CONSTRUCTION EQUIPMENT WORLD ECONOMIC FORUM 12-13 September of 2011 - - PowerPoint PPT Presentation

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CONSTRUCTION EQUIPMENT WORLD ECONOMIC FORUM

12-13 September of 2011

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Project Part-funded by the European Commission by its Energy DG

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SOLINTEL

Develop of a new and highly effective modeling and monitoring Energy Management System technique in order to improve Energy Efficiency and move to a low CO2 emission in the energy intensive non-metallic mineral industry.

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SUMMARY

Develop of a new and highly effective modeling and monitoring Energy Management System technique in order to improve Energy Efficiency and move to a low CO2 emission in the energy intensive non-metallic mineral industry.

1.Where does the project come from? 2.Conceptualization 3.Impact and benefits

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SECTOR OVERVIEW

Develop of a new and highly effective modeling and monitoring Energy Management System technique in order to improve Energy Efficiency and move to a low CO2 emission in the energy intensive non-metallic mineral industry.

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Develop of a new and highly effective modeling and monitoring Energy Management System technique in order to improve Energy Efficiency and move to a low CO2 emission in the energy intensive non-metallic mineral industry.

CONTEXT Granular materials like;  Sand  Crushed rock  Gravel

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Develop of a new and highly effective modeling and monitoring Energy Management System technique in order to improve Energy Efficiency and move to a low CO2 emission in the energy intensive non-metallic mineral industry.

DRIVING FORCES FOR AGGREGATES CONSUMPTION

 Private homes – up to 400 tonnes.  Public buildings – schools, hospitals – up to 3,000 tonnes for a sports stadium.  Road network – 1 km up to 30,000 tonnes.  Rail network – 1 meter up to 9 tonnes.

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Develop of a new and highly effective modeling and monitoring Energy Management System technique in order to improve Energy Efficiency and move to a low CO2 emission in the energy intensive non-metallic mineral industry.

ECONOMIC RELEVANCE

Total production of aggregates in 21 European countries in 2006 3.6 millions of tonne per year

Source: UEPG 2011

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Develop of a new and highly effective modeling and monitoring Energy Management System technique in order to improve Energy Efficiency and move to a low CO2 emission in the energy intensive non-metallic mineral industry.

AGGREGATES CONSUMPTION “The European 2009 average production was 5.5 tonnes /capita, down from 6.2 tonnes/ capita in 2008, further down from 7 tonnes/capita in 2006, again dramatically confirming the extent of the economic crisis over the last 5 years.”

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Develop of a new and highly effective modeling and monitoring Energy Management System technique in order to improve Energy Efficiency and move to a low CO2 emission in the energy intensive non-metallic mineral industry.

CONSUMPTION TREND

Tonnage 2010 vs 2009

Source: UEPG 2011

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Develop of a new and highly effective modeling and monitoring Energy Management System technique in order to improve Energy Efficiency and move to a low CO2 emission in the energy intensive non-metallic mineral industry.

AGGREGATES PRODUCTION

Aggregates production in 2009 in Europe by decreasing tonnes/capita

Source: UEPG 2011

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Develop of a new and highly effective modeling and monitoring Energy Management System technique in order to improve Energy Efficiency and move to a low CO2 emission in the energy intensive non-metallic mineral industry.

GROSS DOMESTIC PRODUCT

Aggregates production in 2009 in Europe – tonnes/capita (vertical scale) GDP (horizontal scale)

Source: UEPG 2011

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PRODUCTION PER COUNTRY 2009

Source: UEPG 2011

Total number of producers companies Total Number (Quarries and Pits) Sand & Gravel (millions tonnes) Crushed Rock (millions tonnes) Marine Aggregates (millions tonnes) Recycled Aggregates (millions tonnes) Manufactured Aggregates (millions tonnes) Total Production (millions tonnes)

Austria

1062 1362 61 31 4 2 97

Belgium

78 104 16 41 3 15 1 78

Bulgaria

190 280 11 14 25

Croatia

260 338 7 22 29

Cyprus

23 23 12 12

Czech Rep

198 384 24 41 65

Denmark

350 500 30 0.2 9 5 44

Finland

400 2091 16 47 1 1 65

France

1428 2481 140 209 6 15 6 376

Germany

1280 2265 236 217 5* 61 36 555

Greece

192 213 1 70 71

Hungary

100 100 37 20 57

Ireland

150 600 19 20 39

Italy

1550 2460 210 140 350

Netherlands

65 160 47 45 22 113

Norway

710 927 13 51 2 66

Poland

2044 1786 131 49 22 1 203

Portugal

617 1081 25 25 50

Romania

430 745 25 12 1 38

Serbia

20 70 12 8 19

Slovakia

180 305 11 18 30

Spain

1555 1765 66 171 1 238

Sweden

985 2109 20 58 1 6 85

Switzerland

540 535 33 5 4 5 47

Turkey

770 770 25 290 315

UK

727 1275 45 86 10 46 10 197

Totals 15904 24729 1259 1658 82 200 63 3262

Develop of a new and highly effective modeling and monitoring Energy Management System technique in order to improve Energy Efficiency and move to a low CO2 emission in the energy intensive non-metallic mineral industry.

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Develop of a new and highly effective modeling and monitoring Energy Management System technique in order to improve Energy Efficiency and move to a low CO2 emission in the energy intensive non-metallic mineral industry.

CURRENT SITUATION “According to Euroconstruct, 2009 was the worst year for construction in this decade, as total construction output fell by 8% “.

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Develop of a new and highly effective modeling and monitoring Energy Management System technique in order to improve Energy Efficiency and move to a low CO2 emission in the energy intensive non-metallic mineral industry.

CURRENT SITUATION

• The difficulties of high public deficits in Ireland, Spain and Portugal

forced further significant austerity measures, cuts in housing construction and public investments.

• Lack in domestic demand, the curtailment of public investments,

avoidance of long-term commitments and the reassessment of ongoing public projects also led to lower performance in many other countries.

• According to the new country-by-country analysis done by the

Euroconstruct members, 2011 will be a year of change.

• After three years of recession, construction market players have one

more year to restructure themselves before positioning to a very moderate recovery.

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Develop of a new and highly effective modeling and monitoring Energy Management System technique in order to improve Energy Efficiency and move to a low CO2 emission in the energy intensive non-metallic mineral industry.

PERSPECTIVES FOR THE FUTURE

• By 2013, Euroconstruct countries anticipate a lower than 2007 total

construction output, €1,341 billion (€1,506 billion in 2007).

• Among the three subsectors, civil engineering proved to be the most stable

during the crisis years and after.

• The previously most severely hit residential construction will hardly recover

from its poor position - nevertheless a growth by 1.9% in 2011 is expected.

• In 2013, output of the residential sector is not predicted to reach the

performance of 2008. According to the forecasts, 60% of the residential output will come from renovation activity in 2013.

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Develop of a new and highly effective modeling and monitoring Energy Management System technique in order to improve Energy Efficiency and move to a low CO2 emission in the energy intensive non-metallic mineral industry.

FUTURE OF THE SECTOR

• Construction is a vital sector in the European economy. The ten-year-period

between 2004 and 2013 is showing important structural changes within the sector.

• Actual demands in the near-future (due to efficient energy consumption,

upgrading the built environment, housing replacement, new health utilities for the ageing population, lower-CO2 emission buildings) are expected to force construction to turn into a higher value and higher quality performing sector.

• This will require new products, new technologies and new skills.

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Develop of a new and highly effective modeling and monitoring Energy Management System technique in order to improve Energy Efficiency and move to a low CO2 emission in the energy intensive non-metallic mineral industry.

ENERGETIC FIGURES

U.S. Mining Industry Energy Bandwidth for Coal, Metal, and Mineral Mining

Source: Mining Industry Energy Bandwidth Study, June 2007 by the U.S. Department of Energy.

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Develop of a new and highly effective modeling and monitoring Energy Management System technique in order to improve Energy Efficiency and move to a low CO2 emission in the energy intensive non-metallic mineral industry.

ENERGETIC FIGURES

Source: Mining Industry Energy Bandwidth Study, June 2007 by the U.S. Department of Energy.

Energy Consumption by Equipment category in U.S Mineral Mining Industry (TBtu/yr)

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Develop of a new and highly effective modeling and monitoring Energy Management System technique in order to improve Energy Efficiency and move to a low CO2 emission in the energy intensive non-metallic mineral industry.

ENERGY & CARBON TABLE

Mineral Product Carbon * kg CO2/t Energy ** kWh/t Ready Mixed Concrete 0.95 1.76 Sand & Gravel 4.28 8.3 Crushed Rock 4.32 9.7 Asphalt 34.4 98.11

Embodied Carbon and Energy for typical aggregate products

*Carbon data is from the Mineral Products Association 2009 Sustainable Development Report; kg/CO2/t is kilograms of carbon dioxide per tonne. ** Energy data is from the Tarmac 2009 Sustainable Development Report; kWh/t is kilowatt hours per tonne. All data is for 2008. Source: Mitchell, C.J. 2012. Aggregate Carbon Demand: The hunt for low-carbon aggregate. Proceedings of the 16th Extractive Industry Geology Conference, EIG Conferences Ltd.

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Develop of a new and highly effective modeling and monitoring Energy Management System technique in order to improve Energy Efficiency and move to a low CO2 emission in the energy intensive non-metallic mineral industry.

CO2 EMISSIONS FIGURES

EU-27 Population and greenhouse emissions CO2 emissions* of world’s largest emitters

Source: Eurostat (online data code: tps00001) and EEA, also available at Eurostat (online data code: tsdcc210) Source: Data for the EU: EEA, also available at Eurostat (online data code: tsdcc210); data for other countries: IEA, CO2 Highlights, 2010. (*emissions from energy use only)

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Develop of a new and highly effective modeling and monitoring Energy Management System technique in order to improve Energy Efficiency and move to a low CO2 emission in the energy intensive non-metallic mineral industry.

CO2 EMISSIONS FIGURES

Source: Dr. Mile Watkins. The significance of Carbon, March 2009 . Aggregates industries sustainable construction department.

Kg CO2 per ton of production Comprising process energy, product transport and distribution

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Develop of a new and highly effective modeling and monitoring Energy Management System technique in order to improve Energy Efficiency and move to a low CO2 emission in the energy intensive non-metallic mineral industry.

KEY POINTS

• According to the new country-by-country analysis done by the Euroconstruct

members, 2011 will be a year of change.

• By 2013, Euroconstruct countries anticipate a lower than 2007 total

construction output, €1,341 billion (€1,506 billion in 2007).

• Actual demands in the near-future are expected to force construction to turn

into a higher value and higher quality performing sector. This will require new products, technologies and skills.

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Develop of a new and highly effective modeling and monitoring Energy Management System technique in order to improve Energy Efficiency and move to a low CO2 emission in the energy intensive non-metallic mineral industry.

EE-QUARRY

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Develop of a new and highly effective modeling and monitoring Energy Management System technique in order to improve Energy Efficiency and move to a low CO2 emission in the energy intensive non-metallic mineral industry.

OBJECTIVE The overall objective of the project is to develop a new and highly effective modeling and monitoring Energy Management System technique in order to improve Energy Efficiency and move to a low CO2 emission in the energy intensive non-metallic mineral industry: EE- QUARRY.

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Develop of a new and highly effective modeling and monitoring Energy Management System technique in order to improve Energy Efficiency and move to a low CO2 emission in the energy intensive non-metallic mineral industry.

OBJECTIVES

ENERGY EFFICIENCY

OPPORTUNITIES REDUCING CO2 IMPACTS

QUARRIES EE-QUARRY

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Develop of a new and highly effective modeling and monitoring Energy Management System technique in order to improve Energy Efficiency and move to a low CO2 emission in the energy intensive non-metallic mineral industry.

REQUIREMENTS

• The EE-QUARRY Project emerges from the necessity to

control a very demanding industry sector which characterizes from its high energy demand and enormous GHG emissions.

• The goal is to apply a whole new analysis technique in
• rder to improve EE and to reduce GHGE on quarries,

through the constant monitoring and optimization on every production process.

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Develop of a new and highly effective modeling and monitoring Energy Management System technique in order to improve Energy Efficiency and move to a low CO2 emission in the energy intensive non-metallic mineral industry.

The European Aggregates Industry has the responsibility to provide essential materials in a responsible way to meet Europe’s needs. This sector has the peculiarity that comprises many SMEs. Some figures:

• 13,500 companies across Europe.
• 21 national associations.
• 3 billion tones of materials produced yearly.
• 28,000 operating sites.
• 350,000 employees.

SECTOR OVERVIEW

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Develop of a new and highly effective modeling and monitoring Energy Management System technique in order to improve Energy Efficiency and move to a low CO2 emission in the energy intensive non-metallic mineral industry.

• The project illustrates the way in which a dynamic European industrial sector can

successfully combine competitiveness and sustainability, that do not contradict but complement each other.

12% 16% 3% 3% 16% 22% 28%

USA Europe Japan Canada Russia China Others

Percentages of aggregates consumption in the world.

WORLD PRODUCTION

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Develop of a new and highly effective modeling and monitoring Energy Management System technique in order to improve Energy Efficiency and move to a low CO2 emission in the energy intensive non-metallic mineral industry.

• Achieve a sustainable supply and access to resources is another goal of the sector.
• Therefore, it is important that the results of this project help in the sustainable control of

the industry, so this access will not be denied unnecessarily.

SECTOR CONSTRAINTS

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Develop of a new and highly effective modeling and monitoring Energy Management System technique in order to improve Energy Efficiency and move to a low CO2 emission in the energy intensive non-metallic mineral industry.

CONCEPT

• The concept is very simple but highly efficient, will be based on a research

methodology which only purpose it will be to obtain as much as information and data as possible, covering production processes till the service ones.

• Another goal of the Project EE-Quarry is to contribute significantly and efficiently to
• ptimize required resources involved into the extraction and production of

aggregates, through a series of verification procedures, control and monitoring of all phases of production found in such industries.

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• The optimization of the system not only

encourages energy efficiency, but benefits production as well.

• Economic incentives for energy efficiency

measures have the magnitude and quick payback that could facilitate industry-wide replication.

Develop of a new and highly effective modeling and monitoring Energy Management System technique in order to improve Energy Efficiency and move to a low CO2 emission in the energy intensive non-metallic mineral industry.

OPTIMIZATION

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Develop of a new and highly effective modeling and monitoring Energy Management System technique in order to improve Energy Efficiency and move to a low CO2 emission in the energy intensive non-metallic mineral industry.

WORKING PLAN

In order to achieve objectives, a working plan with this activities was defined:

• 1. Detect critical and intensive energy demanding processes.
• 2. Modeling and monitoring innovative energetic optimization solutions.
• 3. Implementation of the benefits of the solutions developed.
• 4. Reduce the CO2 impact after the production processes.
• 5. Identificate scientific and technical knowledge.
• 6. Awareness, dissemination and training of the project results.

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Develop of a new and highly effective modeling and monitoring Energy Management System technique in order to improve Energy Efficiency and move to a low CO2 emission in the energy intensive non-metallic mineral industry.

ENERGY EFFICIENCY

INTEGRATION MODEL ENERGY COMPENSATION AND CO2 NEUTRALIZATION

High Energy Consumption High Level of Emissions Energy Efficiency Compensation Sources of CO2

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Develop of a new and highly effective modeling and monitoring Energy Management System technique in order to improve Energy Efficiency and move to a low CO2 emission in the energy intensive non-metallic mineral industry.

• Competitiveness policy (Lisbon Strategy): Transforming the EU industry from a resource

intensive to a knowledge intensive one, is a key objective of the Lisbon Agenda, while increasing the productivity and competitiveness of EU enterprises.

• Environmental Policies: The EE-QUARRY will support the fulfillment of the targets established

by Kyoto protocol concerning the reduction of greenhouse gas. The Bali Declaration urging GHG limits December 7, 2007 and the SET Plan for reducing 20% of the GHG emissions ( at 1990 level) in 2020 and reducing CO2 emissions by 60 to 80% in 2050.

• Energy Policies: EE-QUARRY will also contribute to achieve the mandates of the Action Plan on

Energy Efficiency in Europe.

• Research Policy : EE-QUARRY will have a significant impact on the RTD in the Mining sector

contributing to reinforce the aggregate extraction research expenditure level in Europe, which is far behind other sectors, towards the·3% GPD target figure by 2010 in Europe as stated at the Barcelona Summit.

EU POLICIES

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Develop of a new and highly effective modeling and monitoring Energy Management System technique in order to improve Energy Efficiency and move to a low CO2 emission in the energy intensive non-metallic mineral industry.

PARTNERS

Nº Organization name Short name Type Country 1 SOLINTEL M&P S.L (Coordinator) SOLINTEL SME Spain 2 ACCIONA Infraestructuras ACCIONA Large Spain 3 Aridos Carmona S.A CAMT SME Spain 4 CTM Marble Technological Centre CTM RTD Spain 5 D'Appolonia DAPP Large Italy 6 Exergia EXERGIA SME Greece 7 MIRO MIRO RTD UK 8 EPC-FRANCE EPC Large France 9 S&B Industrial Minerals S&B Large Greece 10 University of Leicester ULECI University UK 11 Mostostal Warszawa MW Large Poland

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Develop of a new and highly effective modeling and monitoring Energy Management System technique in order to improve Energy Efficiency and move to a low CO2 emission in the energy intensive non-metallic mineral industry.

PARTNERS

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Develop of a new and highly effective modeling and monitoring Energy Management System technique in order to improve Energy Efficiency and move to a low CO2 emission in the energy intensive non-metallic mineral industry.

GOVERNANCE STRUCTURE

GENERAL ASSEMBLY STEERING COMMITTEE PROJECT COORDINATOR

Scientific & Technical Committee Admin/Financial/Legal Coord. Work Packages Leaders Task Leaders

European Commission Executive Management Team

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Develop of a new and highly effective modeling and monitoring Energy Management System technique in order to improve Energy Efficiency and move to a low CO2 emission in the energy intensive non-metallic mineral industry.

COMMITTEES

GENERAL ASSEMBLY

Chairman Members

STEERING COMMITTEE

Chairman Members (WP Leaders)

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Develop of a new and highly effective modeling and monitoring Energy Management System technique in order to improve Energy Efficiency and move to a low CO2 emission in the energy intensive non-metallic mineral industry.

COMMUNICATION FLOW

The Project Coordinator, will be responsible for the continuous follow-up of the project. The Project Coordinator is the unique contact partner of the project from EE-QUARRY for interfacing with the EC.

PROJECT COORDINATOR EUROPEAN COMISSION STEERING COMMITTEE GENERAL ASSEMBLY ADMIN/FINANCIAL/LEGAL COORDINATION SCIENTIFIC & TECHNICAL COMMITTEE TASK LEADERS WP LEADERS

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Develop of a new and highly effective modeling and monitoring Energy Management System technique in order to improve Energy Efficiency and move to a low CO2 emission in the energy intensive non-metallic mineral industry.

GRANT & CONSORTIUM AGRREMENT

29% 18% 11% 42% SMEs Research Education Enterprise 66% 24% 5% 5% Demo RTD Management Other Budget distribution per type of company Budget distribution per type of activity

Distribution:

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Develop of a new and highly effective modeling and monitoring Energy Management System technique in order to improve Energy Efficiency and move to a low CO2 emission in the energy intensive non-metallic mineral industry.

PARTNERS BACKGROUND

Partner Name Active participation

• f key industrial

partners Owner/Exploitation

• f non- metallic

mineral quarries Coordination of previous FP projects Participation in the Framework Programme Involvement

• f SME

Experienced research

• rganizations

SOLINTEL X X X ACCIONA X X X X X CAMT X X X CTM X X DAPPOLONIA X X X EXERGIA X X X X MIRO X X X X EPC-FRANCE X X X S&B X X X ULEIC X X MOSTOSTAL X X X

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Develop of a new and highly effective modeling and monitoring Energy Management System technique in order to improve Energy Efficiency and move to a low CO2 emission in the energy intensive non-metallic mineral industry.

EE-QUARRY PROJECT- WP’S DESCRIPTION

• WP1. Project Management

WP.2 Low energy efficiency processes in the energy intensive industry of aggregates extraction WP.3 Modeling and monitoring innovative energetic optimization solutions

• WP4. Increasing EE
• pportunities and

reducing Co2 impacts WP5. EE-QUARRY demonstration

• f its

implementation benefits WP6. Business models & Exploitation of project results WP7. Awareness dissemination and training

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Develop of a new and highly effective modeling and monitoring Energy Management System technique in order to improve Energy Efficiency and move to a low CO2 emission in the energy intensive non-metallic mineral industry.

WORK PACKAGES

Work Package Nº Work Package Title Lead Beneficiary Type of activity Start month End month 1 Project Management SOLINTEL MGT 09/2010 08/2014 2 Low energy efficiency processes in the energy intensive industry of aggregates extraction ACCIONA RTD 09/2010 08/2011 3 Modeling and Monitoring innovative energetic optimization solutions CAMT RTD 03/2011 11/2012 4 Increasing EE opportunities and reducing CO2 impact after production processes CTM RTD 09/2010 08/2012 5 EE-QUARRY Implementation Benefits DAPP DEM 06/2012 02/2014 6 Business model and Exploitation of the project results EXERGIA RTD 09/2011 08/2014 7 Awareness, Dissemination and Training MIRO OTHER 09/2010 08/2014 TOTAL PROJECT DURATION: 4 YEARS

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Develop of a new and highly effective modeling and monitoring Energy Management System technique in order to improve Energy Efficiency and move to a low CO2 emission in the energy intensive non-metallic mineral industry.

WP 1. PROJECT MANAGEMENT

Define the overall coordination, governance structure, the communication flow and methods necessaries to meet the project objectives.

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Develop of a new and highly effective modeling and monitoring Energy Management System technique in order to improve Energy Efficiency and move to a low CO2 emission in the energy intensive non-metallic mineral industry.

• WP2. LOW ENERGY EFFICIENCY PROCESS
• Intensive energetic

extracting processes

• Energy intensive

consumption equipment

Detect & Identify

• Embedded energy per

machine or stage

• Embedded energy per

process

• Emissions

Quantify

• Define performance

indicators

• Control and

monitoring

• Efficiency

Improve

• Detect the critical and intensive energy demanding processes using energy management

system techniques to provide optimizing solution opportunities, which can be turned into successful and low energy consuming stages in the next WP.

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Develop of a new and highly effective modeling and monitoring Energy Management System technique in order to improve Energy Efficiency and move to a low CO2 emission in the energy intensive non-metallic mineral industry.

Reduce the environmental impact of aggregate extraction through the development, promotion and implementation of strategies and technologies that maximize the production and quality of saleable product and which minimize energy consumption . What do we need in order to optimize a process?

• Deposit characteristics.
• Blast design.
• Initial product demands (capacity, fraction curves).
• Suitable machines and equipments.
• Right process.

PROCESS KNOWLEDGE

• WP. 3 INNOVATIVE OPTIMIZATION ENERGETIC SOLUTIONS

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Develop of a new and highly effective modeling and monitoring Energy Management System technique in order to improve Energy Efficiency and move to a low CO2 emission in the energy intensive non-metallic mineral industry.

• WP. 3 INNOVATIVE OPTIMIZATION ENERGETIC SOLUTIONS

Blasting+Drilling Hauling+loading Crushing+screeing Outbound logistics Geology

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Develop of a new and highly effective modeling and monitoring Energy Management System technique in order to improve Energy Efficiency and move to a low CO2 emission in the energy intensive non-metallic mineral industry.

• Reduction of the rejected material in closed circuit.
• Reduction-avoidance of noncompliance products. Reprocessing.
• Optimum reduction ratio for Crushers.
• Reduction of energy losses in washing systems.
• Reduction of bottlenecks in treatment plants.
• Automation:
• Total Automation of the treatment plant.
• Partial Automation.
• Frequency Variators.
• Water pumps.
• Crushers.
• Replacement of low efficiency machinery.

RESULTS

• Desired products (capacity, size distribution)
• Suitable machines (settings, capacity)
• Optimal usage of the machines
• WP. 3 INNOVATIVE OPTIMIZATION ENERGETIC SOLUTIONS

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Develop of a new and highly effective modeling and monitoring Energy Management System technique in order to improve Energy Efficiency and move to a low CO2 emission in the energy intensive non-metallic mineral industry.

• WP. 4 EE OPPORTUNITIES TO COMPENSATE CO2 EMISSIONS

ENERGY EFFICIENCY OPPORTUNITIES REDUCING CO2 IMPACTS

CO2

ENERGY WP 4 COMPENSATION CO2 FINAL EMISSIONS. FINAL ENERGY CONSUMPTION.

Generate energy efficiency opportunities and CO2 compensation activities due to the environmental impact created in its life time cycle. WP4 will take a broad and beyond vision to energy efficiency opportunities and CO2 holistic impact.

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Develop of a new and highly effective modeling and monitoring Energy Management System technique in order to improve Energy Efficiency and move to a low CO2 emission in the energy intensive non-metallic mineral industry.

• WP5. IMPLEMENTATION BENEFITS
• The overall objective of WP5 is to demonstrate and apply the solutions

developed in WP3.

• Four quarries, located in strategic positions all around Europe, will be controlled,

monitored and evaluated according to WP2 and WP3 performance indicators.

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Develop of a new and highly effective modeling and monitoring Energy Management System technique in order to improve Energy Efficiency and move to a low CO2 emission in the energy intensive non-metallic mineral industry.

• WP. 6 BUSINESS MODEL & EXPLOITATION OF THE PROJECT RESULTS

Identificate the scientific and technical knowledge, products and services generated in EE-Quarry. The exploitation plan will cover:

• Individual and whole consortium exploitation plans.
• Market analysis.
• Business models definition for the exploitation of the Project

results.

• IPR and knowledge protection strategy.

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Develop of a new and highly effective modeling and monitoring Energy Management System technique in order to improve Energy Efficiency and move to a low CO2 emission in the energy intensive non-metallic mineral industry.

WP.7 AWARENESS AND DISSEMINATION

Objectives:

• Develop an awareness and dissemination plan.
• Produce and run education and training activities.

These objectives will be served by the following elements:

• Identification and classification of target stakeholders to be addressed.
• The dissemination methods and their specific associated activities.
• Schedule and complementarily of the dissemination activities among

partners.

• Individual dissemination plans.
• The conditions to ensure proper dissemination of the generated

knowledge, related to confidentiality, publication and use of the knowledge.

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Develop of a new and highly effective modeling and monitoring Energy Management System technique in order to improve Energy Efficiency and move to a low CO2 emission in the energy intensive non-metallic mineral industry.

FINANCIAL ISSUES

The financial contribution of the European Union to the project is:

3.775.282, 52 €.

Partners contribution:

41%

Total budget of:

6.380.937,90 €

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Develop of a new and highly effective modeling and monitoring Energy Management System technique in order to improve Energy Efficiency and move to a low CO2 emission in the energy intensive non-metallic mineral industry.

PROJECT IMPACT

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Develop of a new and highly effective modeling and monitoring Energy Management System technique in order to improve Energy Efficiency and move to a low CO2 emission in the energy intensive non-metallic mineral industry.

PROJECT IMPACT

• Identification of intensive energetic extracting processes.
• Identification of energy inefficient procedures.
• Identification of energy intensive consumption equipment,

involved into the production stages and its technical requirements.

• Definition of the efficiency energetic performance indicators for

every phase.

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Develop of a new and highly effective modeling and monitoring Energy Management System technique in order to improve Energy Efficiency and move to a low CO2 emission in the energy intensive non-metallic mineral industry.

PROJECT IMPACT

• Definition of standards, recommendation and guidelines

towards to a highly energetic optimization process.

• Optimization of the blasting mechanism according to explosive

performance and desired granulometry.

• Provide the optimum aggregate size for an energetic production

process.

• Design a procedure to support energy production through

best practice techniques.

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Develop of a new and highly effective modeling and monitoring Energy Management System technique in order to improve Energy Efficiency and move to a low CO2 emission in the energy intensive non-metallic mineral industry.

PROJECT IMPACT

• Quantification of the life cycle impact of the quarry production

to define the potential impact, the energy embedded per process and the CO2 emitted.

• Define added value activities after the quarry end of life.

Production of sealable products or production of energy will be

• evaluated. Define potential Energy production and CO2

compensation sources.

• Determinate

the

• ptimum

quarry final disposition to compensate the CO2 emitted during the quarry life.

• Develop of a constant progressive and self-correcting model.

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Develop of a new and highly effective modeling and monitoring Energy Management System technique in order to improve Energy Efficiency and move to a low CO2 emission in the energy intensive non-metallic mineral industry.

CONTACT INFORMATION

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Develop of a new and highly effective modeling and monitoring Energy Management System technique in order to improve Energy Efficiency and move to a low CO2 emission in the energy intensive non-metallic mineral industry.

WEB-SITE www.ee-quarry.eu

For additional information, visit the web site…

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Develop of a new and highly effective modeling and monitoring Energy Management System technique in order to improve Energy Efficiency and move to a low CO2 emission in the energy intensive non-metallic mineral industry.

CONTACT DETAILS

• Mr. J. Antonio Barona B.

Civil Engineer (PUJ), M.Sc on Innovation, Systems and Construction Materials (IETcc), M.Sc. in Project Management (UPM) and MBA. Wide experience on engineering, field and consultancy related to the building construction & energy sector, such as novel multifunctional materials and energy efficient programs for buildings, districts and industrial facilities. More than 8 years of experience in the management, planning, execution and control of building and infrastructure construction together with the coordination of international research and development funded projects. Currently, he is project Coordinator of 2 FP7 projects focused on the construction aggregate sector, energy efficiency for industrial facilities and novel ICT solutions for energy efficient buildings and its surroundings. E-Mail: antonio.barona@solintel.eu Tel: +34 91 229 13 68 Fax: +34 91 229 13 67.