDROOM

BALCONY

23rd FLOOR LVL

LIFT LOBBY

HALLWAY

BATH

KITCHEN

MASTER BEDROOM

BALCONY

22nd FLOOR LVL

LIFT LOBBY

HALLWAY

BATH

KITCHEN

MASTER BEDROOM

BALCONY

21st FLOOR LVL

LIFT LOBBY

HALLWAY

BATH

KITCHEN

MASTER BEDROOM

BALCONY

20th FLOOR LVL

LIFT LOBBY

HALLWAY

BATH

KITCHEN

MASTER BEDROOM

BALCONY

19th FLOOR LVL

LIFT LOBBY

HALLWAY

BATH

KITCHEN

MASTER BEDROOM

BALCONY

18th FLOOR LVL

LIFT LOBBY

HALLWAY

BATH

KITCHEN

MASTER BEDROOM

BALCONY

17th FLOOR LVL

LIFT LOBBY

HALLWAY

BATH

KITCHEN

MASTER BEDROOM

BALCONY

16th FLOOR LVL

LIFT LOBBY

HALLWAY

BATH

KITCHEN

MASTER BEDROOM

BALCONY

15th FLOOR LVL

LIFT LOBBY

HALLWAY

BATH

KITCHEN

MASTER BEDROOM

BALCONY

14th FLOOR LVL

LIFT LOBBY

HALLWAY

BATH

KITCHEN

MASTER BEDROOM

BALCONY

13th FLOOR LVL

LIFT LOBBY

HALLWAY

BATH

KITCHEN

MASTER BEDROOM

BALCONY

12th FLOOR LVL

LIFT LOBBY

HALLWAY

BATH

KITCHEN

MASTER BEDROOM

BALCONY

A16-08 NAJMAT TOWER SERVICE & RESIDENTIAL APARTMENTS

SECTIONAL ELEVATION

MEP EQUIPMENT SPACE

30th FLOOR LVL

11th FLOOR LVL

HALLWAY

10th FLOOR LVL

LIFT LOBBY

HALLWAY

9th FLOOR LVL

LIFT LOBBY

HALLWAY

POWDER RM

KITCHEN

LIVING / DINING

BALCONY

8th FLOOR LVL

LIFT LOBBY

HALLWAY

POWDER RM

KITCHEN

LIVING / DINING

BALCONY

7th FLOOR LVL

LIFT LOBBY

HALLWAY

POWDER RM

KITCHEN

LIVING / DINING

6th FLOOR LVL

LIFT LOBBY

HALLWAY

BATH

STUDIO UNITS

BALCONY

5th FLOOR LVL

LIFT LOBBY

HALLWAY

BATH

STUDIO UNITS

BALCONY

4th FLOOR LVL

LIFT LOBBY

HALLWAY

BATH

STUDIO UNITS

BALCONY

3rd FLOOR LVL

LIFT LOBBY

HALLWAY

BATH

STUDIO UNITS

BALCONY

2nd FLOOR LVL

LIFT LOBBY

HALLWAY

BATH

STUDIO UNITS

BALCONY

1st FLOOR LVL

PODIUM-02 LVL

PODIUM-01 LVL

GROUND FLOOR LVL

PO. Box 62010 AD - UAE www.bead-architects.com info@bead-architects.com Tel.:+971 (0) 2 6668110 Fax:+971 (0) 2 6668115

SECTION C - SIKKA REV - 04 30/07/2017 | SCALE 1:200@A1

CORRIDOR

ROOF GARDEN

CORRIDOR

CORRIDOR

SERVICE CORRIDOR

GENERAL CASHIER

PANTRY

LIFT LOBBY

KITCHEN

CORRIDOR

IT MANAGER

LOUNGE

S&M MANAGER

LIFT LOBBY

DOUBLE HEIGHT LOBBY

LIFT LOBBY

BALCONY

BALCONY

ROOF GARDEN

RECEPTION

LIFT LOBBY

PARKING

OFFICE ENTRY

RESTAURANT

CORRIDOR

DRIVEWAY

CORRIDOR

DRIVEWAY

SERVICE / ESCAPE CORRIDOR

CORRIDOR

TRUCK PARKING

DRIVEWAY / PARKING

STAFF AMENITIES

LIFT LOBBY

F&B

F&B

TERRACE

EXPRESS LAUNDRY / LINEN STORE

DRIVEWAY

TRUCK PARKING

DRIVEWAY

F&B

PUBLIC TOILET

DRIVEWAY


MARINA VIEW AL NAJMAT ABUDHABI DEVELOPMENT AT AL REEM ISLAND PLOT RR2-C16 & RR2-C17B CONCEPT DESIGN :: A16-08 & A16-08A :: 4th May 2017 :: REV.0


BEAD MIXED USE

T3

T3

T2

T1

DESIGN TEAM Muhannad Assam Marta Krivosik Ramzi Omar

T2

T1

Jeddah Towers

OPTION A - GFA REPRESENTATION ON THE SITE

(2B + G + M + 27Floors)

OPTION C - REFINING GFA, RECONSIDERING PROPORTIONS

 Total Gross Floor Area: 57,363 sqm  Total Built Up Area: 78,245 sqm Client: Emaar Developers Contributions: • Working extensively on the design front of architecture ranging from Pre concept Design, Concept Design, Form finding methodologies, Facade Design. • Design Development, 3D Modelling, 3D Printing, Space Planning, Presentations, Illustrations, Preparation of Project Data Matrix.

T3 T3 T1 T2

T2 T1 OPTION B - CREATING “GATE” FEELING WITH SIMPLE ELEMENTS - PROBLEM WITH GFA

OPTION D - REFINING PROPORTIONS AND FURTHER GFA

3D PRINTED MASSING STUDIES / DESIGN EVOLUTION


CORE 2 CORE 1 90 DEGREES

PERPENDICULAR TO AXIS

BREAKING POINT FOR OPENING

REDISTRIBUTE GFA BASED ON THE REQUIREMENTS

BUILDING VERTICAL CIRCULATION CORES

RESIDENTIAL

J

P

CIVIC PLAZA

FINAL TREATMENT TO EMPHSASIZE THE “GATE” EFFECT

PROVIDED PLAZA VIEWS

RETAIL

BUILDING FUNCTION DISTRIBUTION

HEALTH CLUB AND TERRACES

DESIGN STORY / NARRATIVE


SITE PLAN

GROUND FLOOR LEVEL

3RD FLOOR LEVEL

HEALTH CLUB


1ST FLOOR LEVEL

2ND FLOOR LEVEL

TOWER 1 & 2 TYPICAL FLOORS

TOWER 3 TYPICAL FLOORS


STUDIO Area: 40.32 sqm Total Number Of Studios: 23 SCALE 1:100

1 bed

2 bed

2 bed+

Area: 72.24 sqm Total Number Of 1 Bed: 64 SCALE 1:100

Area: 108.36 sqm Total Number Of 2 Bed: 67 SCALE 1:100

Area: 126.42 sqm Total Number Of 2 Bed+: 45 SCALE 1:100

3 BED

3 BED+

Area: 144.48 sqm Total Number Of 3 Bed: 57 SCALE 1:100

Area: 162.54 sqm Total Number Of 3 Bed+: 48 SCALE 1:100

4 BED Area: 180.60 sqm Total Number Of 4 Bed: 16 SCALE 1:100



BEAD PRIVATE VILLA DESIGN TEAM Muhannad Assam Marta Krivosik Ramzi Omar HH Sheikh Saeed Villa (1Level)  Total Built Up Area: 1200 sqm Client: HH Sheikh Saeed Contributions: Pre concept Design, Concept Design, Facade Design. Design Development, 3D Modelling, Space Planning, Presentations, Illustrations, Concept report preparation. Managed architectural visualizations from conceptual design to final presentation.


SITE PLAN

FLOOR PLAN BUILT UP AREA :: 863 SQM TERRACE AREA :: 204 SQM



Professional

THOMAS ASSOCIATES Bangalore, India





































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