Global Development Trends, Prospects and Issues ... - Semantic Scholar

23rd TWG - GCR Meeting, IAEA Headquarters, Vienna, 5 - 7 March 2013

Global Development Trends, Prospects and Issues for SMRs Deployment Dr. M. Hadid Subki Technical Lead, SMR Technology Development Nuclear Power Technology Development Section, Division of Nuclear Power, Department of Nuclear Energy

IAEA International Atomic Energy Agency

Outline • • • • • • •

Status of Countries on Nuclear Energy Initiatives What’s new in global SMR development and deployment? Options of SMR Design & Technology Perceived Advantages and Challenges Specific Advantages and Challenges in GCR deployment Newcomer Countries’ Considerations and Plan Contribution to Nuclear Safety Action Plan #12 on Utilize Effective R&D • IAEA Events on SMR in 2013 • Summary IAEA

2

Status of Countries on NE Initiatives

Which countries deploy SMRs?

Technology developer countries (NPPs in operation) Countries with NPPs Newcomer countries

Asia Europe Africa

IAEA

Latin America

3

What’s New in Global SMR Development? mPower NuScale W-SMR Hi-SMUR

B&W received US-DOE funding for mPower design. The total funding is 452M$/5 years for two (2) out of the four (4) competing iPWR based-SMRs. Some have utilities to adopt in specific sites.

SMART

On 4 July 2012, the Korean Nuclear Safety and Security Commission issued the Standard Design Approval for the 100 MWe SMART – the first iPWR received certification.

KLT-40s SVBR-100 BREST-300 SHELF

2 modules marine propulsion-based barge-mounted KLT-40s are in construction 98%; Lead-bismuth eutectic cooled SVBR-100 & BREST-300 deploy by 2018, SHELF seabed-based conceptual PWR-SMR design

Flexblue

DCNS originated Flexblue capsule, 50-250 MWe, 60-100m seabed-moored, 5-15 km from the coast, off-shore and local control rooms

CAREM-25

Site excavation for CAREM-25 was started in September 2011, construction of a demo plan starts soon in 2012

4S

Toshiba had promoted the 4S for a design certification with the US NRC for application in Alaska and newcomer countries.

PFBR PHWRs: 220, 540 & 700, AHWR300-LEU

IAEA

The Prototype FBR is preparing for commissioning and start-up test. 4 units of PHWR-700 under construction, 4 more units to follow. The AHWR300-LEU 4 is on final detailed design stage and prepared for construction.

What’s New in Global SMR Development? (cont’d) CEFR HTR-PM ACP-100

IRIS

2 modules of HTR-PM are under construction; CNNC developing ACP-100 conceptual design, fast progress, preparing for deployment by 2018 Politecnico di Milano (POLIMI) and universities in Croatia & Japan are continuing the development of IRIS design - previously lead by the Westinghouse Consortium

Recently introduced at the 2012 IAEA SMR Meetings: ACP-100, CNNC, China

IAEA

Flexblue, DCNS, France

5

Reactors Under Construction with SMR category Country

Reactor Model

Output (MWe)

Designer

Number of units

Argentina

CAREM-25 (a prototype)

27

CNEA

1

CAREM-25

2017 ~ 2018

China

HTR-PM (GCR)

200

Tsinghua Univ./Harbin

1

Shidaowan unit 1

2017 ~ 2018

PHWR 700

640

NPCIL

2

Kakrapar 3 and 4

6/2015 and 12/2015

PHWR 700

640

NPCIL

2

Rajashtan units 7 and 8

6/2016 and 12/2016

PFBR 500 (LMFBR)

500

IGCAR

1

PFBR Kalpakkam

2015

Pakistan

CNP-300

300

CNNC China

2

Chasnupp 3 and 4

12/2016

Romania

CANDU-6

620

AECL

3

Chernavoda units 3, 4 and 5

2016, 2017, 2018

Russian Federation

KLT-40S (ship-borne)

30

OKBM Afrikantov

2

Akademik Lomonosov

2012

Slovakia

VVER-440 (V213)

405

OKB Gidropress

2

Mochovce 3 and 4

~ 2018

India

IAEA

Site, Plant ID, and unit #

Commercial Start

6

Light Water Cooled SMRs

CAREM-25 Argentina

mPower USA

IMR Japan

NuScale USA

IAEA

SMART Korea, Republic of

Westinghouse SMR - USA

VBER-300 Russia

WWER-300 Russia

CNP-300 China, Peoples Republic of

KLT-40s Russia

ABV-6 Russia

7

Heavy Water Cooled SMRs

EC6 Canada

IAEA

PHWR-220, 540, & 700 India

AHWR300-LEU India

8

Liquid Metal Cooled SMRs

CEFR China

4S Japan

IAEA

PFBR-500 India

SVBR-100 Russian Federation

PRISM USA

9

Gas Cooled SMRs

GT-HTR300 Japan HTR-PM China

PBMR South Africa

12

IAEA

GT-MHR USA

EM2 USA

10

Concept of Integral PWR based SMRs Westinghouse SMR

SMART

pressurizer CRDM

pumps Steam generators

core + vessel

Steam generators

CRDM

pumps core + vessel

IAEA

11

Integral Primary System Configuration Courtesy: Westinghouse Electric Company LLC, All Rights Reserved

X X X X XX XX X Benefits of integral vessel configuration: • eliminates loop piping and external components, thus enabling compact containment and plant size  reduced cost • Eliminates large break loss of coolant accident (improved safety)

IAEA

12

SMRs for Immediate Deployment Name

Design Organization

Country of Origin

Electrical Capacity, MWe

Design Status

1

PHWR-220

NPCIL

India

220

16 units in operation

2

PHWR-540

NPCIL

India

540

2 units in operation

3

PHWR-700

NPCIL

India

700

4 units under construction

4

KLT-40S

70

2 units under construction

5

HTR-PM

Tsinghua University

China, Republic of

200

Detailed design, 2 modules under construction

6

CAREM-25

CNEA

Argentina

27

Started site excavation in Sept 2011, construction in 2012

7

Prototype Fast Breed Reactor (PFBR-500)

IGCAR

India

500

Under construction – Commissioning in mid 2012

9

CNP-300

CNNC

China, Republic of

300

3 units in operation, 2 units under construction

IAEA

OKBM Afrikantov Russian Federation

SMRs for Near-term Deployment Organization

Country of Origin


1

System Integrated Modular Advanced Reactor (SMART)

Korea Atomic Energy Research Institute

Republic of Korea

100

2

mPower

Babcock & Wilcox

United States of America

design, to apply for 180/module Detailed certification - end of 2013

3

NuScale

NuScale Power Inc.


45/module

Detailed design, to apply for certification - end of 2013

4

VBER-300

OKBM Afrikantov

Russian Federation

300

Detailed design

5

SVBR-100

JSC AKME Engineering

Russian Federation

100

Detailed design for prototype construction

6

Westinghouse SMR

Westinghouse


225

Detailed Design

7

Super-Safe, Small and Simple (4S)

Toshiba

Japan

10

Detailed design

Name

IAEA

Design

Design Status Standard Design Approval Received 4 July 2012

Example of SMRs for Long-term Deployment

1 2 3

Name

Design Organization

Country of Origin


Design Status

IRIS

IRIS International Consortium


335

Conceptual Design

GE Hitachi


311

Detailed Design

BARC

India

300

Conceptual Design

Power Reactor Innovative Small Modular (PRISM) AHWR300-LEU using Thorium MOX Fuel

4

Integrated Modular Water Reactor (IMR)

Mitsubishi Heavy Industries

Japan

350

Conceptual Design

5

Flexblue

DCNS

France

50-250

Conceptual Design

6

FBNR

FURGS

Brazil

72

Conceptual Design

7

VK-300

RIAR

Russian Federation

100/300

Conceptual Design

8

EM2

General Atomics

USA

240

Conceptual Design

IAEA

Perceived Advantages and Challenges IAEA Observation Advantages

Challenges

Technological Issues Non-Technological Issues

• Shorter construction period (modularization) • Potential for enhanced safety and reliability • Design simplicity • Suitability for non-electric application (desalination, etc.). • Replacement for aging fossil plants, reducing GHG emissions

• Licensability (due to innovative or first-of-a-kind engineering structure, systems and components) • Non-LWR technologies • Operability performance/record • Human factor engineering; operator staffing for multiple-modules plant • Post Fukushima action items on design and safety

• Fitness for smaller electricity grids • Options to match demand growth by incremental capacity increase • Site flexibility • Reduced emergency planning zone • Lower upfront capital cost (better affordability) • Easier financing scheme

• Economic competitiveness • First of a kind cost estimate • Regulatory infrastructure (in both expanding and newcomer countries) • Availability of design for newcomers • Infrastructure requirements • Post Fukushima action items on institutional issues and public 16 acceptance

IAEA

Advantages in GCR Commercial Deployment • Potential to provide stable energy prices, secure source and reduced GHG emissions • Industrial Applications • • • • •

Non-electric applications Petroleum refineries Chemical plants Bio- and synthetic-fuels productions Coal/shale oil/oil sands to liquid petroleum

• Options to Enhance Energy Supply Security using Hybrid Energy System based on SMRs (an on-going project with EC – JRC) • Synergizing renewable-electric plants, industrial applications and small reactors based on GCR technology, with a dynamic energy switching

• Economics • • • •

Producing electricity with higher efficiency Higher burn-up Burns uranium, plutonium, thorium and MOX Fuel form easy to dispose

IAEA

17

Advantages in GCR Commercial Deployment

Options to Enhance Energy Supply Security using Hybrid Energy System based on SMRs (an on-going project with EC – JRC)

IAEA

18

Challenges in GCR Commercial Deployment • Licensing & Regulation • Primarily China, Japan, Russian Federation and the USA currently have on-going • •

GCR design development for eventual deployment. Shared-location with industrial application Multi-module applications  Control room staffing  Security requirements  Post-Fukushima safety lessons-learned for multiple-units and modules power station

• Economics • Cost Evaluation and Optimization available? • • •

Cost of nuclear should be competitive with other energy sources (LNG, coal, pipeline gas) locally Extrapolation from supplier country to siting/targeted country Merit and demerit of modularization vs stick-build in target country (promoting local content)

• Identification of Potential Global Market for GCRs • Standardization • R&Ds in Higher Temperature Applications • Reactor vessel and turbine materials • Advanced heat exchangers

IAEA

19

Newcomer Countries Considerations Robust Energy Policy

Security of Supply + GRID

Integrated Infrastructure

Affordability (Capital & electricity costs)

Proliferation resistance & physical protection

Introduction of the first Nuclear Power Plant

Economic Competitive ness

Public acceptance

Domestic Industry Participation

Nuclear Safety

IAEA

Viable financing scheme

20

Current Newcomer Countries Plan Country Bangladesh

Grid Capacity in GWe 5.8

Vietnam

15.19

Jordan

2.6

Current Deployment Plan 2 x 1000 MWe PWRs in Rooppur in 2018 4 x 1000 MWe PWRs in Ninh Thuan #1 by 2020 4 x 1000 MWe PWRs in Ninh Thuan #2 by 2025 2 x 1000 - 1100 MWe PWR in + possible interest in SMR

UAE

23.25

4 x 1400 MWe PWR in Braka by 2018

Belarus

8.03

2 x 1200 MWe PWR in Ostrovets by 2018

Turkey

44.76

4 x 1200 MWe PWR in Akkuyu by 2022

Malaysia

25.54

2 x 1000 MWe LWRs, 1st unit by 2021

Indonesia

32.8

2 x 1000 LWRs, with potential interest of deploying Small Reactors for industrial process and non-electric applications by 2024

IAEA

Commercial unavailability limits Newcomer Countries in advanced SMR Technology Selection21

New entrants with active participation in IAEA’s Programme on SMR Country

Grid Capacity in GWe

Current Plan

Rationales (in addition to the small grid capacity)

Mongolia

0.83

Potential for future SMR deployment

Energy supply security + non-electric application(s)

Egypt

24.67

Had considered 1000 MWe Class LWR and/or SMR


Ghana

1.99


Energy supply security

Kenya

1.71



Morocco

6.16



Nigeria

5.9



Sudan

2.34



Tunisia

3.65



Algeria

10.38



Albania

1.6



Croatia

4.02



Jamaica