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Project overview Multi-fuel energy
generation for Sustainable and Efficient use of
Coal (SECoal) Speaker Sylwester
Kalisz
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KIC InnoEnergy CC Poland project review
Krakow, 11-12 April 2011
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SECoal project - goal and impacts

• Objective
• SECoal project is dedicated to deliver innovative
  approaches to the co-utilization of multi-fuel
  inputs of various origin and quality in
  conjunction with coal-based power generation. It
  aims at quick delivery of industrially demanded,
  yet innovative, technological solutions and
  products ready for direct deployment in power
  utilities
• For existing business processes
• SECoal will enhance security of energy supply
  through diversification of fuels contribute to
  reduction of greenhouse gas emissions through
  enhanced usage of bio-derived fuels
• SECoal will deliver incremental innovation
  technologies directly applicable in related
  industries
• SECoal will contribute to reduction of operating
  costs of power generation utilities
• For new business processes
• SECoal will deliver innovative co-firing
  technologies thanks to services provided by
  dedicated, newly established spin-off company

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SECoal project summary
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SECoal project WP organisation
WP0 MANAGEMENT AND MARKET ANALYSES
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SECoal project WPs
WORK PACKAGE DESCRIPTION WORK PACKAGE DESCRIPTION WP No 0
  Work package Title   Project management, techno-economic, market and patent analyses   Project management, techno-economic, market and patent analyses   Project management, techno-economic, market and patent analyses
  Institution(s)   Task leader   ALL partners   SUT ALL partners   SUT ALL partners   SUT
Objectives secure best practices in project management and thematic coordination deliver business oriented techno-economic analyses of SECoal products deliver market search analyses for implementation of SECoal products deliver patent search analyses for better management of SECoal IP rights   Objectives secure best practices in project management and thematic coordination deliver business oriented techno-economic analyses of SECoal products deliver market search analyses for implementation of SECoal products deliver patent search analyses for better management of SECoal IP rights   Objectives secure best practices in project management and thematic coordination deliver business oriented techno-economic analyses of SECoal products deliver market search analyses for implementation of SECoal products deliver patent search analyses for better management of SECoal IP rights   Objectives secure best practices in project management and thematic coordination deliver business oriented techno-economic analyses of SECoal products deliver market search analyses for implementation of SECoal products deliver patent search analyses for better management of SECoal IP rights  
Work plan and distribution of tasks   Task 0.1 Project coordination thematic coordination tasks coordination budget and timeline coordination   Task 0.2 Techno-economic analysis of WtE (Waste-to-Energy) opportunities waste fuel availability ranking of technologies regulatory constraints and opportunities competing waste fuel handling technologies market depth   Task 0.3 Techno-economic analyses of direct and in-direct co-firing scenarios energy density and transportation issues - pelletizing vs. torrefaction technology barriers in direct co-firing technology barriers in in-direct co-firing regulatory constraints and opportunities business opportunities   Task 0.4 Patenting and IP rights management support to product patenting patent search services, patent filing   Work plan and distribution of tasks   Task 0.1 Project coordination thematic coordination tasks coordination budget and timeline coordination   Task 0.2 Techno-economic analysis of WtE (Waste-to-Energy) opportunities waste fuel availability ranking of technologies regulatory constraints and opportunities competing waste fuel handling technologies market depth   Task 0.3 Techno-economic analyses of direct and in-direct co-firing scenarios energy density and transportation issues - pelletizing vs. torrefaction technology barriers in direct co-firing technology barriers in in-direct co-firing regulatory constraints and opportunities business opportunities   Task 0.4 Patenting and IP rights management support to product patenting patent search services, patent filing   Work plan and distribution of tasks   Task 0.1 Project coordination thematic coordination tasks coordination budget and timeline coordination   Task 0.2 Techno-economic analysis of WtE (Waste-to-Energy) opportunities waste fuel availability ranking of technologies regulatory constraints and opportunities competing waste fuel handling technologies market depth   Task 0.3 Techno-economic analyses of direct and in-direct co-firing scenarios energy density and transportation issues - pelletizing vs. torrefaction technology barriers in direct co-firing technology barriers in in-direct co-firing regulatory constraints and opportunities business opportunities   Task 0.4 Patenting and IP rights management support to product patenting patent search services, patent filing   Work plan and distribution of tasks   Task 0.1 Project coordination thematic coordination tasks coordination budget and timeline coordination   Task 0.2 Techno-economic analysis of WtE (Waste-to-Energy) opportunities waste fuel availability ranking of technologies regulatory constraints and opportunities competing waste fuel handling technologies market depth   Task 0.3 Techno-economic analyses of direct and in-direct co-firing scenarios energy density and transportation issues - pelletizing vs. torrefaction technology barriers in direct co-firing technology barriers in in-direct co-firing regulatory constraints and opportunities business opportunities   Task 0.4 Patenting and IP rights management support to product patenting patent search services, patent filing  
Milestones   M 0.2.1 Data on WtE opportunities gathered (Q3 2011) M 0.3.1 Data on best co-firing practices gathered (Q3 2011)   Milestones   M 0.2.1 Data on WtE opportunities gathered (Q3 2011) M 0.3.1 Data on best co-firing practices gathered (Q3 2011)   Milestones   M 0.2.1 Data on WtE opportunities gathered (Q3 2011) M 0.3.1 Data on best co-firing practices gathered (Q3 2011)   Milestones   M 0.2.1 Data on WtE opportunities gathered (Q3 2011) M 0.3.1 Data on best co-firing practices gathered (Q3 2011)  
Deliverables/Outcome KPI   D 0.2.1 Report on WtE opportunities (Q1 2012) D 0.3.1 Report on best co-firing practices (Q1 2012)   Deliverables/Outcome KPI   D 0.2.1 Report on WtE opportunities (Q1 2012) D 0.3.1 Report on best co-firing practices (Q1 2012)   Deliverables/Outcome KPI   D 0.2.1 Report on WtE opportunities (Q1 2012) D 0.3.1 Report on best co-firing practices (Q1 2012)   Deliverables/Outcome KPI   D 0.2.1 Report on WtE opportunities (Q1 2012) D 0.3.1 Report on best co-firing practices (Q1 2012)  
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SECoal project WPs
WORK PACKAGE DESCRIPTION WORK PACKAGE DESCRIPTION WP No 1
  Work package Title   Components for advanced co-utilization concepts   Components for advanced co-utilization concepts   Components for advanced co-utilization concepts
  Institution(s)   Contact person (s)   IFK (J.Maier/M.Zieba) WP Leader SUT-IPET (M.Pronobis, S.Kalisz) WUT-IPEFM (H.Kruczek) KIT (H.J.Gehrmann) KTH-EFT (W.Yang) IFK (J.Maier/M.Zieba) WP Leader SUT-IPET (M.Pronobis, S.Kalisz) WUT-IPEFM (H.Kruczek) KIT (H.J.Gehrmann) KTH-EFT (W.Yang) IFK (J.Maier/M.Zieba) WP Leader SUT-IPET (M.Pronobis, S.Kalisz) WUT-IPEFM (H.Kruczek) KIT (H.J.Gehrmann) KTH-EFT (W.Yang)
Objectives The success of advanced co-utilization of different fuels depends on reliability of a single component in the whole production chain. WP1 is focused on - identification of limiting processes and components - identification of promising technologies to overcome the limits - testing these technologies in a scale which is directly transferrable to the related industries so as the co-utilization is realized in a realistic and cost-effective manner in a short period of time.   Objectives The success of advanced co-utilization of different fuels depends on reliability of a single component in the whole production chain. WP1 is focused on - identification of limiting processes and components - identification of promising technologies to overcome the limits - testing these technologies in a scale which is directly transferrable to the related industries so as the co-utilization is realized in a realistic and cost-effective manner in a short period of time.   Objectives The success of advanced co-utilization of different fuels depends on reliability of a single component in the whole production chain. WP1 is focused on - identification of limiting processes and components - identification of promising technologies to overcome the limits - testing these technologies in a scale which is directly transferrable to the related industries so as the co-utilization is realized in a realistic and cost-effective manner in a short period of time.   Objectives The success of advanced co-utilization of different fuels depends on reliability of a single component in the whole production chain. WP1 is focused on - identification of limiting processes and components - identification of promising technologies to overcome the limits - testing these technologies in a scale which is directly transferrable to the related industries so as the co-utilization is realized in a realistic and cost-effective manner in a short period of time.  
Work plan and distribution of tasks (including timing of tasks) see time schedule   Task 1.1 Direct co-utilization at high shares (SUT- IPET task leader)   Task 1.2. Indirect (satellite) co-utilization concepts (KIT task leader) Task 1.3. Fuel predrying process for co-utilization (WUT-IPEFM task leader)   Task 1.4. Milling methodology for high share biomass co-utilisation (SUT-IPET task leader) Task 1.5 Innovative, multi-fuel low-emission burner concepts (IFK task leader) Work plan and distribution of tasks (including timing of tasks) see time schedule   Task 1.1 Direct co-utilization at high shares (SUT- IPET task leader)   Task 1.2. Indirect (satellite) co-utilization concepts (KIT task leader) Task 1.3. Fuel predrying process for co-utilization (WUT-IPEFM task leader)   Task 1.4. Milling methodology for high share biomass co-utilisation (SUT-IPET task leader) Task 1.5 Innovative, multi-fuel low-emission burner concepts (IFK task leader) Work plan and distribution of tasks (including timing of tasks) see time schedule   Task 1.1 Direct co-utilization at high shares (SUT- IPET task leader)   Task 1.2. Indirect (satellite) co-utilization concepts (KIT task leader) Task 1.3. Fuel predrying process for co-utilization (WUT-IPEFM task leader)   Task 1.4. Milling methodology for high share biomass co-utilisation (SUT-IPET task leader) Task 1.5 Innovative, multi-fuel low-emission burner concepts (IFK task leader) Work plan and distribution of tasks (including timing of tasks) see time schedule   Task 1.1 Direct co-utilization at high shares (SUT- IPET task leader)   Task 1.2. Indirect (satellite) co-utilization concepts (KIT task leader) Task 1.3. Fuel predrying process for co-utilization (WUT-IPEFM task leader)   Task 1.4. Milling methodology for high share biomass co-utilisation (SUT-IPET task leader) Task 1.5 Innovative, multi-fuel low-emission burner concepts (IFK task leader)
Links to KIC InnoEnergy Strategy   Exploitation Links to innovation system WP1 will work out innovative approaches to relatively mature technologies in order to increase the share of co-utilized fuels. As such the delivered solutions will have to interact with existing technological infrastructures bridging the 'old' with the 'new' . Consequently the proposed solutions will be the base for a novel co-utlization concepts to be developed in WP4.   Education Links to education programs WP1 will contribute to the Summer School foreseen in WP5. Findings from WP1 will be presented at the related EIT labelled courses.   Links to KIC InnoEnergy Strategy   Exploitation Links to innovation system WP1 will work out innovative approaches to relatively mature technologies in order to increase the share of co-utilized fuels. As such the delivered solutions will have to interact with existing technological infrastructures bridging the 'old' with the 'new' . Consequently the proposed solutions will be the base for a novel co-utlization concepts to be developed in WP4.   Education Links to education programs WP1 will contribute to the Summer School foreseen in WP5. Findings from WP1 will be presented at the related EIT labelled courses.   Links to KIC InnoEnergy Strategy   Exploitation Links to innovation system WP1 will work out innovative approaches to relatively mature technologies in order to increase the share of co-utilized fuels. As such the delivered solutions will have to interact with existing technological infrastructures bridging the 'old' with the 'new' . Consequently the proposed solutions will be the base for a novel co-utlization concepts to be developed in WP4.   Education Links to education programs WP1 will contribute to the Summer School foreseen in WP5. Findings from WP1 will be presented at the related EIT labelled courses.   Links to KIC InnoEnergy Strategy   Exploitation Links to innovation system WP1 will work out innovative approaches to relatively mature technologies in order to increase the share of co-utilized fuels. As such the delivered solutions will have to interact with existing technological infrastructures bridging the 'old' with the 'new' . Consequently the proposed solutions will be the base for a novel co-utlization concepts to be developed in WP4.   Education Links to education programs WP1 will contribute to the Summer School foreseen in WP5. Findings from WP1 will be presented at the related EIT labelled courses.  
Deliverables/Outcome KPI   D1.1.2 Evaluation of at least 5 different direct co-firing applications (Biomass/RDF/share etc.) with respect to firing concept, burnout and possible fly ash utilization routes and limitations (IFK) (Q2 2013) D1.1.3 Evaluation of feasibility of the implementation of a pulverized burner in a grate system) (Q4 2012) (KIT) D1.2.2 A novel biomass pretreatment technology (hydro-treatment) (KTH) (Q4 2011) D1.3.1 Testing and evaluation predrying biomass methods (Q4 2012) D1.4.1 Report on possibility of application of standard grindability index (Q4 2012) D1.5.1 Applicability of flameless combustion for utilization of bio-derived LCV gases (IFK, IST) (Q4 2012) Deliverables/Outcome KPI   D1.1.2 Evaluation of at least 5 different direct co-firing applications (Biomass/RDF/share etc.) with respect to firing concept, burnout and possible fly ash utilization routes and limitations (IFK) (Q2 2013) D1.1.3 Evaluation of feasibility of the implementation of a pulverized burner in a grate system) (Q4 2012) (KIT) D1.2.2 A novel biomass pretreatment technology (hydro-treatment) (KTH) (Q4 2011) D1.3.1 Testing and evaluation predrying biomass methods (Q4 2012) D1.4.1 Report on possibility of application of standard grindability index (Q4 2012) D1.5.1 Applicability of flameless combustion for utilization of bio-derived LCV gases (IFK, IST) (Q4 2012) Deliverables/Outcome KPI   D1.1.2 Evaluation of at least 5 different direct co-firing applications (Biomass/RDF/share etc.) with respect to firing concept, burnout and possible fly ash utilization routes and limitations (IFK) (Q2 2013) D1.1.3 Evaluation of feasibility of the implementation of a pulverized burner in a grate system) (Q4 2012) (KIT) D1.2.2 A novel biomass pretreatment technology (hydro-treatment) (KTH) (Q4 2011) D1.3.1 Testing and evaluation predrying biomass methods (Q4 2012) D1.4.1 Report on possibility of application of standard grindability index (Q4 2012) D1.5.1 Applicability of flameless combustion for utilization of bio-derived LCV gases (IFK, IST) (Q4 2012) Deliverables/Outcome KPI   D1.1.2 Evaluation of at least 5 different direct co-firing applications (Biomass/RDF/share etc.) with respect to firing concept, burnout and possible fly ash utilization routes and limitations (IFK) (Q2 2013) D1.1.3 Evaluation of feasibility of the implementation of a pulverized burner in a grate system) (Q4 2012) (KIT) D1.2.2 A novel biomass pretreatment technology (hydro-treatment) (KTH) (Q4 2011) D1.3.1 Testing and evaluation predrying biomass methods (Q4 2012) D1.4.1 Report on possibility of application of standard grindability index (Q4 2012) D1.5.1 Applicability of flameless combustion for utilization of bio-derived LCV gases (IFK, IST) (Q4 2012)
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SECoal project WPs
WORK PACKAGE DESCRIPTION WORK PACKAGE DESCRIPTION WP No 2
  Work package Title   Efficient and economic utilization of lean gases from in situ processing of coals   Efficient and economic utilization of lean gases from in situ processing of coals   Efficient and economic utilization of lean gases from in situ processing of coals
  Institution(s)   Contact person (s)   UJ (A. Adamski) WP Leader ICE-PAS (K.Gosiewski) SUT-IPET (M.Pronobis/S.Kalisz) IFK (M.Zieba) WUT-DCTF (J.Trawczynski) UJ (A. Adamski) WP Leader ICE-PAS (K.Gosiewski) SUT-IPET (M.Pronobis/S.Kalisz) IFK (M.Zieba) WUT-DCTF (J.Trawczynski) UJ (A. Adamski) WP Leader ICE-PAS (K.Gosiewski) SUT-IPET (M.Pronobis/S.Kalisz) IFK (M.Zieba) WUT-DCTF (J.Trawczynski)
Objectives WP2 is focused on - inventory of coal mine methane emissions - catalytic combustion of lean methane-air mixtures - non-catalytic combustion of lean methane-air mixtures - power generation with use of waste, low calorific value gases   Objectives WP2 is focused on - inventory of coal mine methane emissions - catalytic combustion of lean methane-air mixtures - non-catalytic combustion of lean methane-air mixtures - power generation with use of waste, low calorific value gases   Objectives WP2 is focused on - inventory of coal mine methane emissions - catalytic combustion of lean methane-air mixtures - non-catalytic combustion of lean methane-air mixtures - power generation with use of waste, low calorific value gases   Objectives WP2 is focused on - inventory of coal mine methane emissions - catalytic combustion of lean methane-air mixtures - non-catalytic combustion of lean methane-air mixtures - power generation with use of waste, low calorific value gases  
Work plan and distribution of tasks (including timing of tasks) see time schedule   Task 2.1 Inventory and characterization of coal mine methane emissions with particular emphasis on Ventilation Air Methane - VAM Task 2.2 Catalytic combustion of lean methane-air mixtures including evaluation of catalytic systems and determination of minimal content of CH4 allowing its autothermic combustion (UJ, WUT-DCTF)   Development of the oxide binary/ternary catalyst Development of methane enrichment system Catalytic tests and catalyst shaping - laboratory and real VAM feed    Task 2.3 Direct, non-catalytic combustion methods of CH4-lean gases (SUT-IPET, IFK, ICE-PAS) Adaptation and testing of flameless burner for utilization or flaring of CH4-lean gases (IFK) Reverse flow non-catalytic combustion of coal mine VAM (ICE-PAS). Total cost 400 k   Work plan and distribution of tasks (including timing of tasks) see time schedule   Task 2.1 Inventory and characterization of coal mine methane emissions with particular emphasis on Ventilation Air Methane - VAM Task 2.2 Catalytic combustion of lean methane-air mixtures including evaluation of catalytic systems and determination of minimal content of CH4 allowing its autothermic combustion (UJ, WUT-DCTF)   Development of the oxide binary/ternary catalyst Development of methane enrichment system Catalytic tests and catalyst shaping - laboratory and real VAM feed    Task 2.3 Direct, non-catalytic combustion methods of CH4-lean gases (SUT-IPET, IFK, ICE-PAS) Adaptation and testing of flameless burner for utilization or flaring of CH4-lean gases (IFK) Reverse flow non-catalytic combustion of coal mine VAM (ICE-PAS). Total cost 400 k   Work plan and distribution of tasks (including timing of tasks) see time schedule   Task 2.1 Inventory and characterization of coal mine methane emissions with particular emphasis on Ventilation Air Methane - VAM Task 2.2 Catalytic combustion of lean methane-air mixtures including evaluation of catalytic systems and determination of minimal content of CH4 allowing its autothermic combustion (UJ, WUT-DCTF)   Development of the oxide binary/ternary catalyst Development of methane enrichment system Catalytic tests and catalyst shaping - laboratory and real VAM feed    Task 2.3 Direct, non-catalytic combustion methods of CH4-lean gases (SUT-IPET, IFK, ICE-PAS) Adaptation and testing of flameless burner for utilization or flaring of CH4-lean gases (IFK) Reverse flow non-catalytic combustion of coal mine VAM (ICE-PAS). Total cost 400 k   Work plan and distribution of tasks (including timing of tasks) see time schedule   Task 2.1 Inventory and characterization of coal mine methane emissions with particular emphasis on Ventilation Air Methane - VAM Task 2.2 Catalytic combustion of lean methane-air mixtures including evaluation of catalytic systems and determination of minimal content of CH4 allowing its autothermic combustion (UJ, WUT-DCTF)   Development of the oxide binary/ternary catalyst Development of methane enrichment system Catalytic tests and catalyst shaping - laboratory and real VAM feed    Task 2.3 Direct, non-catalytic combustion methods of CH4-lean gases (SUT-IPET, IFK, ICE-PAS) Adaptation and testing of flameless burner for utilization or flaring of CH4-lean gases (IFK) Reverse flow non-catalytic combustion of coal mine VAM (ICE-PAS). Total cost 400 k  
Links to KIC InnoEnergy Strategy   Exploitation Links to innovation system - WP2 will contribute to utilization of a massive streams of a greenhouse gas (methane) in an energy recovery processes Education Links to education programs WP2 will contribute to the Summer School foreseen in WP5. Findings from WP2 will be presented at the related EIT MSc and PhD labeled courses.   Links to KIC InnoEnergy Strategy   Exploitation Links to innovation system - WP2 will contribute to utilization of a massive streams of a greenhouse gas (methane) in an energy recovery processes Education Links to education programs WP2 will contribute to the Summer School foreseen in WP5. Findings from WP2 will be presented at the related EIT MSc and PhD labeled courses.   Links to KIC InnoEnergy Strategy   Exploitation Links to innovation system - WP2 will contribute to utilization of a massive streams of a greenhouse gas (methane) in an energy recovery processes Education Links to education programs WP2 will contribute to the Summer School foreseen in WP5. Findings from WP2 will be presented at the related EIT MSc and PhD labeled courses.   Links to KIC InnoEnergy Strategy   Exploitation Links to innovation system - WP2 will contribute to utilization of a massive streams of a greenhouse gas (methane) in an energy recovery processes Education Links to education programs WP2 will contribute to the Summer School foreseen in WP5. Findings from WP2 will be presented at the related EIT MSc and PhD labeled courses.  
Deliverables/Outcome KPI   D2.2.1 Report on formulation and performance of catalyst for lean methane total combustion (Q2 2013) UJ D2.2.2 Technical report on catalytic VAM mitigation (Q2 2013) WUT-DCTF D2.2.3 Patent applications on catalyst for methane total combustion (Q4 2011/Q4 2012) D2.3.1 Report on testing of the flameless burner for the utilization of CH4-lean gases (Q4 2012)IFK D2.3.2 Selection of the appropriate honeycomb monolith geometry together with the combustion kinetic description for this monolith. (Q4 2012) ICE-PAS D2.3.3 Basic design parameters for the TFRR pilot research unit (Q4 2013) ICE-PAS   Deliverables/Outcome KPI   D2.2.1 Report on formulation and performance of catalyst for lean methane total combustion (Q2 2013) UJ D2.2.2 Technical report on catalytic VAM mitigation (Q2 2013) WUT-DCTF D2.2.3 Patent applications on catalyst for methane total combustion (Q4 2011/Q4 2012) D2.3.1 Report on testing of the flameless burner for the utilization of CH4-lean gases (Q4 2012)IFK D2.3.2 Selection of the appropriate honeycomb monolith geometry together with the combustion kinetic description for this monolith. (Q4 2012) ICE-PAS D2.3.3 Basic design parameters for the TFRR pilot research unit (Q4 2013) ICE-PAS   Deliverables/Outcome KPI   D2.2.1 Report on formulation and performance of catalyst for lean methane total combustion (Q2 2013) UJ D2.2.2 Technical report on catalytic VAM mitigation (Q2 2013) WUT-DCTF D2.2.3 Patent applications on catalyst for methane total combustion (Q4 2011/Q4 2012) D2.3.1 Report on testing of the flameless burner for the utilization of CH4-lean gases (Q4 2012)IFK D2.3.2 Selection of the appropriate honeycomb monolith geometry together with the combustion kinetic description for this monolith. (Q4 2012) ICE-PAS D2.3.3 Basic design parameters for the TFRR pilot research unit (Q4 2013) ICE-PAS   Deliverables/Outcome KPI   D2.2.1 Report on formulation and performance of catalyst for lean methane total combustion (Q2 2013) UJ D2.2.2 Technical report on catalytic VAM mitigation (Q2 2013) WUT-DCTF D2.2.3 Patent applications on catalyst for methane total combustion (Q4 2011/Q4 2012) D2.3.1 Report on testing of the flameless burner for the utilization of CH4-lean gases (Q4 2012)IFK D2.3.2 Selection of the appropriate honeycomb monolith geometry together with the combustion kinetic description for this monolith. (Q4 2012) ICE-PAS D2.3.3 Basic design parameters for the TFRR pilot research unit (Q4 2013) ICE-PAS  
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SECoal project WPs
WORK PACKAGE DESCRIPTION WORK PACKAGE DESCRIPTION WP No 3
  Work package Title   Modeling tools, monitoring and control of multi-fuel power generation   Modeling tools, monitoring and control of multi-fuel power generation   Modeling tools, monitoring and control of multi-fuel power generation
  Institution(s)   Contact person (s)   WUT-IPEFM (H.Kruczek) WP Leader CzUT (W.Nowak/R.Rajczyk) SUT-IPET (M.Pronobis/S.Kalisz) CUT (J.Taler/P.Wais) BZF (G.B.Lenkey) WUT-IPEFM (H.Kruczek) WP Leader CzUT (W.Nowak/R.Rajczyk) SUT-IPET (M.Pronobis/S.Kalisz) CUT (J.Taler/P.Wais) BZF (G.B.Lenkey) WUT-IPEFM (H.Kruczek) WP Leader CzUT (W.Nowak/R.Rajczyk) SUT-IPET (M.Pronobis/S.Kalisz) CUT (J.Taler/P.Wais) BZF (G.B.Lenkey)
Objectives WP3 is focused on - 1D and 3D calculation models for biomass combustion in utility PC and CFB units - additives in CFB and PC combustion technologies - monitoring of fouling and corrosion under multi-fuel combustion conditions   Objectives WP3 is focused on - 1D and 3D calculation models for biomass combustion in utility PC and CFB units - additives in CFB and PC combustion technologies - monitoring of fouling and corrosion under multi-fuel combustion conditions   Objectives WP3 is focused on - 1D and 3D calculation models for biomass combustion in utility PC and CFB units - additives in CFB and PC combustion technologies - monitoring of fouling and corrosion under multi-fuel combustion conditions   Objectives WP3 is focused on - 1D and 3D calculation models for biomass combustion in utility PC and CFB units - additives in CFB and PC combustion technologies - monitoring of fouling and corrosion under multi-fuel combustion conditions  
Work plan and distribution of tasks (including timing of tasks) see time schedule   Task 3.1 Development of comprehensive 0D, 1D and 3D calculation models for biomass combustion and modelling of utility PC and CFB units (CzUT task leader, SUT-IPET, WUT-IPEFM, BZF) Task 3.2 Analysis of synergy effects of co-processing of agro biomass and bio-wastes with coal for heat and power generation (WUT-IPEFM) Task 3.3 Development of co-utilization and combustion systems in CFB and PC technologies with additives to avoid fouling, slagging and corrosion problems (SUT-IPET task leader, CzUT) Task 3.4 Development and design of monitoring system for fouling and corrosion under multi-fuel combustion conditions (CUT, WUT-IPEFM, BZF) Work plan and distribution of tasks (including timing of tasks) see time schedule   Task 3.1 Development of comprehensive 0D, 1D and 3D calculation models for biomass combustion and modelling of utility PC and CFB units (CzUT task leader, SUT-IPET, WUT-IPEFM, BZF) Task 3.2 Analysis of synergy effects of co-processing of agro biomass and bio-wastes with coal for heat and power generation (WUT-IPEFM) Task 3.3 Development of co-utilization and combustion systems in CFB and PC technologies with additives to avoid fouling, slagging and corrosion problems (SUT-IPET task leader, CzUT) Task 3.4 Development and design of monitoring system for fouling and corrosion under multi-fuel combustion conditions (CUT, WUT-IPEFM, BZF) Work plan and distribution of tasks (including timing of tasks) see time schedule   Task 3.1 Development of comprehensive 0D, 1D and 3D calculation models for biomass combustion and modelling of utility PC and CFB units (CzUT task leader, SUT-IPET, WUT-IPEFM, BZF) Task 3.2 Analysis of synergy effects of co-processing of agro biomass and bio-wastes with coal for heat and power generation (WUT-IPEFM) Task 3.3 Development of co-utilization and combustion systems in CFB and PC technologies with additives to avoid fouling, slagging and corrosion problems (SUT-IPET task leader, CzUT) Task 3.4 Development and design of monitoring system for fouling and corrosion under multi-fuel combustion conditions (CUT, WUT-IPEFM, BZF) Work plan and distribution of tasks (including timing of tasks) see time schedule   Task 3.1 Development of comprehensive 0D, 1D and 3D calculation models for biomass combustion and modelling of utility PC and CFB units (CzUT task leader, SUT-IPET, WUT-IPEFM, BZF) Task 3.2 Analysis of synergy effects of co-processing of agro biomass and bio-wastes with coal for heat and power generation (WUT-IPEFM) Task 3.3 Development of co-utilization and combustion systems in CFB and PC technologies with additives to avoid fouling, slagging and corrosion problems (SUT-IPET task leader, CzUT) Task 3.4 Development and design of monitoring system for fouling and corrosion under multi-fuel combustion conditions (CUT, WUT-IPEFM, BZF)
Links to KIC InnoEnergy Strategy   Exploitation Links to innovation system - WP3 will contribute to enhancement of multi-fuel power plant reliability - WP3 will deliver new monitoring and control systems for multi-fuel combustors Education Links to education programs WP3 will contribute to the Summer School foreseen in WP5. Findings from WP3 will be presented at the related EIT labeled courses.   Links to KIC InnoEnergy Strategy   Exploitation Links to innovation system - WP3 will contribute to enhancement of multi-fuel power plant reliability - WP3 will deliver new monitoring and control systems for multi-fuel combustors Education Links to education programs WP3 will contribute to the Summer School foreseen in WP5. Findings from WP3 will be presented at the related EIT labeled courses.   Links to KIC InnoEnergy Strategy   Exploitation Links to innovation system - WP3 will contribute to enhancement of multi-fuel power plant reliability - WP3 will deliver new monitoring and control systems for multi-fuel combustors Education Links to education programs WP3 will contribute to the Summer School foreseen in WP5. Findings from WP3 will be presented at the related EIT labeled courses.   Links to KIC InnoEnergy Strategy   Exploitation Links to innovation system - WP3 will contribute to enhancement of multi-fuel power plant reliability - WP3 will deliver new monitoring and control systems for multi-fuel combustors Education Links to education programs WP3 will contribute to the Summer School foreseen in WP5. Findings from WP3 will be presented at the related EIT labeled courses.  
Deliverables/Outcome KPI   3.1.1 Report of biomass combustion phenomena (Q1 2012) 3.1.2 Report of 0D and 1D model validations (Q4 2012) 3.1.3 Report of updated 3-D model (Q4 2013) 3.1.4 Report of 3-D model validations and industrial test runs. (Q4 2012) 3.1.5 Model of 3D biomass combustion in the CFB boiler (CzUT) (Q4 2012) 3.1.6 Model of 3D biomass combustion in the PC boiler (SUT) (Q4 2012) 3.2.1 Report on effects of co-processing of agro biomass and bio-wastes with coal WUT (Q1 2012) 3.3.1 Optimized additive product for commercial deployment (SUT) (Q4 2012) 3.4.2 Applying and testing of an sample probe to evaluate the deposit, slagging and corrosion behavior under multi-fuel combustion conditions (WUT) (Q4 2011) 3.4.3 Installation of computer-based system for monitoring in on-line mode of slagging and fouling (CUT, IST) (Q4 2011) 3.4.4 Tests that allows for optimization of sootblower sequencing based on actual cleaning requirements (CUT) (Q4 2011) 3.4.5 Risk based inspection methodology and system for on-line monitoring of combustion system (BZF) (Q4 2012)   Deliverables/Outcome KPI   3.1.1 Report of biomass combustion phenomena (Q1 2012) 3.1.2 Report of 0D and 1D model validations (Q4 2012) 3.1.3 Report of updated 3-D model (Q4 2013) 3.1.4 Report of 3-D model validations and industrial test runs. (Q4 2012) 3.1.5 Model of 3D biomass combustion in the CFB boiler (CzUT) (Q4 2012) 3.1.6 Model of 3D biomass combustion in the PC boiler (SUT) (Q4 2012) 3.2.1 Report on effects of co-processing of agro biomass and bio-wastes with coal WUT (Q1 2012) 3.3.1 Optimized additive product for commercial deployment (SUT) (Q4 2012) 3.4.2 Applying and testing of an sample probe to evaluate the deposit, slagging and corrosion behavior under multi-fuel combustion conditions (WUT) (Q4 2011) 3.4.3 Installation of computer-based system for monitoring in on-line mode of slagging and fouling (CUT, IST) (Q4 2011) 3.4.4 Tests that allows for optimization of sootblower sequencing based on actual cleaning requirements (CUT) (Q4 2011) 3.4.5 Risk based inspection methodology and system for on-line monitoring of combustion system (BZF) (Q4 2012)   Deliverables/Outcome KPI   3.1.1 Report of biomass combustion phenomena (Q1 2012) 3.1.2 Report of 0D and 1D model validations (Q4 2012) 3.1.3 Report of updated 3-D model (Q4 2013) 3.1.4 Report of 3-D model validations and industrial test runs. (Q4 2012) 3.1.5 Model of 3D biomass combustion in the CFB boiler (CzUT) (Q4 2012) 3.1.6 Model of 3D biomass combustion in the PC boiler (SUT) (Q4 2012) 3.2.1 Report on effects of co-processing of agro biomass and bio-wastes with coal WUT (Q1 2012) 3.3.1 Optimized additive product for commercial deployment (SUT) (Q4 2012) 3.4.2 Applying and testing of an sample probe to evaluate the deposit, slagging and corrosion behavior under multi-fuel combustion conditions (WUT) (Q4 2011) 3.4.3 Installation of computer-based system for monitoring in on-line mode of slagging and fouling (CUT, IST) (Q4 2011) 3.4.4 Tests that allows for optimization of sootblower sequencing based on actual cleaning requirements (CUT) (Q4 2011) 3.4.5 Risk based inspection methodology and system for on-line monitoring of combustion system (BZF) (Q4 2012)   Deliverables/Outcome KPI   3.1.1 Report of biomass combustion phenomena (Q1 2012) 3.1.2 Report of 0D and 1D model validations (Q4 2012) 3.1.3 Report of updated 3-D model (Q4 2013) 3.1.4 Report of 3-D model validations and industrial test runs. (Q4 2012) 3.1.5 Model of 3D biomass combustion in the CFB boiler (CzUT) (Q4 2012) 3.1.6 Model of 3D biomass combustion in the PC boiler (SUT) (Q4 2012) 3.2.1 Report on effects of co-processing of agro biomass and bio-wastes with coal WUT (Q1 2012) 3.3.1 Optimized additive product for commercial deployment (SUT) (Q4 2012) 3.4.2 Applying and testing of an sample probe to evaluate the deposit, slagging and corrosion behavior under multi-fuel combustion conditions (WUT) (Q4 2011) 3.4.3 Installation of computer-based system for monitoring in on-line mode of slagging and fouling (CUT, IST) (Q4 2011) 3.4.4 Tests that allows for optimization of sootblower sequencing based on actual cleaning requirements (CUT) (Q4 2011) 3.4.5 Risk based inspection methodology and system for on-line monitoring of combustion system (BZF) (Q4 2012)  
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SECoal project WPs
WORK PACKAGE DESCRIPTION WORK PACKAGE DESCRIPTION WP No 4
  Work package Title   Advanced concepts of integrated multi-fuel, low-emission power generation   Advanced concepts of integrated multi-fuel, low-emission power generation   Advanced concepts of integrated multi-fuel, low-emission power generation
  Institution(s)   Contact person (s)   SUT-IPET (M.Pronobis/S.Kalisz) WP Leader WUT-IPEFM (H.Kruczek) CUT (J.Taler/P.Wais) KTH-EFT (W.Yang) BZF (G.B.Lenkey) EDF (H.Kubiczek) SUT-IPET (M.Pronobis/S.Kalisz) WP Leader WUT-IPEFM (H.Kruczek) CUT (J.Taler/P.Wais) KTH-EFT (W.Yang) BZF (G.B.Lenkey) EDF (H.Kubiczek) SUT-IPET (M.Pronobis/S.Kalisz) WP Leader WUT-IPEFM (H.Kruczek) CUT (J.Taler/P.Wais) KTH-EFT (W.Yang) BZF (G.B.Lenkey) EDF (H.Kubiczek)
Objectives WP4 is focused on - novel, integrated co-utilization concepts - maximization of co-firing share - development of jet enhanced combustion system - mitigation of negative co-firing effects   Objectives WP4 is focused on - novel, integrated co-utilization concepts - maximization of co-firing share - development of jet enhanced combustion system - mitigation of negative co-firing effects   Objectives WP4 is focused on - novel, integrated co-utilization concepts - maximization of co-firing share - development of jet enhanced combustion system - mitigation of negative co-firing effects   Objectives WP4 is focused on - novel, integrated co-utilization concepts - maximization of co-firing share - development of jet enhanced combustion system - mitigation of negative co-firing effects  
Work plan and distribution of tasks (including timing of tasks) see time schedule   Task 4.1 Hybrid in-direct co-firing system with use of depleted oxidizer (SUT-IPET) Task 4.2 Mitigation of negative impacts of co-utilization with use of innovative fuel additives (slagging, fouling, alkali metals capture) (SUT-IPET, EDF, BZF)   Task 4.3 Hybrid in-direct co-firing system using biogas and biochars (WUT-IPEFM) Task 4.4 Multi bio-fuel fired CFB unit coupled with coal fired boiler (WUT-IPEFM, CzUT) Task 4.5 Development and design of jet enhanced combustion system (SUT-IPET) and novel boiler combustion system with pretreated biomass (KTH-EFT) Task 4.6 Development and implementation of installation for co-firing pulverized coal and biomass up to 20 total fuel energy (CUT)   Work plan and distribution of tasks (including timing of tasks) see time schedule   Task 4.1 Hybrid in-direct co-firing system with use of depleted oxidizer (SUT-IPET) Task 4.2 Mitigation of negative impacts of co-utilization with use of innovative fuel additives (slagging, fouling, alkali metals capture) (SUT-IPET, EDF, BZF)   Task 4.3 Hybrid in-direct co-firing system using biogas and biochars (WUT-IPEFM) Task 4.4 Multi bio-fuel fired CFB unit coupled with coal fired boiler (WUT-IPEFM, CzUT) Task 4.5 Development and design of jet enhanced combustion system (SUT-IPET) and novel boiler combustion system with pretreated biomass (KTH-EFT) Task 4.6 Development and implementation of installation for co-firing pulverized coal and biomass up to 20 total fuel energy (CUT)   Work plan and distribution of tasks (including timing of tasks) see time schedule   Task 4.1 Hybrid in-direct co-firing system with use of depleted oxidizer (SUT-IPET) Task 4.2 Mitigation of negative impacts of co-utilization with use of innovative fuel additives (slagging, fouling, alkali metals capture) (SUT-IPET, EDF, BZF)   Task 4.3 Hybrid in-direct co-firing system using biogas and biochars (WUT-IPEFM) Task 4.4 Multi bio-fuel fired CFB unit coupled with coal fired boiler (WUT-IPEFM, CzUT) Task 4.5 Development and design of jet enhanced combustion system (SUT-IPET) and novel boiler combustion system with pretreated biomass (KTH-EFT) Task 4.6 Development and implementation of installation for co-firing pulverized coal and biomass up to 20 total fuel energy (CUT)   Work plan and distribution of tasks (including timing of tasks) see time schedule   Task 4.1 Hybrid in-direct co-firing system with use of depleted oxidizer (SUT-IPET) Task 4.2 Mitigation of negative impacts of co-utilization with use of innovative fuel additives (slagging, fouling, alkali metals capture) (SUT-IPET, EDF, BZF)   Task 4.3 Hybrid in-direct co-firing system using biogas and biochars (WUT-IPEFM) Task 4.4 Multi bio-fuel fired CFB unit coupled with coal fired boiler (WUT-IPEFM, CzUT) Task 4.5 Development and design of jet enhanced combustion system (SUT-IPET) and novel boiler combustion system with pretreated biomass (KTH-EFT) Task 4.6 Development and implementation of installation for co-firing pulverized coal and biomass up to 20 total fuel energy (CUT)  
Links to KIC InnoEnergy Strategy   Exploitation Links to innovation system - WP4 will contribute to enhancement of multi-fuel capacity with significant reduction of negative side-effects - WP4 will deliver new combustion system for solid fuels Education Links to education programs WP4 will contribute to the Summer School foreseen in WP5. Findings from WP4 will be presented at the related EIT labeled courses.     Links to KIC InnoEnergy Strategy   Exploitation Links to innovation system - WP4 will contribute to enhancement of multi-fuel capacity with significant reduction of negative side-effects - WP4 will deliver new combustion system for solid fuels Education Links to education programs WP4 will contribute to the Summer School foreseen in WP5. Findings from WP4 will be presented at the related EIT labeled courses.     Links to KIC InnoEnergy Strategy   Exploitation Links to innovation system - WP4 will contribute to enhancement of multi-fuel capacity with significant reduction of negative side-effects - WP4 will deliver new combustion system for solid fuels Education Links to education programs WP4 will contribute to the Summer School foreseen in WP5. Findings from WP4 will be presented at the related EIT labeled courses.     Links to KIC InnoEnergy Strategy   Exploitation Links to innovation system - WP4 will contribute to enhancement of multi-fuel capacity with significant reduction of negative side-effects - WP4 will deliver new combustion system for solid fuels Education Links to education programs WP4 will contribute to the Summer School foreseen in WP5. Findings from WP4 will be presented at the related EIT labeled courses.    
Deliverables/Outcome KPI 4.1.1 Report from in-direct co-firing with depleted oxidizer (Q3 2013) SUT-IPET 4.2.1 Report on the Hungarian experiences of biomass co-firing, alkali related problems, potential solutions. (BZF) (Q2 2012) 4.2.2 Optimized fuel mix of lignite/coal and biomass/waste co-firing (SUT-IPET, WUT, BZF) (Q4 2012) 4.2.3 Database for biomass fuels (BZF) (Q1 2012) 4.2.4 Optimizing software for optimizing co-firing systems (BZF) (Q1 2012)  4.5.1 Report on an integrated CHP plant with biomass pretreatment aiming for CO2 reduction (Q4 2011) KTH-EFT 4.5.2 Report on a novel boiler combustion system with pretreated biomass (Q1 2013) KTH-EFT 4.6.1 Implementation of installation for co-firing pulverized coal and biomass up to 20 total fuel energy (CUT) (Q4 2012) Deliverables/Outcome KPI 4.1.1 Report from in-direct co-firing with depleted oxidizer (Q3 2013) SUT-IPET 4.2.1 Report on the Hungarian experiences of biomass co-firing, alkali related problems, potential solutions. (BZF) (Q2 2012) 4.2.2 Optimized fuel mix of lignite/coal and biomass/waste co-firing (SUT-IPET, WUT, BZF) (Q4 2012) 4.2.3 Database for biomass fuels (BZF) (Q1 2012) 4.2.4 Optimizing software for optimizing co-firing systems (BZF) (Q1 2012)  4.5.1 Report on an integrated CHP plant with biomass pretreatment aiming for CO2 reduction (Q4 2011) KTH-EFT 4.5.2 Report on a novel boiler combustion system with pretreated biomass (Q1 2013) KTH-EFT 4.6.1 Implementation of installation for co-firing pulverized coal and biomass up to 20 total fuel energy (CUT) (Q4 2012) Deliverables/Outcome KPI 4.1.1 Report from in-direct co-firing with depleted oxidizer (Q3 2013) SUT-IPET 4.2.1 Report on the Hungarian experiences of biomass co-firing, alkali related problems, potential solutions. (BZF) (Q2 2012) 4.2.2 Optimized fuel mix of lignite/coal and biomass/waste co-firing (SUT-IPET, WUT, BZF) (Q4 2012) 4.2.3 Database for biomass fuels (BZF) (Q1 2012) 4.2.4 Optimizing software for optimizing co-firing systems (BZF) (Q1 2012)  4.5.1 Report on an integrated CHP plant with biomass pretreatment aiming for CO2 reduction (Q4 2011) KTH-EFT 4.5.2 Report on a novel boiler combustion system with pretreated biomass (Q1 2013) KTH-EFT 4.6.1 Implementation of installation for co-firing pulverized coal and biomass up to 20 total fuel energy (CUT) (Q4 2012) Deliverables/Outcome KPI 4.1.1 Report from in-direct co-firing with depleted oxidizer (Q3 2013) SUT-IPET 4.2.1 Report on the Hungarian experiences of biomass co-firing, alkali related problems, potential solutions. (BZF) (Q2 2012) 4.2.2 Optimized fuel mix of lignite/coal and biomass/waste co-firing (SUT-IPET, WUT, BZF) (Q4 2012) 4.2.3 Database for biomass fuels (BZF) (Q1 2012) 4.2.4 Optimizing software for optimizing co-firing systems (BZF) (Q1 2012)  4.5.1 Report on an integrated CHP plant with biomass pretreatment aiming for CO2 reduction (Q4 2011) KTH-EFT 4.5.2 Report on a novel boiler combustion system with pretreated biomass (Q1 2013) KTH-EFT 4.6.1 Implementation of installation for co-firing pulverized coal and biomass up to 20 total fuel energy (CUT) (Q4 2012)
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SECoal project WPs
WORK PACKAGE DESCRIPTION WORK PACKAGE DESCRIPTION WP No 5
  Work package Title   Social impacts, public perception and educational programmes   Social impacts, public perception and educational programmes   Social impacts, public perception and educational programmes
  Institution(s)   Contact person (s)   BZF(G.B.Lenkey) WP Leader   ALL BZF(G.B.Lenkey) WP Leader   ALL BZF(G.B.Lenkey) WP Leader   ALL
Objectives WP5 is focused on - dissemination of SECoal results - public acceptance to co-utilization practices - increase of professional knowledge in the field of co-utilization - LCA analyses on environmental loads     Objectives WP5 is focused on - dissemination of SECoal results - public acceptance to co-utilization practices - increase of professional knowledge in the field of co-utilization - LCA analyses on environmental loads     Objectives WP5 is focused on - dissemination of SECoal results - public acceptance to co-utilization practices - increase of professional knowledge in the field of co-utilization - LCA analyses on environmental loads     Objectives WP5 is focused on - dissemination of SECoal results - public acceptance to co-utilization practices - increase of professional knowledge in the field of co-utilization - LCA analyses on environmental loads    
Work plan and distribution of tasks (including timing of tasks) see time schedule   5.1 Comparative LCA (Life Cycle Assessment) analyses of multi-fuel co-utilization technologies (BZF) Input- output data collection for different technologies, Set up the model for different technologies Evaluation of the results of the LCA   5.2 Optimizing the multi-fuel co-utilization and clean coal technologies from environmental loading point of view (BZF) Data mining from the LCA analysis, Determining of criterion system for optimizing Set up the model for optimizing Optimization with applying simulation software Evaluation of the optimization Evaluation of the results of the LCA   Task. 5.3 Summer school for biomass utilization technology   Work plan and distribution of tasks (including timing of tasks) see time schedule   5.1 Comparative LCA (Life Cycle Assessment) analyses of multi-fuel co-utilization technologies (BZF) Input- output data collection for different technologies, Set up the model for different technologies Evaluation of the results of the LCA   5.2 Optimizing the multi-fuel co-utilization and clean coal technologies from environmental loading point of view (BZF) Data mining from the LCA analysis, Determining of criterion system for optimizing Set up the model for optimizing Optimization with applying simulation software Evaluation of the optimization Evaluation of the results of the LCA   Task. 5.3 Summer school for biomass utilization technology   Work plan and distribution of tasks (including timing of tasks) see time schedule   5.1 Comparative LCA (Life Cycle Assessment) analyses of multi-fuel co-utilization technologies (BZF) Input- output data collection for different technologies, Set up the model for different technologies Evaluation of the results of the LCA   5.2 Optimizing the multi-fuel co-utilization and clean coal technologies from environmental loading point of view (BZF) Data mining from the LCA analysis, Determining of criterion system for optimizing Set up the model for optimizing Optimization with applying simulation software Evaluation of the optimization Evaluation of the results of the LCA   Task. 5.3 Summer school for biomass utilization technology   Work plan and distribution of tasks (including timing of tasks) see time schedule   5.1 Comparative LCA (Life Cycle Assessment) analyses of multi-fuel co-utilization technologies (BZF) Input- output data collection for different technologies, Set up the model for different technologies Evaluation of the results of the LCA   5.2 Optimizing the multi-fuel co-utilization and clean coal technologies from environmental loading point of view (BZF) Data mining from the LCA analysis, Determining of criterion system for optimizing Set up the model for optimizing Optimization with applying simulation software Evaluation of the optimization Evaluation of the results of the LCA   Task. 5.3 Summer school for biomass utilization technology  
Links to KIC InnoEnergy Strategy   Exploitation Links to innovation system - WP5 will contribute to public understanding of innovative co-utilization concepts   Education Links to education programs WP5 will prepare the Summer School and will interact with related EIT labeled courses.   Links to KIC InnoEnergy Strategy   Exploitation Links to innovation system - WP5 will contribute to public understanding of innovative co-utilization concepts   Education Links to education programs WP5 will prepare the Summer School and will interact with related EIT labeled courses.   Links to KIC InnoEnergy Strategy   Exploitation Links to innovation system - WP5 will contribute to public understanding of innovative co-utilization concepts   Education Links to education programs WP5 will prepare the Summer School and will interact with related EIT labeled courses.   Links to KIC InnoEnergy Strategy   Exploitation Links to innovation system - WP5 will contribute to public understanding of innovative co-utilization concepts   Education Links to education programs WP5 will prepare the Summer School and will interact with related EIT labeled courses.  
Deliverables/Outcome KPI   5.1.1 LCA case study for each technology, input-output database, GaBi 4.3 LCA Software (Q1 2012) 5.2.1 Case study for optimisation, using Simul8 Software (Q1 2013) 5.3.1 Summer school (Q3 2013) Deliverables/Outcome KPI   5.1.1 LCA case study for each technology, input-output database, GaBi 4.3 LCA Software (Q1 2012) 5.2.1 Case study for optimisation, using Simul8 Software (Q1 2013) 5.3.1 Summer school (Q3 2013) Deliverables/Outcome KPI   5.1.1 LCA case study for each technology, input-output database, GaBi 4.3 LCA Software (Q1 2012) 5.2.1 Case study for optimisation, using Simul8 Software (Q1 2013) 5.3.1 Summer school (Q3 2013) Deliverables/Outcome KPI   5.1.1 LCA case study for each technology, input-output database, GaBi 4.3 LCA Software (Q1 2012) 5.2.1 Case study for optimisation, using Simul8 Software (Q1 2013) 5.3.1 Summer school (Q3 2013)
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SECoal project plan
2011 2011 2011 2011 2012 2012 2012 2012 2013 2013 2013 2013
Task/Milestones Q1 Q2 Q3 Q4 Q1 Q2 Q3 Q4 Q1 Q2 Q3 Q4
T0.1                        
T0.2                        
M0.2.1       X                
T0.3                        
M0.3.1       X                
T0.4                        
T1.1
M1.1.1 X
M1.1.2 X
T1.2
M1.2.1 X
T1.3
T1.4
M1.4.1 X
T1.5
M1.5.1 X
M1.5.2 X
T2.1
T2.2
M2.2.1 X
M2.2.2 X
M2.2.3 X
T2.3                        
M2.3.1       X                 
M2.3.2        X                
M2.3.3 X
M2.3.4 X
T3.1
M3.1.1 X
M3.1.2 X
M3.1.3 X
M3.1.4 X
M3.1.5 X
T3.2
T3.3
M3.3.1 X
T3.4
T4.1
M4.1.1 X
T4.2
M4.2.1 X
M4.2.2 X
M4.2.3 X
M4.2.4 X
M4.2.5 X
T4.3
T4.4
T4.5
M4.5.1 X
T4.6
T5.1
M5.1.1 X
M5.1.2 X
T5.2
T5.3
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SECoal project products Reverse flow
non-catalytic combustion of coal mine
Ventilation Air Methane
Effects were calculated per average coal mine
shaft in Poland (flowrate 720 000 Nm3/h)
Ecological effect (Methane combusted)
Demonstration plant in ICE-PAS
for 0.2vol.CH4 8581 tCH4/ year for
0.5vol.CH4 21452 tCH4/ year
Methane has Global Warming Potential at least
25 times higher than CO2!!!
Heat recovery effect for 1.0 vol.CH4
37 MWt for 0.4 vol.CH4 4.3 MWt
With the SECoal Project Ms Anna Pawlaczyks PhD
thesis will be connected
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SECoal project products CFB simulator
CFB simulator will be a powerful software that
will help to design, operate and optimize
performance of large and medium scale circulating
fluidized bed boilers Picture not existing
yet Market value CFB simulator will be able to
help with design and with operational problems
thus cutting costs by some percent. Industrial
CFB boilers owners already expressed their will
to use such a product. At least 1 PhD thesis and
2-3 MSc or BSc thesis Introduction late 2013
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SECoal project products Catalyst for methane
oxidation (lean sources - VAM)

• Working temperature 250 350 C
• Main challenges
• ? finding the formula of an efficient and
  economically reasonable catalytic system
• ? determination of minimal content of CH4
  allowing its autothermic combustion
• ? evaluation of the versatile method of methane
  enrichment
• Educational achievements
• Ph.D. Thesis 3
• M.Sci. 10
• B.Sci. 11

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15
SECoal project products Monitoring system for
corrosion hazard in pulverized coal boilers
Visualization of the measurements of oxygen
concentration and on-line layout of corrosion
hazard of pulverized boiler obtained with the use
of neural networks
Market
All power stations equipped with PC boilers 80
units x 200 000 zl in Poland.
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16
SECoal project products Burners for liquid
biofuel
Burner for bio-liquid fuel output 1.5
t/hr applicable for start up and co-firing
biofuel in PC boiler
Multistream Burner for bio-liquid fuel output
300-700 kg/hr applicable for co-firing biofuel in
PC boiler ( additional effect- reduction NOX
emission by reburning mechanism in high
temperature)

• Market PC and stoker boilers installed in PP and
  CHP
• 40 PC units x 1 000 000 PLN

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SECoal project products Micronisation of
agro-biomass
New installation for biomass fuel producers to
apply in PP and CHP plant using co-firing of
biomass Cost of industrial installation at output
3 t/hr- 5 mln PLN - market is under analysis
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18
SECoal project products Expert services in
co-firing technologies (LCA, fuel database and
on-line monitoring)

• Risk based inspection methodology and system for
  on-line monitoring of combustion system
• Special equipment and system will be developed
  for monitoring the damage of critical locations
  of high temperature components in the combustion
  system (software and hardware)
• Reduction of maintenance cost
• Reduction of production loss due to not planned
  shutdowns
• MSc and PhD theses involved 1 MSc
• Estimate of time to market 3 years
• Software for optimising co-firing systems and
  database for biomass fuels
• Development of a Biomass Database
• Development of optimizing methods/software for
  co-firing of agro-biomass and bio-waste with coal
  
• Increase of efficiency of co-firing system
• Reduction of costs of maintenance
• Increased production
• Estimate of MSc and PhD theses involved 1 PhD
• Estimate of time to market 2 years
• LCA (Life Cycle Assessment) analyses of
  multi-fuel co-utilization technologies
• Development of LCA models for different
  technologies
• Optimisation method of multi-fuel technologies
  from environmental poitn of view

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SECoal project products spin-off in co-firing
technology services

• Fields of activity
• technologies for emission reduction from power
  generation and industrial processes
• technologies increasing the renewable energy
  share in overall energy supply
• services in energy management with special focus
  on the use of waste energy sources.
• The offer will consist of technical advice,
  consulting services, R D work, sales of
  licenses and upgrades of existing installations.

• Status
• Market analysis initiated supply and demand
  identified
• Business model in verification
• Commercialization strategy conditioned by new
  Regulation in exploitation of IP rights at the
  Silesian University of Technology
• Spin-off business plan in progress

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SECoal project budget
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SECoal project budget distribution
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SECoal project Summary

Criterion
1 Partners Involvement of Education, Research and Industry. Industry involvement in terms of participation in market assessment, prototyping and exploitation is paramount.
2 Partners InnoEnergy partners (formal KIC level partners or/and Associate partners) from at least 2 cc
3 Expected or foreseen economical market impact of the project outcomes. Economic impact being quantitative and/or qualitative (i.e. by increasing efficiency, reduction of green house emissions, or increase security)
4 Clear identification of what is new vs state of the art (i.e. in technology, business models, )
5 Duration 1 to 3 years.
6 Results within 18 months. Easy to assess/with clear contribution to KPI At least one new product / service or At least one new patent or At least on spin-off / patent transferred to SME And At least one scientific publication
7 A deliverable should be a demonstrator, prototype or equivalent, in the premises of the industry within the project team
8 Aligned with KIC strategy (e.g. SET plan, sustainability etc.)
9 Impact on Society and Public Acceptance considered

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SECoal project Recent developments and Open
issues

• Migration of GIG from SECoal to ACoPP
• Partnership cancellation IST and KTH Energy
  Dept.
• PA prepared and circulated within partners for
  signing
• Most of partners report they are just about to
  sign
• IP most difficult
• Formal industrial partner EDF (co-manager
  H.Kubiczek)
• Budget availability (?)

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