sharebox on-line training symbiotic exchange of energy:...
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SHAREBOX on-line training
Symbiotic exchange of energy: Technologies and management
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Introduction - SHAREBOX Energy Tool Overview
SHAREBOX Energy Tool
Symbiotic Relationship w.r.t Waste
Energy
Identifying Synergies
Opportunities
Systematic Decision Making;
Maximize Business
Opportunities
Enabling Dynamic Control
and Management
Compared and Assessed Synergy
Opportunity
In-house, Industrial
Cluster and/or Wider Energy
Network
Detailed Modelling and
Simplified Algorithms
Life-cycle Cost Impact of Candidate Options
Optimum Waste to Energy &
Storage Technology Utilization
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Waste Heat to Energy and Storage Integration Database & Cost Modelling
Waste heat sourcesData base has Efficiency score, which can be weighted by usersGives an overall rating of technologies
Conversiontechnologies
Co
nve
rsio
n s
co
res
Storagetechnologies
Sto
rag
e s
co
res
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End-User Modelling & Optimization
Optimized Waste Heat Symbiosis
Sheet
Waste Heat
Step 1: Matching would be done within 30 KM radius for waste heat “have” and “want”.
Step 2: Matching the available waste heat temperature range to required
Step 3: Matching quantity of waste heat (KWh/ year) available to required.
Step 4: Matching hours of the day availability of waste heat for symbiosis
Step 5: Matching the selling and purchase price for the waste heat
Step 6: Applications segregation
Step 7: Waste and storage technologies matching
Industry Name
Geographical LocationIndustry ClassificationSymbiosis Industry NameQuality available for waste heat symbiosis (°C)
Quantity required for waste heat symbiosis
(KWh/ year)Quantity percentage of waste heat symbiosis (%)
Waste heat trading hours (hrs)
Waste heat price ($/ KWh)Application for waste heat utilization
Optimized waste heat to energy technology
Optimized Storage technology
Annual Savings’ from process optimization
and/or electricity generation ($)
Waste Heat
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End-User Modelling & Optimization
Optimized Electricity Symbiosis
Sheet
Industry Name
Geographical Location
Industry Classification
Symbiosis Industry
Name
Time Category
Symbiosis tariff within
Industrial park ($/KWh)
Tariff to feedback to
Electric grid
Selected symbiosis
choice (Industrial park or
grid)
Electricity
Step1: Matching would be done within 30 KM radius for excess electricity “have” and “want”.
Step 2: Matching hours of the day, availability of electricity for symbiosis
Step 3: Matching quantity of electricity (KWh/ year) available to required.
Step 4: Matching the selling and purchase price for the electricity
Electricity
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Potential of symbiotic energy exchange –The ICO example
Industrie Center Obernburg industrial park near Frankfurt, Germany, operated my Mainsite
Power station120 MWel, powered by
natural gas90 % efficiency
Electricity
Heat
Industrial processes on the site
Surplus: into national grid
Industrial processes on the site
Sewage sludge drying facility for neighboring municipalities
Heating for neighboring housing
Swimming pool for industrial park workers and their families
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Energy Tool- Integration to SHAREBOX
1. Location Indicator
2. Industry Classification
3. Industry Particulars
4. Heat and Electricity “have” and “want” Mapping
5. Desired Waste to Energy Application
6. Application Multi-Criterial Assessment
7. Selection of most important factor for Industrial Symbiosis
8. Available waste to energy and associated storage technologies for desired application
9. Waste to Energy and Storage Technologies weightings for User-specified Analysis
10. Industry specific scores for W-E and storage technology options
11. Waste to Energy symbiosis selection
12. Regulations
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External Optimization Tool – Merit
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The SHAREBOX Approach
SHAREBOX Energy Tool
Symbiotic Relationship w.r.t Waste Energy
Identifying Synergies Opportunities
Systematic Decision Making; Maximize Business Opportunities
Enabling Dynamic Control and Management
Compared and Assessed Synergy Opportunity
In-house, Industrial Cluster and/or Wider Energy Network
Detailed Modelling and Simplified Algorithms
Life-cycle Cost Impact of Candidate Options
Optimum Waste to Energy & Storage Technology Utilization
External Optimisation
External to SHAREBOX Platform
Internal to SHAREBOX Platform
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Réseau: Simulation of Supply and Demand
Réseau: agent-based simulation of manufacturing and transactionsBuyers and Sellers (Agents) managed by a single System object
• System: controls the order of events, and maintains historic data• Factories, market buyers/sellers (Agents):
Key Innovation: combines complex decision rationale with process models The decision rules: Random price, Best price, Risk-based, Contract
G.O. Ajisegiri 2019. Simulation of the Interaction between Supply And Demand in an Eco-Industrial Park. PhD thesis
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Technology Options Ranking
Company Resource Name Description SIC Description Supply Type starting at stopping at Intensity nature Resource
Type
Available Quantity
TJ/yr
MWhr/yr
cmp1 Adjacent Energy Sink Sound recording and music
publishing activities
Continuous UL 60C water have 5 1389
cmp2 Alternative energy Alternative Energy to
propane gas - 150 tonnes
Manufacture of hollow glass Continuous h gas Want 7.5 2083
cmp3 CHP - recovering power / heat
from cold stores
Processing and preserving of
potatoes
Continuous UL 60C water have 5 1389
cmp4 CHP Unit Remediation activities and
other waste management
services
Continuous L lp steam want 12 3333
cmp5 CHP unit Growing of cereals (except
rice), leguminous crops and oil
seeds
Continuous UL 60C water Want 5 1389
cmp6 Energy Recovery System Remediation activities and
other waste management
services
Continuous UL 60C water have 5 1389
cmp7 Energy Recovery System Growing of cereals (except
rice), leguminous crops and oil
seeds
Continuous h husks have 56.4 15667
cmp8 Energy Supply 1-10MW Remediation activities and
other waste management
services
Continuous h elec Want 36 10000
cmp9 HEAT Construction of commercial
buildings
06:00 16:00 L IP steam Want 12 3333
cmp10 Heat - 1MW/hr Construction of commercial
buildings
06:00 16:00 L/H lp steam, gas elec Want 15.8 4380
cmp11 Heat - 1MW/hr Recovery of sorted materials 08:00 18:00 L lp Have 15.8 4380
cmp12 Heat 1MW Per Hour Recovery of sorted materials 08:00 18:00 UL 60C water Have 15.8 4380
cmp13 Heat from AD plant Real estate agencies 08:00 18:00 UL 60C water Have 3.6 1000
cmp14 Heating Source that
incinerates recyclables
Heating Source that
incinerates recyclables
Manufacture of electric
lighting equipment
Continuous H solid waste have 3.6 1000
cmp15 Steam Packaging activities Continuous L lp steam Have 20 5556
cmp16 Steam Generation New methods of Steam
Generation
Manufacture of prepared feeds
for farm animals
Continuous L lp steam Want 20 5556
cmp17 Waste heat Growing of cereals (except
rice), leguminous crops and oil
seeds
Continuous L lp ateam Want 3.6 1000
MERIT
Demand/ Supply
Matching Score
Collection ofEnergy Have/WantsReal DataFor application X
Manufacturing profilesRéseauAgent based Trading
MinimisedResidual D/S
Approach:
Case-based reasoning for identifying the best synergy solution
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Limitations in storing energy (especially electricity) at reasonable costs
Limitations in transporting energy (especially heat) at reasonable costs
Temporary shifts in availability may inhibit matching of supply and demand
Expert knowledge and sophisticated technologies may be required tovalorize remaining energy supplies, e. g. low temperature heat
Investment for secondary use may cost more than just buying primary energy
Regulatory restrictions or restrictions in availability of space
Challenges
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Ajisegiri, G.O. 2019. Simulation of the Interaction between Supply And Demand in an Eco-Industrial Park. PhD thesis, University of Leeds
Literature for further studies
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Authors of this presentation
www.spire2030.euAnsgar Rudolph
Frans Muller
Hassan Javed
Andrew Heyes
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The project: SHAREBOX
▪ Joint project funded by EU (Horizon 2020)
▪ 16 project partners from 8 countries
▪ EC funding (A): 5.416.544,75 €
▪ Private investment (B): 1.500.000 €
▪ Funding period: 2015-2019
www.spire2030.eu
Secure Management Platform for Sharing Process Resources
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