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TRANSCRIPT
- NERS 2016 -
EDF Presentation
Prague,
November, 9th 2016
Patrick ZAK EDF SA
New Nuclear Projects and Engineering
Pre development & Marketing Director
| 2 NERS 2016 Nov. 2016
SUMMARY
1.EPR Technology and Safety Principles
2.Licensing
3.Localization
4.Financing
| 3
1. EPR TECHNOLOGY A PROVEN AND EVOLUTIONARY TECHNOLOGY
Evolutionary design based on the most advanced French and German technologies, N4 & Konvoi
Large Power: 4,590 MWth, 1,650 MWe
High efficiency: up to 37%
Target Design Availability: 92% (EUR methodology)
Lower operating costs: -20%
Low fuel costs: -15% U consumption
Design service life: 60 years
A proven design, based on the most powerful
reactors operating in Europe
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The EPR reactor is designed to resist to exceptional events
and prevent damage to the surroundings
The Design of the Safety Systems is based on Redundancy, Diversity
and Complementarity
spray nozzles
xx
x
x
FL flow limiter
CHRS
water level in case of waterinjection into spreading compartment
(2x)
passive
spreading compartment
melt flooding via cooling deviceand lateral gap
in-containment refuelingwater storage tank
flooding device
Complementarity (between active and
passive systems)
Diversity (against
Common Cause
Failures)
Redundancy (against
single failure)
4 train systems in
4 Safeguard Buildings
1
2 3 4
Diversified Emergency
Diesel Generators
Core Catcher &
Containment Spray
1. EPR SAFETY PRINCIPLES Reactor safety approach
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Diesel building door
Double wall, up to 1.8m thick
Large commercial airplane crash resistant:
External reinforced concrete containment
protecting critical buildings
High earthquake resistance
Doors able to withstand explosions
and flooding
Ability to withstand extreme external events
Airplane Crash
resistance shell
Common raft for
nuclear island
1. EPR SAFETY PRINCIPLES Designed to meet the most demanding nuclear and industrial safety standards
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Independent cooling trains
+ physical separation
6 protected, redundant and
diversified emergency
diesel generators
Large protected water reserves
Robustness of cooling functions
IRWST2 (1800 m3)
EFWS1 tanks
(4x400 m3)
Fire fighting
tank
(2600 m3)
1: EFWS Emergency Feed Water System
2: IRWST In Containment Refueling Water Storage Tank
1. EPR SAFETY PRINCIPLES Designed to meet the most demanding nuclear and industrial safety standards
Core catcher to collect and cool the
corium
Passive hydrogen recombiners to
avoid H2 detonation
No impact on local populations in the event of
serious accident
Reactor pit
IRWST
Spreading area
Sacrificial concrete
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Construction license granted in 4 countries
Design license well advanced in US
In line with the safety objectives of the Western European Nuclear Regulators‘ Association (WENRA)
2. LICENSING A design already assessed and licensed by various independent
bodies and safety authorities, worldwide
NNSA 国家核安全局
A smoother licensing phase supported by experienced team
involved in numerous licensing contexts
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3 LOCALIZATION Distinct areas and levels offering opportunities for a wide range of
supply and jobs
Within a wide range of opportunities in Engineering,
Procurement, Construction, Operating & Maintenance
Balance of Plant
10%
Conventional
Island
20%
Nuclear Island
40%
Civil & marine
works
30%
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1. Sourcing – Establish the master supplier list – Initiate first contact visits – Send Request For Interest (RFI)
2. Pre-selection – Preselect suppliers according to RFI feedback analysis – Visit supplier for pre-assessment (quality management,
design, manufacturing, etc.)
3. Pre-Qualification – Define action plan and follow-up – Carry out product or process qualification tests as necessary – Send a blank RFQ for detailed technical assessment
4. Qualification – Approve supplier once qualification is satisfactory before the
contract is signed (Approved Vendor List)
Steps
1. Sourcing
2. Pre-selection
3. Pre-Qualification
4. Qualification
Approved Vendor List
No - Go
No - Go
No - Go
Tim
es
ca
le ~
2 y
ea
rs
Go
Go
NPCIL or French team
NPCIL or French team
French team support
French team support
Go
3 LOCALIZATION A step by step and robust Suppliers Qualification Process
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4. FINANCING Nuclear power plant project key bankability requirements
KEY NON FINANCIAL REQUIREMENTS
NUCLEAR SAFETY FIRST !
KEY FINANCIAL REQUIREMENTS
Strong support from the State
to provide visibility on long-term political
commitment at national and local levels
Shareholders’ reputation
and Financial strength Proven / Approved Technology
Strong and stable legal and regulatory
framework
Nuclear project management & operational
experience of the Owner/Operator
Key stakeholders support
including Unions and Public Acceptance
solid integration of environmental and
social impacts
Long term visibility and certainty on
revenues during operations
Experienced main contractors with in-
house design capabilities
KEY BUSINESS REQUIREMENTS
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4. FINANCING Sources and possible financing mix for the investment
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Development
Phase
Construction
Phase
Decommissioning
Phase
Operation Phase
FID First
concrete
pouring
End of loan
reimbursement
Shareholders' Equity
Commercial banks
Multilateral banks, development banks
Export Credit Agencies
Pension /
Infrastructure /
Sovereign funds Refinancing options Owner-Operator
State-linked financial institutions
Purely financial investors
Investment covers engineering and construction costs, owner’s costs, debt interests,
long-term liabilities (decommissioning, waste and spent fuel management)
Building of decommissioning funding through
provisions
Decommissioning
funding drawdown
Commercial
Operation Date
| 12 NERS 2016 Nov. 2016
Thank you for
your attention