Download - 15_MASDARCITY
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September 10
Building the Worlds Most Sustainable City
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What is Masdar City?
A Sustainable City
providing the highest quality
of life with the lowest
environmental footprint.
100% Renewable Energy
Zero Waste
Net Zero Carbon
Fossil Fuel Free Zone
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What is Masdar City?
Initiative of the Leadership of the Emirate of Abu Dhabi
Site area: 700 hectares / 7 Sq/KM
Mixed use city
Population:
40,000 residents
50,000 commuting = 90,000 people
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MASDAR
Abu
Dhabi
Airport
Yas Island
(Formula 1)
Saadiyat Island
(Louve)
(Guggenheim)
Khalifa
City
Abu Dhabi
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Agenda
What makes Masdar City Unique?
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Traditional Arabic City Design
Narrow streets
Natural shading
High Density
/Low Rise Living
Public spaces
Mixed Use
Walkable
Fez
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People and Community
High Density /
Low Impact
Public Squares
Mixed Use Development
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p8
Sense of PlaceResearch and
Learning ArchitectureQuality of Place
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Life in Masdar City Masdar HQ Exterior
p10
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Life in Masdar City Masdar HQ Interior
p11
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Life in Masdar City Civic Square
p12
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Life in Masdar City Streetscapes
p13
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Life in Masdar City Terrace
p14
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What makes Masdar City Unique?
A graduate-level, research-driven institution in partnership with MIT
Masdar
Institute
The City will strive towards a zero waste objectiveRecycling /
Waste to
Energy
The City will contain pioneering public transportation systems
Innovative
Transporta-
tion System
Building design will ensure the latest use of energy efficient technologies and smart design
Building
Design
The City will be powered with Renewable energyRenewable
Energy
p15
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Building Design Waste Transportation
Energy
Generation
Design of a conventional city
Conventional Oil & Gas Landfill Fossil fuel
80% 13% 7%
1,100,000 Tonnes CO2
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Design of Masdar City
Energy Efficient RenewableRecycling /
Waste to Energy
Electric /
Solar
-56% -24% -12% -7%
= 0 CO2
Carbon offsetting /
Carbon Sequestration-1%
Building Design Waste TransportationEnergy Generation
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Energy
100% Powered by Renewable Energy
170MW from Photovoltaic
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100% Renewable Energy Solutions
Concentrated Solar Power (26%)
Photo Voltaic (53%)
Evacuated Thermal Tube
Collector (14%)
Waste to Energy (7%)
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MASDAR Water Strategy
Reduce water
leakage to 3%
Recycle 90%
of grey water
Reduce consumption
to
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Bundled projects scenarios Onsite vs Regional
On-Site Scenario:
Study for On-Site Groundwater use
Seawater or Off-Site GW supply w/
on-site desalination
Brine Treatment and Reuse
Local Waste for 3 MW WtE
Regional Scenario:
ADDC Water Supply
Regional Waste for 10 MW WtE
CSP from Small Square
Game Changing
Issues:
Green Buildings
Hydro Study re GW
Volume
WtE Demand
Geothermal Resource
On-site Desalination
Greywater Recycling
PRT vs. Metro
Small Square Timing
MissesMeets
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CH2M HILL Proprietary - Reuse Prohibited
On-Site scenario description
September 10 p22
Base Projects & Primary Projects
Dry MRF + In-Vessel Composting Biomass burner construction wood waste Waste minimization and AWCS Alternative water options-Dew/Fog collector Reduce undercroft lighting and ventilation Reduce non-resident building electrical load Geothermal energy + pumping to demand Reduce street lighting load Add 1 MW PV ground mount to 10 MW farm Eliminate blackwater treatment electrical load
use biogas from anaerobic digestion Reduce water distribution energy load Water supply from seawater or groundwater RO desalination plant on-site Flora/Fauna/Wildlife/People optimization
Secondary Projects
Install 3 MW WtE for non-recyclables Increase rooftop PV generation + cleaning develop recycle market Study on-site hyper-saline ground water Brine treatment and reuse of products Increase CSP electrical/thermal cooling ratio Increase electrical distribution efficiency Reduce ICT and PRT demand
Use Seawater or Off-Site Ground Water for potable water w/Green Power
at intake or well location
On-site Desalination, Brine Management & Reuse
All Energy Projects in top 31 ranked Roadmaps
11% Energy gap compare to 31% gap
for demand < 40% AD reference w/Roadmaps
28% Energy gap compare to 44% gap
for 10% better than AD reference results
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Months
MW
h/d
ay
Baseline Demand 10% AD Reference Onsite Electric Supply Current Onsite Demand Current Baseline Demand
On-Site Scenario
Electrical Supply vs. Demand
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CH2M HILL Proprietary - Reuse Prohibited
Onsite cost-benefits: demand comparisons
Develop & Strategy Investment = $46 million
Spending in 2009 = $14 million
Spending in 2010 = $25 million
Spending in 2011+ = $ 7 million
Notes:
1. Cost shown are based on current information and therefore order-of-magnitude (+50%, -30%) in nature for comparison purposes only. Once a scenario(s) is selected, a more thorough and
detailed delivery plan and cost estimate will be prepared.
2. Investment to concept noted above includes investigation studies, pilot project, demonstration and feasibility studies only.
Scenario 1a
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40
60
80
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Energy
Water
Waste
Biodiversity
Goal Scenario 1a
Projected Demand
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CH2M HILL Proprietary - Reuse Prohibited
Regional scenario description
September 10 p24
Base Projects & Primary Projects
Dry MRF + In-Vessel Composting Biomass burner construction wood waste Waste minimization and AWCS Alternative water options-Dew/Fog collector Reduce undercroft lighting and ventilation Reduce non-resident building electrical load Geothermal energy + pumping to demand Reduce street lighting load Add 1 MW PV ground mount to 10 MW farm Eliminate black water treatment electrical load
use biogas from anaerobic digestion
Reduced demand from small square delay Water supply from ADDC Flora/Fauna/Wildlife/People optimization
Secondary Projects
Install 10 MW WtE for non-recyclables + additional imported waste
Increase rooftop PV generation + cleaning develop recycle market CSP production on small square Increase CSP Electrical/Thermal cooling ratio Increase Electrical Distribution efficiency Reduce ICT and PRT demand
Use ADDC for majority of potable water supply
Import waste for WtE Generation
Determine ROI for Small Square CSP
3% Energy gap compare to 31% gap
for demand < 40% AD reference
21% Energy gap compare to 44% gap
for 10% better than AD results
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1000
1500
2000
2500
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Months
MW
h/d
ay
Current Regional Demand Regional Electric Supply Regional Demand 10% Abu Dhabi Current Baseline Demand
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CO2e concept
Embedded CO2e
Buildings & Platform (Dcarbon8)
Infrastructure (TBD)
Regional Infrast. (TBD)
Operations CO2e
Infrastructure (McKinsey)
Utilities (McKinsey)
Embedded CO2e
Food (TBD)
Flora/Fauna (TBD)
People choices (TBD)
CO2e Balance
Results in
6 months
to
2+ years
Concept
Design
in
9 months
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CH2M HILL Programme Management
Responsibilities include:
Design
Health, Safety & Environment
Sustainability
Project Delivery
Program and Document Controls
Procurement
Performance Indicators
Technology
City Governance
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PM Objectives on Masdar City
The Masdar City Vision is incorporated in the delivery of
the overall programme.
The delivery of Masdar City to established budgets and
schedules.
The delivery of Masdar City to achieve the established
sustainability standards.
The delivery of Masdar City to achieve the established
quality standards.
Provide leadership, management and direction on all
aspects of the delivery of Masdar City to achieve these
objectives.
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p28
Masdar City Under Construction
Masdar Institute - Phase 1a
45,000 sq.m
August 2009
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Masdar City Layering
PV roof
Building plots
Raised street level
PRTPrimary infrastructure
Abu Dhabi metro
p29
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Integrated Transport
Masdar City will be the first land-based city to operate without fossil fueled vehicles
Walking, electric vehicles, cycling, PRT and LRT are the modes of transportation within Masdar City.
With 40,000 commuters per day, Masdar City will have strategically placed parking areas for fossil-fueled vehicles
PRT Fast Facts
PRT Vehicles: 3,000
PRT Stations: 85-100
FRT Vehicles 810
PRT Trips per day: 135,000
Max. Walking Distance to
PRT Station:
150m
LRT Trips per hour: 5,000 people
Personal Rapid Transit (PRT)
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Mobility
LRT Station
PRT Station
Public Green
Space
Public Park
Neighbourhood
Centre
Place of
Worship
Playground
Work places
Shops
150 m
Cycle / Segway
Walking 2-3min
School
300 m
p31
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Supply Chain Sustainability
Definition
Supply Chain Sustainability (SCS) is the collaborative effort of multiple stakeholders to design, build, and operate a seamless, value-added supply chain to meet MASDARs goals and objectives
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SMS - A Tool to Deliver the Masdar Vision
Plan
Monitor
Visualize and Analyze
Foot printSupply ChainProducts and Materials
Reporting
Operate the City
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Masdar City
Governance Department
What it is!
What it is not!
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Masdar City
It is NOT a City in the traditional Western definition
No elected officials
Not a separate public entity
It is a Private Development
Tenancy Codes & Specific sustainability rules
Specific guidelines on fit-out requirements
Specific sustainability goals (OPL)
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Sustainability includes the City Governance
Department
The City Governance Department has worked to incorporate
and integrate sustainability, expressed as the One Planet
Living Principles, into:
Governance
Management and Operations planning
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Continuing Challenges
Integration of the infrastructure
systems
Sourcing new sustainable
technologies
Increasing efficiencies of current
technologies
Supply chain mapping of
materials and products
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Next steps
Infrastructure associated
development
Phase 1 podium construction
Architectural competitions for
iconic buildings
Optimising real estate mix