7/27/2019 S1a2 NEDO Naruse

1/45

Technical Cooperation throughNEDO International Projects

February 15, 2010

Shigeo NaruseDirector General

International Projects Management Division

Energy and Environment Technology Center

7/27/2019 S1a2 NEDO Naruse

2/45

(1) What is NEDO?

(2) NEDOs R&D Activities

(3) International Activities

(4) Recent Developments & NEDO

Activities in India

2

7/27/2019 S1a2 NEDO Naruse

3/45

(1) What is NEDO ?

3

7/27/2019 S1a2 NEDO Naruse

4/45

Approximately 1,000

Approximately US$2.4B* =12,000 Crore Rs** =\234.7Bin FY 2009

*$1=\100**\100=50Rs

Oct. 1980: Established as New Energy Development Organization

Oct. 1988: Activities expanded to include industrial technology R&D; name changedto New Energy and Industrial Technology Development Organization

R&D related to industrial technology, new energy and energy efficiency

technologiesIntroduction and deployment of new energy and energy efficiency technologiesOther related activities

4

ActivitiesActivities

HistoryHistory

PersonnelPersonnel

FY2009 BudgetFY2009 Budget

Profile of NEDO

7/27/2019 S1a2 NEDO Naruse

5/45

National R&D Scheme in Japan

Council for Science and Technology PolicyCouncil for Science and Technology Policy

Develop National-level Strategy

Coordinate Ministry Policies

Chair: Prime Minister

Other MinistriesOther Ministries

Budget

Ministry of Economy, TradeMinistry of Economy, Trade

and Industry (METI)and Industry (METI)

Ministry of Education,Ministry of Education,

Culture, Sports, Science andCulture, Sports, Science and

Technology (MEXT)Technology (MEXT)

NEDONEDO

IndustryUniversities

R&D Management

Public Research Laboratories

Grants Subsidies

(Consortium)

Private CompaniesUniversities

4

7/27/2019 S1a2 NEDO Naruse

6/45

6

Organization of NEDO(as of September 2009) General Affairs and Policy Planning Department

Accounting Department

Assets Management Department

Information and Systems Department

Industrial Technology Center

Research and Development Promotion Department

Nanotechnology and Materials Technology Development Department

Biotechnology and Medical Technology Development Department

Washington D.C., Paris, Bangkok, Beijing, New Delhi

Kyushu, Hokkaido, Kansai

AuditorAuditorss

Head OfficeHead Office

Branch OfficesBranch Offices

ChairmanChairman

PresidentPresident

Executive DirectorsExecutive Directors

Overseas OfficesOverseas Offices

Energy and Environment Technology Center

Environment Technology Development Department

Energy and Environment Policy Department

New Energy Technology Development Department

Energy Conservation Technology Development Department

Electronic and Information Technology Development Department

Personnel Affairs Department

Kyoto Mechanisms Promotion Department

AuditorAuditorSupport OfficeSupport Office

Fuel Cell and Hydrogen Technology Development Department

Clean Coal Projects Department

Project Evaluation Department

Inspection and Operational Management Department

Machinery System Technology Development Department

7/27/2019 S1a2 NEDO Naruse

7/45

7

(2) NEDOs R&D Activities

7/27/2019 S1a2 NEDO Naruse

8/45

81974

1980

1997

2000

1992

(Sunshine Project Initiated)

Establishment of NEDO

TF-Si Solar Cells

Crystalline SiliconSolar Cells

II-VI compound

Solar cells

Amorphous Sil iconSolar Cells

Residential PV System Technology

Low Cost SOG-Si Production Process

1MW Demonstrate

PV Plant (Saijyo)

PV System Demonstration

CIS Solar Cells

III-V High-eff. Solar cells

Basic Technology for Silicon

Solar Cells (wafer, cell-process)

500kW Pilot Production- Line for mc-SiSolar Cells

Technology for a-Si Solar Cells Production

1MW PV Power Plant

Low Cost mc-Silicon Solar Cells Production Technology

(Efficiency = 17.2%, 189 yen/W)

Thin Film Silicon Solar Cells (140 yen/W)(New Sunshine Project Completed)

NEDOs Present R&D Programs for Low Cost

Solar Cell and Module Production

BIPV module

Grid ConnectedPV System

BSF

Textured surface

Printing fine-electrode

AR-coating

Glass Substrate

Textured TCO

a-Si Top Cell

Sun-Light

poly-Si

Bottom Cell

Back Reflector

Interlayer

Japans PV R&D Achievements

Hybrid TF-Si Solar Cells

R&D Tasks R&D ResultsExamples of Programs (Energy Area)

F l C ll d H d T h l i R&D t NEDO

7/27/2019 S1a2 NEDO Naruse

9/45

FY2006

Fuel Cell and Hydrogen Technologies R&D at NEDO

Development of Highly Durable Membrane

LPG Reformers (2006-2008)

Development of SOFC System

Technology (2004-2007)

Development for Safe Utilization and Infrastructure

of Hydrogen (2003-2007)

FY2007 FY2008 FY2009 FY2011FY2010FY2005

PEFC

SOFC

Hydrogen

Codes &

Standards

Demonstrative

Research

Strategic Development of PEFC Technologies for

Practical Appl ication (2005-2009)

Research on Nanomaterials forHigh Performance Fuel Cells (2008-2014)

Fuel Cell Cutting-Edge Scientif ic Research Project

(METI: 2005-2007) (NEDO: 2008-2009)

Development of System and Elemental

Technology on SOFC (2008-2012)

Advanced Research on Hydrogen Storage Materials

(2007-2011)

Fundamental Research Project on Advanced Hydrogen

Science (2006-2012)

Development of Technologies for Hydrogen Production,

Delivery and Storage Systems (2008-2012)

Establishment of Codes & Standardsfor Hydrogen Economy Society (2005-2009)

Demonstration of Residential PEFC System forMarket Creation (2005-2009)

Demonstrative Research on SOFC (2007-2010)

Japan Hydrogen & Fuel Cell Demonstration Project

(METI: 2006-2008) (NEDO: 2009-2010)

7/27/2019 S1a2 NEDO Naruse

10/45

10

NEDOs Electric Energy Storage System R&D

Development of

Fundamental

Technologies for

Next-generationSatellites

Research and

Development of an

Energy Storage

System Using

AdvancedBatteries

Development of

Lithium Battery

Technology for

Use in FCV

Development of

High Performance

Battery System forNext-generation

Vehicles

Advanced Battery Electric

Energy Storage System

Development (LIBES)

FY2002 FY2006

85 90 95 00 05 10

FY2007 - FY2011

FY1992 FY2001

FY2003 FY2007

FY1980 FY1991

Li-ion

NAS, Zn-Br, Zn-Cl and RF Ni-MH, Li-ion

R&D Initiative for

Scientific Innovation of

Next-generation

Batteries

FY2009 FY2015

Grid-

Development of an

Electric EnergyStorage System for

connection

with New

Energy

Resources

FY2006 FY2010

7/27/2019 S1a2 NEDO Naruse

11/45

High-efficiency Heat Pumps

11

Technology is applicable to air conditioning and hot

water supply systems, which account for nearly 50%

of CO2 emissions in commercial/residential sector.

Further emission reductions can be expected with

this technology, which has drastically improved

efficiencies over conventional technology.

COP*

5.0

2002 2006 2010

2050

Twicecurrentlevels

10.0

All-in-one CO2 HPWH**

Conventional gas

water heater

Conventional CO2 HPWH**

*Coefficient of performance **Heat pump water heater

Cool Earth-Innovative

Energy Technology

Target

Air conditioning(heat from groundwater

Air conditioning& hot water heater(using desiccant)

0

7/27/2019 S1a2 NEDO Naruse

12/45

12

To develop technology

for long-life, highly-

efficient organic ELelement with high color

rendering of white

illumination and high

brightness by applying amultiphoton element

structure.

OLED Technology for High-efficiency Lighting

Project Outline

FY2004-FY2009

Project Duration

Residential Power Consumption

TV

10%

Clothes dryers

3%

Others

20%

Electriccarpets

4%

Air

conditioners

25%

Heated toilet

seats

4%

Dishwashers

2%

Refrigerator

16%

Lighting

16%

Directional

Light SourceDiffused Light Source

Pendant LightsIncandescent Lamps

OLED LED

Down Lights

Ceiling Lights

Spotlights

Bracket Lights

Fluorescent Lamps

Retail and

CommercialGeneral Households

7/27/2019 S1a2 NEDO Naruse

13/45

Grid Connection Technology

Wakkanai Solar Power

- Large-scale PV system

- Development of system stabilization technologies

Hokuto Solar Power

- Output control system using PCS,

storage cells

Ota Grid-Interconnection of Clustered

Photovoltaic Solar Power Systems

- Voltage fluctuation measures forinter-connect

solar power systems

- Testing ofstand-alone operation

Okinawa Stand-alone New Energy Systems- System stabilization when introducing large so

power sources

Hachinohe Micro Grid

- Demand matching within micro grid

Tomamae Wind Farm

- Power storage techniques to handle

short-term output fluctuations

- Output forecasting methods

World-leading Technologies- System stabilization control technology

- Energy efficiency technology

- Demand side technology

(Source: NEDO Proving tests related to Smart Gri

7/27/2019 S1a2 NEDO Naruse

14/45

14

(3) International Activities

7/27/2019 S1a2 NEDO Naruse

15/45

15

Collaboration through Parallel Funding

Collaborative ActionCollaborative ActionCollaborative Action

NEDONEDO

Collaborative Work

R&D&I, road mapping, evaluation, etc.

Collaborative WorkCollaborative Work

R&D&I, road mapping, evaluation, etc.

Teamsin foreign countries

Teamsin foreign countries Team

in Japan

Teamin Japan

PartnersPartners

in foreign countriesin foreign countries

Support

Support

Domestic R&D support

schemes that place a highvalue on internationalcollaboration (subsidies orentrustment)

Concentration multi-junction solar cells (EU)

Mi id D t ti i L Al N M i

7/27/2019 S1a2 NEDO Naruse

16/45

16

Microgrid Demonstration in Los Alamos, New Mexico

Demonstration of concentration power storage or home demand response

9 Concentration PV generation and power storage system will be installed on dist ribution l ines of about 2 to 5 MW.

9Experiments on absorbing PV output f luctuations will be conducted using various PV introduction efficiencies obtained by changinggrid formation.

9 A d istr ibut ion network w ith high operabi li ty wil l be installed and demonstrated by introducing smart d istr ibut ion equipment

(distribution equipment with IT capabilities).

Smart

grid

house

Microgrid Demonstration in Commercial Area in Albuquerque

7/27/2019 S1a2 NEDO Naruse

17/45

Microgrid Demonstration in Commercial Area in Albuquerque

Demand response demonstration using facilities in industrial or

commercial buildings

9 Project is designed to demonstrate highly reliable building power system that can continue operating by using power

storage systems, gas engine cogeneration, fuel cells, a heat storage tank, solar cells, etc. when grid connection to

buildings is cut.

9 It will be demonstrated that solar output fluctuations on a microgrid can be absorbed by using EMS in buildings and

grid and by controll ing building facilities.17

7/27/2019 S1a2 NEDO Naruse

18/45

NEDO Projects in Asia

18

Energy Efficiency Model Projects

(46 projects in 9 countries)

Coal Utilization Model Projects

(30 projects in 6 countries)

International Cooperative Demonstration

Projects Utilizing Photovoltaic PowerGeneration Systems

(21 projects in 10 countries)

As of April2009

7/27/2019 S1a2 NEDO Naruse

19/45

19

(4) Recent

Developments & NEDOActivities in India

7/27/2019 S1a2 NEDO Naruse

20/45

Growing Energy Supply in India

Supply will double by 2030

Equivalent to adding one more Japan in 20 years

SourceHandbook of Energy & Economic Statistics in Japan, 2009

2006Japan: 528

India: 556

Primary Energy Supply

7/27/2019 S1a2 NEDO Naruse

21/45

Electricity Generation Peak Demand/Supply

12% Shortage

7/27/2019 S1a2 NEDO Naruse

22/45

Energy Production and Imports (2008)

2Source: BP statistical review, 2009

73% of oil, 26% of natural gas and 16% of coalare imported

CO2 Emissions

7/27/2019 S1a2 NEDO Naruse

23/45

CO2 Emissions

Worldwide CO2 emissions (2006)(Million t)

SourceHandbook of Energy & Economic Statistics in Japan, 2009

Total CO2 emissions volume is 4th highest in the world.

Emissions per capita are 1.1t.

Total27,347

CO2 Equivalent

Million t

National Action Plan on Climate Change

7/27/2019 S1a2 NEDO Naruse

24/45

National Action Plan on Climate Change

Solar energy 20,000MW from solar power and thermal, by2020

Enhanced energy

efficiency

10,000MW energy savings by 2012

Sustainable habitat Improved energy efficiency of housings, officebuildings, public transportation, waste

management

Water resources Water conservation, optimal river managementHimalayan ecosystem Ecosystem preservation and monitoring of

glaciers

Forestation Forestation of 60 lac ha, Green India

Sustainable agriculture Measures for drought, risk management

agricultural studies

Strategy for climate

change

Ensuring funding, research, observation, data

management

Announced on 30 June, 2008

National Solar Mission

7/27/2019 S1a2 NEDO Naruse

25/45

National Solar Mission

Jawaharlal Nehru National Solar Mission

Cabinet approval on 19 Nov., 2009 Setting target 22,000MW by 2022

Budget plan: 4337 crore Rs. estimation

Applied area Target for 1st st.

-FY2012

Target for 2nd st.

(FY2013-16)

Target for 3rd st.

(FY2017-22)

Solar energy collector 70 lac m2 150 lac m2 200 lac m2

Solar power generation,

off-grid

200 MW 1,000 MW 2,000 MW

Solar power generation,on-grid (inc. rooftop)

1,000-2000 MW 4,000-10,000 MW 20,000MW

E S i A ti iti

7/27/2019 S1a2 NEDO Naruse

26/45

Major implementations and resultsduring 11th plan (FY2007-2011):

Bachat Lamp Yojana Replacement of incandescent bulbs with CFL in households

Result: 54 lac distributed in HP from 11/08-03/09, 164 MW

Standards & Labeling (S&L) Minimum energy performance standards with 5 stars (AC, refrig., etc.)

Result: 599.44 MW

Energy Conservation Building Code (ECBC) Minimum energy performance standards for new commercial buildings

Result: 11 buildings, estimated savings: 6.1MW

Energy Saving Activities

Source: Verified Energy Savings related with the activities of BEE for the year 2008-09 (July 2009)

Designated Industries

7/27/2019 S1a2 NEDO Naruse

27/45

Designated Industriesunder Energy Conservation Law

Sector Scale

Thermal PP Over 30,000 MTOE annuallyFertilizer Over 30,000 MTOE annually

Cement Over 30,000 MTOE annually

Iron & Steel Over 30,000 MTOE annually

Chlor-alkali Over 12,000 MTOE annually

Aluminum Over 7,500 MTOE annually

Railway Over 30,000 MTOE annually or regulated

figure by Ministry of Railway

Textile Over 30,000 MTOE annually

Paper, pulp Over 30,000 MTOE annually

Revised energy conservation law, March 2007

Energy Conservation Building Code

7/27/2019 S1a2 NEDO Naruse

28/45

EPI: Energy Performance Index (kWh/m2/year)

From 1 (lowest) to 5 (highest) ratingFor office buildings with capacity over 500kW

- 3 climate zones: Warm and humid, composite, hot and

dry- Rate of air conditioning: under 50%, more than 50%

Future plan:- 5 climate zones

- variation of sorts of buildings:

office buildings, hotel facilities, hospitals,shopping malls and IT parks

Energy Conservation Building Code(as of Feb. 09)

7/27/2019 S1a2 NEDO Naruse

29/45

NEDO Activities in India

29

ModelProjectsIncreasingtheEfficientUseofEnergyusinga

CokeDryQuenchingSystem

UtilizationofSensibleHeatfromBlastFurnace

hotstove

Waste

HighlyEfficientCoalPreparationTechnology

WasteHeatRecoverySystemofCementPlant

ConvertingaDieselGeneratortoDualFuel

Operation

SinterCoolerWasteHeatRecovery

CooperativeResearchProgramLongTermReliabilityofPhotoVoltaicModules

Studyof

Micro

Grid/Smart

Grid

in

Neemrana

EnergyEfficiencyAnalysisCementIndustry

IronandSteelIndustry

RepresentativeOffice7th Floor,HotelLeMeridien CommercialTower

Raisina Road,NewDelhi110001India

Tel:+911143510101

Fax:+911143510102

55

44

11

11

66

33

44

22

33

2211

Bilaspur

NewDelhiAjmer

Pune

Vishnupuram

Reddipalayam

Vishakapatnam

Angul

RaurkelaJamshedpur

1

2

3

4

6

1

1 2 6

3 4 5

5

55

66

NEDO

As of December 2009

2

O

7/27/2019 S1a2 NEDO Naruse

30/45

Model Projects Objectivesfor Energy Efficiency and Coal Utilization

Objectives:

- To introduce and demonstrate effective energy efficiencyand clean coal technologies already in practical use in

Japan to host countries

- To support the self-help efforts of host countries by sharing

tasks and costs for projects

- Implementation and technology deployment

(Not ODA projects)

30

7/27/2019 S1a2 NEDO Naruse

31/45

Model Project Implementation Scheme

Parties involved for conclusion of MOU, Agreement and ID

31

Japan

NEDONEDO

Entrusted Company

Memorandum ofUnderstanding

(MOU)

ImplementationDocument (ID)

Ministry in Charge

Implementation

Site Firm

India

Entrustment Instructions for cooperation

(agreement)

7/27/2019 S1a2 NEDO Naruse

32/45

Project name Implementation site Period (FY)

The Model Project for Utilization of Sensible Heatfrom Blast Furnace Hot Stove Waste Gas

Tata Iron and Steel Co.,

Ltd.

(Jharkhand)

2001-2003

The Model Project for Waste Heat Recovery

System of Cement Plant

The India Cements

Limited

(Andhra Pradesh)

2001-2004

The Model Project for Coke Dry QuenchingTata Steel, Ltd.

( Jharkhand )2006-2010

The Model Project for Converting a Diesel

Generator to Dual-Fuel Operation

Tata Motors, Ltd.

(Pune)2008-2010

The Model Project for Sinter Cooler Waste Heat

Recovery RINL Vizag Steel Plant 2009-2011

32

Energy Efficiency Model Projects in India

7/27/2019 S1a2 NEDO Naruse

33/45

Project name Implementation site Period (FY)

The Model Project for Highly Efficient Coal

Preparation Technology

Monnet Ispat & Energy,

Ltd.

(Orissa)

2008-2010

33

Coal Utilization Project in India

Project name Implementation site Period (FY)

Long-term Reliability of Photovoltaic Modules

Solar Energy Center,

MNRE,National Physical

Laboratory

2008-2009

The Study of Stable Power Supply System of

Micro Grid/Smart Grid for the Industrial Parks inIndia

IIT HyderabadNeemrana 2009-2010

Cooperative Research Program in India

Energy efficiency: The Model Project for Utilization of Sensible

7/27/2019 S1a2 NEDO Naruse

34/45

Host Country India

Implementation siteTata Iron and Steel Co., Ltd.

(Jharkhand)

Counterpart

Department of Economic

Affairs/Ministry of Finance,Ministry of Steel

Energy savings effectApprox. 8,110t/yr

(Crude Oil Equivalent)

CO2 reduction volume Approx. 25,090t/yr

34

Waste heat recovered from stove

stacks exhaust gas is used to

preheat the blast furnace gascombusted in the stoves, thereby

reducing the amount of energy

normally required for the hot stove

and blast furnace.

Entrusted Company:

Nippon Steel Engineering

Co., Ltd.

e gy e c e cy e ode ojec o U a o o Se s b e

Heat from Blast Furnace Hot Stove Waste Gas

Project Overview

Project Term

FY2001 FY2003Stack

Circulating pump

Hot Stove

Heat exchanger

Expansion tank

Heat transfer oil

Heat exchanger

Hot air

BlowerCold air

Blast furnace

New equipmentSystem for Utilization of Sensible Heat fromBlast Furnace Hot Stove Waste Gas

Burnerfan

Combustiongas

Air for combustion

Heat transfer oilreservoir tank Supply pump

Energy efficiency: The Model Project for Waste Heat Recovery

S t f C t Pl t

7/27/2019 S1a2 NEDO Naruse

35/45

Host Country India

Implementation siteThe India Cements Limited

(Andhra Pradesh)

Counterpart

Department of EconomicAffairs/Ministry of Finance,

Ministry of Commerce andIndustry

Energy savings effect14,840 t/yr (Crude Oil

Equivalent)

CO2 reduction effect Approx. 45,110 t/yr

35

Waste heat collected in the form of

steam is used to generate electricity

for the plant and thereby improveenergy efficiency.

Entrusted Company:

Kawasaki Heavy Industries Ltd.(Currently Kawasaki Plant Systems,

Ltd.)

System of Cement Plant

FY2001 FY2004

Cement Plant Waste Heat Recovery PowerGeneration Facilities

New equipment

Steam/water flow

Gas flow

Raw materialprocess

Preheating

process

Calciningfurnace

Drum

Clinker cooler

Kiln

Firing processProduct manufacturing

process

Dustcollector Exhaust fan

Stack

PH boiler

HP flasher

Turbine

AQC boiler

CondenserLP

flasher

Generator

Preheater

Project Overview

Project Term

Energy efficiency: The Model Project for Coke Dry Quenchnig

7/27/2019 S1a2 NEDO Naruse

36/45

Host Country India

Implementation siteTata Steel, Ltd.

(Jharkhand)

CounterpartDepartment of Economic

Affairs/Ministry of Finance,

Ministry of Steel

Energy savings effect50,000 t/yr (Crude Oil

Equivalent)

CO2 reduction volume Approx. 137,000 t/yr

36

Hot coke from a coke oven is quenched

in a coke dry quenching system using

nitrogen gas instead of the conventional wetcooling process using water, and waste

heat is recovered and used in the steel

manufacturing process. This reduces

energy consumption, CO2

emissions and

the spread of atmospheric pollutants, such

as coal dust.

Entrusted company: Nippon Steel Corp.

(Now known as Nippon Steel EngineeringCo., Ltd.)

Energy efficiency: The Model Project for Coke Dry Quenchnig

FY2006 FY2009

JamshedpurMumbai

( ))

Chennai( )

( )

Kolkata

CDQ

22

11

JamshedpurMumbai

( ))

Chennai( )

( )

Kolkata

Coke Dry Quenching System (CDQ)

Boiler

BucketRotary seal valve

Sub-economizer

Charging

facility

Gas circulation fan

2Secondary dust catcher

1Primary dust catcher

Cooling

Chamber

Pre-

chamber

Crane

Steam forsteel mill

Conveyer belt

Project Overview

Project Term

Energy efficiency: The Model Project for Converting a

Diesel Generator to Dual-Fuel Operation

7/27/2019 S1a2 NEDO Naruse

37/45

Host Country India

Implementation siteTata Motors, Ltd.

(Pune)

Counterpart

Department of Economic

Affairs/Ministry of Finance,Ministry of Power

Energy savings effect2,246t/yr (Crude Oil

Equivalent)

CO2 reduction volume Approx. 1,361 t/yr

37

Diesel Generator to Dual-Fuel Operation

FY2008 FY2009

A diesel engine used for power

generation is being converted to dual-

fuel use to allow the engine to beoperated with natural gas and a small

amount of diesel oil as pilot fuel.

The technology will allow companies

owning diesel captive power plants in

India to reduce power generation costs

by substituting energy sources. In

addition, environmental benefits will be

obtained by switching from diesel to

cleaner burning natural gas.

Entrusted company: JFE Technos Co.,

Ltd.

DF Tank

PumpDF Injection Pump

Cam

A

Piston

DF

Injector

Govern

New parts to be installed for conversion

Turbocharge

Intake

ValveExhaust

Valve

Fuel Injection Nozzle

Gas Pressure Regulator

Shut-off

Valve

A

Main Controller

(Diesel fuel, Natural

gas)

S

Charged Air

Turbocharger

Air

Air Filter

Cooling

Water

Air Cooler

Exhaust Gas

Valve

Controller

Rev. Pick up

Natural

Gas

Gas Injection Valve

Project Overview

Project Term

MOU Signing Ceremony for The Model Project for Converting a Diesel

7/27/2019 S1a2 NEDO Naruse

38/45

Date: 25th July, 2008

Venue: Hotel New Otani, Tokyo

Signers:K. KOIZAWA, Executive Director,NEDO

Kumar Sanjay KRISHNA, Joint

Secretary, DEA/MOFDevender SINGH, Joint Secretary,MOP

A S PURI

Witness:

Dr. D. SUBBARAO / FinanceSecretary

S. MURATA, Chairman, NEDO

38

MOU Signing Ceremony for The Model Project for Converting a Diesel

Generator to Dual-Fuel Operation

The Model Project for Sinter Cooler Waste Heat Recovery

7/27/2019 S1a2 NEDO Naruse

39/45

Sinter cooler waste gas previouslyemitted into the atmosphere in India

will be captured and routed to a wasteheat recovery boiler. The heat canthen be used to drive a steam turbinegenerator and produce electric power.

39

Host country India

Entrusted company JP Steel Plantech Co.

Implementation site RINL Vizag Steel Plant

Counterparts MOS/MOF

Energy savings effect 38,500 toe/yr

CO2 emission

reduction

117,000 t/yr

The Model Project for Sinter Cooler Waste Heat Recovery

G

Dust

catcherBoiler

Circulati

on

fan

Turbine &

generator

Sinter machine

Sinter cooler

Waste heat recovery

system

Stack Sinter blower Windboxes

Circulation

hood

1.

2.3.

4.

Process Flow

FY2009 FY2011

Project Overview

Project Term

The Model Project for Highly Efficient Coal Preparation

7/27/2019 S1a2 NEDO Naruse

40/45

40

Indian coal tends to be low in sulfur

and phosphor content, but contains

a large amount of ash. The objective

of this project is to contribute to the

resolution of energy and

environmental problems caused by

coal utilization in India through thewidespread dissemination of highlyefficient coal preparation technology.

Host country India

Project siteUtkal B-2 Coal Mine (Orissa, India)

Monnet Ispat & Energy, Ltd.

Counterpart Ministry of FinanceMinistry of Coal

Entrusted

company

Japan Coal Energy Center

Nagata Engineering Co., Ltd.

Technology

Variwave Jig system

Auto Reject Control SystemVariable Wave Pattern

Variwave Jig system

Auto Reject Control SystemVariable Wave PatternFY2008 FY2010

Project Overview

Project Term

Cooperative Research for Long-term Reliability

7/27/2019 S1a2 NEDO Naruse

41/45

Four activities will be conducted in this project:

1. Long-term outdoor PV module exposure test

2. Performance and degradation analysis

3. Acquisition of precise meteorological data

4. Fabrication of degradation resistant PV modules suitable for severely hot

and humid conditions of India.

p g y

of Photovoltaic Modules in India and Japan

41

Equipment

ProjectOverview

ProjectTerm

FY2008 FY2009

Cooperative Research for the Study of Stable Power Supply

7/27/2019 S1a2 NEDO Naruse

42/45

The following activities will be conducted in

this project:

1. Examination of best power supply system

for Indian industrial estates

2. Evaluation to determine best supply and

demand control systems that use micro grid

concept (examination and construction of

algorithm)

3. Examination and design of measurement

and protection multi-device to stabilize

electric power on micro grid (examination,

construction of algorithm, and production of

prototype for trial purposes)

System of Micro Grid/Smart Grid for the Industrial Parks in

India

42

ProjectOverview

ProjectTerm

FY2009 FY2010

Micro Grid/Smart Grid Energy Center

Optimum control of operating units

Centralized control

Co. A Co. B Co. C

Connection of existing DEGs

Regional Energy Efficiency Centers

7/27/2019 S1a2 NEDO Naruse

43/45

Establishment of Regional Energy Efficiency Centre at Dr. Ambedkar

Institute of Productivity, National productivity Council, Chennai has been

proposed in collaboration with NPC and Bureau of Energy Efficiency

The following systems are proposed to be set up by NEDO along with the

training facilities

1. Pumping System2. Fan System

3. Compressed Air System

4. Reheating Furnace

5. Open Burner6. Boiler and Steam System

Regional Energy Efficiency Centers

43

Dr. Ambedkar Institute of Productivity, Chennai

F t re Cooperation Delhi M mbai Ind strial Corridor

7/27/2019 S1a2 NEDO Naruse

44/45

Future Cooperation - Delhi Mumbai Industrial CorridorThe Delhi Mumbai Industrial Corridor (DMIC) project is a collaborative effort between Japan and India to develop a major industrial

zone. A freight train line and a thoroughfare between Delhi and Mumbai will be built and infrastructure, including industrial parks,logistics facilities and power plants along the corridor, will be improved as part of this project.

Industrial/social infrastructure

Construction/refurbishment of industrial clusters/parks

Logistics facilities

Construction/expansion of seaports/airports

Housing, commercial/recreation facilities, etc.

With a view to implementing a smart communities model

project using renewable energy technologies like

photovoltaics, feasibility studies at industrial parkslocated along the DMIC are being considered.

Freight train lineNational Route 8

Source: Investment Commission of India

Calcutta

ChennaiBangalore

Delhi

MumbaiV power generationSolar power

Wind power

7/27/2019 S1a2 NEDO Naruse

45/45

Please visit our website

45

Thank you for your kind attention!

Search