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Smart energy efficiency for industrial consumer systems
1. SMART ENERGY EFFICIENCY
FOR INDUSTRIAL
CONSUMER SYSTEMS
BY GEORGES SEIL
C.E.M.® CERTIFIED ENERGY MANAGER AND ISO50001 AUDITOR
2. SHORT BIO OF GEORGES SEIL
• Born 1952 in Luxembourg as Luxembourg citizen
• Mr Seil is a Ph.D., strategy, candidate from Rushmore University (USA) and has studied Computer Science at
the University of Hagen in Germany, Electro technic at the Technical Institute in Luxembourg and Strategy and
Finance at Rushmore University.
• Since 2005, Mr Seil is listed in the official database of the EBRD (European Bank for Reconstruction and
Development) experts and senior advisors and since 2009, he has been selected as one of the few candidates
for the position of Crisis Management Senior Advisor.
• Since 2012 Georges Seil was appointed Energy Efficiency Senior Advisor by the EBRD
• In 2013 he obtained the C.E.M. (Certified Energy Manager) certification by the international Association of
Energy Engineers.
• In 2014 he obtained the ISO50001 Auditor certification by IEMA, Ireland.
• Actually Georges is working on Energy projects in the fields of industrial systems optimization, pyrolysis and
recycling.
3. AGENDA
• What is EE?
• Threats
• Trends
• ISO50001 energy management
• Energy storage
• Waste to energy conversion
• On-site CHP
• Investment opportunities
• Biodegradable
• Plastics
• Used car tires
4. ABOUT ENERGY EFFICIENCY – WHAT IS EE?
• Efficiency is a measure of how much work or energy is conserved in a process
• The efficiency is the energy output, divided by the energy input, and expressed as a percentage
• Enout / Enin (%)
• Using less energy for the same operational processes
• Restrain energy consumption growth
• Use sector best practices
• Different methodologies oriented either to investing in new equipment or optimizing existing systems
• Cultural change
6. INDUSTRY ENERGY CONSUMPTION PROCESSES
• Cold generation by compressor systems
• HVAC mainly for offices
• Heat generation
• Compressed Air
• Light
• Ventilation systems
7. FE-METHOD DEVELOPED BY BIZ-CONSULTANT
• FE = Finite Elements; FEEBIZ = Finite Elements for EE by BIZ-Consultant
• Split the entire energy consumption processes to finite elements
• Identify each FE by its own characteristics and its own database
• Standardize all existing industrial systems by using the identified FE databases
8. FEEBIZ-METHOD SANKEY
Each element relates to its
own subject database
database includes benchmarks and
alternative components
Install data loggers
throughout the system
9. FEEBIZ-METHOD SANKEY
• Step 1: Identify all consumer locations of the industry to be assessed.
• Step 2: Fix the level of expected accurateness. This means that you fix the lowest power level of the equipment that
you want to be included in the model.
• Step 3: Do the inventory of all energy consumer equipment for each location.
• Step 4: Site visit for recording and positioning of the equipment to the model
• Step 5: Fix the data loggers to the equipment and auxiliary measurement points (pipes, supply, indoor temperature,
outdoor temperature, windows, walls, etc…)
• Step 6: Completing the model by linking all elements of the model to its element database
• Step 7: Linking the central database to all elements databases.
• Step 8: Start measurement cycle
• Step 9: Transfer the model to the ISO50001 energy accounting system
• Step 10: Build the global daily energy profile by using energy input power metering for electric, gas and other energy
input systems.
10. THREATS AND BARRIERS
• Industries allow only short payback periods for investments - <=3 years
• Acceptance of Energy Assessments by proven and certified experts
• Acceptance of process optimization versus equipment replacement
• Inhouse high/low energy efficiency know how
• New industries might already benefit from high efficiency – just don‘t know it
• Elder industries might have the high potential for savings, but lack acceptance of the assessments
• There are too many self-claimed energy experts, mainly in the building sector.
11. TRENDS
• ISO 50001
• Not focused to certification, but to implementation of an Energy Management System
• ISO 50001 provides the strong ground for assessment, measuring, creating the reference measures and
planning the efficiency measures
• ISO 50001 builds awareness about processes and behavior
12. TRENDS
• Energy Storage
• Running a 3-tariff costs structure for electric energy and using energy storage for storing energy at low
costs and using energy at high costs tariffs
• Using free capacity (night) for producing cold and releasing the cold in day time (warm)
• Storing excess Solar PV-energy on day time for releasing on night time.
Cold storage system ICEBAT
14. COSTS DISTRIBUTION WITH 3-TARIFF SYSTEM
Use energy
during this phase
Reduce energy in
this phase
E1
E2
E2 > E1=savings
15. WASTE TO ENERGY CONVERSION
• Municipal waste to thermal and electric energy – by incineration;
• some 90% of its initial volume goes up in smoke – filtered- thus substantially reducing landfills by up to 80%
• burned in the post-combustion chamber at temperatures of 800 to 900°C – today dioxin free
• 70 to 80% of the combustion heat recovered after incineration – good efficiency
• about 1,500 kWh of thermal energy per ton of refuse – rather high
• Electric energy efficiency of this process is about 20 to 25% (300 to 400 kWh /ton of refuse). – rather low
• Investments: up from 50-100 M€
• Payback: not less than 10 years
16. WASTE TO ENERGY CONVERSION
• By Plasma technology
• Converts all waste and
Input material to Syngas and
Basalt like rock material
• Excellent for recovering all
Base material
• Investment: up from 100 M€
• Payback: 5-15 years, depends on primary energy
costs
17. WASTE TO ENERGY CONVERSION
• Pyrolysis for Plastics and used car tires
• Operating temperature range: 400-600°C
• Input: waste plastics except PVC; used car tire pellets
• Output:
• pyrolysis gas used for thermo-electric process
• Black carbon for industrial use
• Thermal energy
• Electric energy
• Investment: 4-5 M€ for 8000 tons/year
• Payback: 3-5 years
18. ON-SITE CHP
• On-site generation is a profitable option to improve industrial energy efficiency, cut down energy costs and improve security
and availability of power supply.
• New efficient capacity to replace inefficient and retiring capacity,
• More flexible generation mix since on-site generation adapts to economic cycles,
• Reduced need for transmission and distribution as a result of local generation, and
• Increased use of local energy sources.
• Highly efficient power generation if designed in balance with the heat and power demand of the industrial facility,
• Avoidance of high transmission costs,
• Avoidance of high grid connection fees, if choosing to remain off the grid, and
• Opportunity to sell heat and electricity to external industrial clients through own distribution lines.
• Opportunity for on-site generation depends on local prices for electricity, grid connection and transmission, the availability of
inexpensive fuels and site-specific conditions
19. INVESTMENT OPPORTUNITIES
• Biogas Plant
• Electric output Investment by kWel Overall investment
• 30 kWel € 7500 - € 8500 € 240 000
• 100 kWel € 4000 - € 6000 € 500 000
• 500 kWel € 3500 - € 5000 € 2 000 000
• 1 MWel € 3000 - € 4500 € 3 000 000
• IRR: <=12-15%
• Payback: between 3-6 years; all depending on the level of subsidies on investment and on the level of the Feed-In tariffs.
• Prior tasks and expenditures: feasibility study, environmental impact assessment study, permits, land acquisition and permits.
• Financing: project financing, special EU programmes, private investors
• Threats: contracts with the feedstock suppliers; variable feedstock prices may apply
20. INVESTMENT OPPORTUNITIES
• Pyrolysis for used car tires
• Rubber pellets 5-8mm
• 24000 MWhe /year for 8000tons rubber input
• Plus sales of carbon black, plus thermal energy
• Payback: 3-4 years
• Investment: 5 M€
21. INVESTMENT OPPORTUNITIES
• Pyrolysis – Plastics
• 1kg plastics input produce 0,8liter pyrolysis oil
• Thus 8000 tons plastics produce 65,000 Mwhe – electric energy
• Invest for 8000 tons/year: +-8 M€
• Payback: 3-5 years
• To be combined with PET and LDPE recycling plant, offers self sufficient recycling
• Using with WEEE recycling enables pyrolysis of plastics and cables by generating still good revenue
22. INVESTMENT OPPORTUNITIES
Items Application Sales Market
45% Pyrolysis oil (tire
oil/plastic oil)
1. Add it into heavy oil generator
to produce electricity. 2. Used as
heating material. 3. Sell it into
oil refining factory to further
process it.
Ceramic factory, glass factory,
electric power factory, steel
making factory, boiler
factory…etc.
30% Carbon black
1. Make it into pellet or
briquette for burning. 2. Further
process it into color master
batch as basic material to make
pipes, cable jacket…etc.
Coal briquette factory, plastic
factory, cable factory, etc.
10% Waste gas Recycled into fire furnace to heat reactor to save fuel material.
End Products in Pyrolysis