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Presented By:
MD KHUBAIB RASHIDI
BRANCH-CIVIL,
SEMESTER – 8TH ,
USN 1NC11CV724
Under the Guidance of –
MR NAVEEN KUMAR K.R
(Asst. professor, NCET)
2. Contents
2
Introduction
Records
Challenges
Excavation
Foundation
Structural System
Shape
Buttressed core
Casting of Structure
Concrete Used
Casting of RCC walls
Mechanical Rooms
Elevators
Cladding
Test for Cladding
Glass Panels
The spire
Evacuation and Fire Safety
Environment friendly
Conclusion
References
3. Introduction
3
The Burj Khalifa is the ever built tallest
man made structure.
Location: Dubai, United Arab Emirates
Project Completion: 2010
Site Area: 104,210 m2
Project Area: 454,249 m2
Number of Stories: 162
Building Height: 828 m
Use: Commercial + Office,
Hospitality, Mixed Use,
Residential
Architect : Adrian Smith
Structural Engineer: Bill Baker
The tower was constructed by a UAE based construction company
EMAAR.
5. Records
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Tallest existing structure : 828 m ( 2,717 ft )
Building with the most floors : 162
Highest vertical concrete pumping( for a building) :
606 m
World’s highest elevator installation
World’s longest travel distance elevators : 504 m
World’s tallest structure that includes residential space
World’s highest installation of an aluminum and glass facade : 512 m
World’s highest night club : 144th floor
World’s highest restaurant (Atmosphere) : 122nd floor at 442 m
World’s second highest swimming pool: 76th floor.(world’s highest
swimming pool is located at 118th floor of RITZ CARLTON hotel at
international commerce center, Hong Kong)
6. Challenges Faced
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High Temperature of Dubai resulted in shorter setting time.
Devastating sandstorms in the area.
Wind Velocity at such a height.
Loose and weak soil in the region.
Formation of vortex.
Heat resistance of structure.
Speed of construction.
7. Excavation
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The soil stratum of Dubai is very week so they had to excavate up to 50m
deep to get a hard rock structure.
But the rock that they found was fragile and saturated with ground water
So that any hole made will be cured immediately.
The engineers filled this with a viscous polymer slurry.
This pushes the rock and the ground water to the edges of the boreholes to
keep it open.
This slurry is denser than water and liter than
concrete, so that when concrete is pumped the
concrete displaces the fluid and forms the
foundation.
194 piles were constructed
for avoiding the sinking of this
structure.
8. Foundation
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The superstructure is supported by a large reinforced concrete mat,
which is in turn supported by bored reinforced concrete piles. The
design was based on extensive geotechnical and seismic studies.
The 1.5 meter diameter , 43 meter long piles represent the largest and
longest piles conventionally available in the region.
A high density, low permeability concrete was used in the foundations.
Cathodic protection system
under the mat, to minimize
any detrimental effects form
corrosive chemicals in local
ground water.
9. Structural System
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The spiraling “Y” shaped plan was utilized to shape the structural core
of Burj Khalifa.
This design helps to reduce the wind forces on the tower, as well as to
keep the structure simple and faster constructability.
The structural system can be described as a “buttressed core”, and
consists of high performance concrete wall construction.
At mechanical floors, outrigger walls are provided to link the perimeter
columns to the interior wall system, allowing the perimeter columns to
participate in the lateral load resistance of the structure
10. Shape
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They made a study on the Sears tower at Chicago.
Burj Khalifa was designed in triangular shape because it was suitable to
deflect the wind to different ways.
Triangular shape reduces vortex effect.
11. Buttressed core
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The three wings allow for greater building height by buttressing one
another by a central core hence it is called buttressed core structural
system
This buttressed core is a six sided central piece
So that it is called a Hexagonal Hub
This hub is surrounded by the three wings
These three wings afford the torsional resistance of the tower.
12. Casting of the structure
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The casting of the whole structure is mainly done by two materials
1. Concrete
2. Steel
Over 30,000 tons of steel were used
About 250,000 m3 concrete was also used
The reinforced concrete acts as the backbone of the whole structure.
The pump needs 630HP to pump about 25000 tons of concrete
It had took about 14mints for reaching the concrete to the 150th floor
They completed every new floor in 3 day .
13. Concrete used
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High performance concrete(HPC) having Low permeability, High
durability
C80-C60 cube strength concrete was used
Two largest concrete pumping machines in the world were used for this
purpose
For reducing cracks due to high temperature concreting was done only
at night
14. Casting of RCC walls
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For simplicity and speed the engineers made no. of steel cages
These cages were inserted to the formworks that can be moved easily
After installation of cages concrete was filled in these formworks
Only took 12hrs for the setting of concrete.
After setting the concrete the formworks would move to the next level
with in 2hrs.
15. Speed of construction and Cranes
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For erecting such a structure in the sky steel and glass panels have to be
raised
The cranes consist of two plates on the two sides
It could jump from one floor to the another
So that they were called the kangaroo cranes
So as to speed up the construction the RCC walls was done in a simple
and clever engineering way
16. Mechanical Floors
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Seven double-storey height mechanical floors house the equipment that
bring Burj Khalifa to life.
Distributed around every 30 storeys.
house the electrical sub-stations, water tanks and pumps, air-handling
units etc, that are essential for the operation of the tower and the
comfort of its occupants.
17. Elevators and Escalators
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The Burj can accommodate about 35,000 people at a time
Consist of 57 elevators and 8 escalators
The biggest elevator carries about 46 people at a time
These elevators travel at a speed of 35km/hr
The Burj has a service/firemans elevator which have a capacity to hold
about 5,500kg
And this is the worlds tallest service elevator.
18. Cladding of the tower
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The Burj is claded with high-tech glass which forms as a curtain wall.
The exterior cladding is comprised of reflective glazing with aluminum and
textured stainless steel spandrel panels and stainless steel vertical tubular fins.
If the whole cladding has to be done with high-tech glass which will cost about
100 million dollars.
19. Test for the Cladding against Storm
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The cladding should withstand the heavy sand storms that with in
include water and dust
Prototypes were selected and with the help of propellers artificially
created storm was allowed to hit the glass panels at a greater speed
The glass panels withstands the storm up to 75km/hr .
20. Glass panel
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The outer layer of panel is coated with a thin layer of metal so that it
reflects the UV radiations
The inner layer of panel is coated with thin layer of silver so that it
reflects the IR radiations.
The exterior cladding is comprised of reflective glazing with
aluminum and textured stainless steel spandrel panels and stainless
steel vertical tubular fins.
Close to 26,000 glass
panels, each individually
hand-cut, were used in
the exterior cladding of
Burj Khalifa.
21. The Spire
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The crowning touch of Burj Khalifa is its telescopic spire comprised of
more than 4,000 tons of structural steel.
The spire was constructed from inside the building and jacked to its full
height of over 200 metres (700 feet) using a hydraulic pump.
Creates a sense of completion for the landmark.
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The Burj is naturally fire resistant as the concrete backbone is already fire
resistant
More than that the Burj consist of refuge rooms
These refuge rooms are made of RCC and fire proof sheets that resist the
heat up to 2hrs
These refuge rooms has a special supply of air which pumps through fire
resistant pipes
There are 9 refuge rooms, one in every 30 floors.
The Burj fire safety system mainly consist of 3 components
i. A smoke detector
ii. Water sprinkler
iii. High power fans
As the water is sprinkled the fire gets extinguished and
the high power fans supplies fresh air by pushing the
smoke out
Evacuation and Fire Safety
23. Environment Friendly
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Water heating
The Burj utilizes solar power
378 panels each with an area of
2.7sq.m were installed
These panels have the
ability to heat 140,000 lit
of water when supplied
with just 7hrs of day light.
This is equal to 32,000KW of
energy provided .
24. Environment Friendly
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Condensate recovery system
Collects water condensate from the air conditioning system
And diverts it to an irrigation tank
It provides about 15 million gallons of water per year
This water is used for irrigation of landscape around the Burj
Reduces water related expenses
25. Environment Friendly
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Air ventilation
Air ventilation provided at the top reduces the energy consumption
Air at the top of the building is cooler, has low density and relatively
humid
Its ideal for ventilation
Less energy is required to maintain the comfortable condition
26. CONCLUSION
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More than just the world's tallest building, Burj Khalifa is an example
of international cooperation, and an emblem of the new, dynamic and
prosperous Middle East.
In fewer than 30 years, this city has transformed itself from a regional
centre to a global one.
It represents a significant achievement in terms of utilizing the latest
design, materials, and construction technology and methods, in order
to provide an efficient, rational structure to rise to heights never before
seen.
27. References
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Burland J.B., & Mitchell J.M (1989) piling and deep Foundation.
Proc. Int. conf. on Piling and Deep foundations, London, May 1989.
Brief on the Construction Planning of the Burj Dubai Project, Dubai,
UAE. Ahmad Abdelrazaq, S.E., Kyung Jun Kim and Jae Ho Kim.
Fleming W.G.K., Weltman, A.J., Randolph, M.F., Elson W.K. (1994)
piling Engineering.
Poulous & Bounce (2008).Foundation Design For burj dubai- The
World’s Tallest Building, August 2008.
Validating the dynamics of the burj khalifa, Ahmad Abdelrazaq.
William F. Baker, D. Stanton Korista and Lawrence C. Novak (2007)
Burj Dubai: Engineering The World’s Tallest Building, November 2007.