The SECTOR project: Status quo and outlook of co-firing torrefied material

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The SECTOR project: Status quo and outlook of co-firing torrefied material Michiel Carbo (Energy research Centre of the Netherlands, ECN) Kay Schaubach (Deutsche Biomasseforschungszentrum, DBFZ) Köln, Germany 8 th International Freiberg Conference on IGCC & XtL Technologies 1

The SECTOR project Collaborative project: SECTOR Project start: 01.01.2012 Duration: 42 months Total budget: 10 Mio. Euro Participants: 21 from 9 EU-countries Coordinator: DBFZ 2

SECTOR objectives Support the market introduction of torrefaction-based bioenergy carriers as a commodity renewable solid fuel Further development of torrefaction-based technologies (up to pilot-plant scale and beyond) Development of specific production recipes, validated through extensive labto-industrial-scale logistics and end-use performance testing Development and standardisation of dedicated analysis and testing methods for assessment of transport, storage, handling logistics and end-use performance Assessment of the role of torrefaction-based solid bioenergy carriers in the bioenergy value chains and their contribution to the development of the bioenergy market in Europe Full sustainability assessment of the major torrefaction-based biomass-to-enduse value chains Dissemination of project results to industry and into international forums (e.g. EIBI, EERA, CEN/ISO, IEA and sustainability round tables) 3

SECTOR project structure 4

Torrefied biomass properties in perspective Wood chips Wood pellets Torrefied wood pellets Charcoal Coal Moisture content (wt%) 30 55 7 10 1 5 1 5 10 15 Calorific value (LHV, MJ/kg) 7 12 15 17 18 22 30 32 23 28 Volatile matter (wt% db) 75 84 75 84 55 80 10 12 15 30 Fixed carbon (wt% db) 16 25 16 25 22 35 85 87 50 55 Bulk density (kg/l) 0.20 0.30 0.55 0.65 0.65 0.80 0.18 0.24 0.80 0.85 Vol. energy density (GJ/m 3 ) 1.4 3.6 8 11 12 19 5.4 7.7 18 24 Hygroscopic properties Hydrophilic Hydrophilic (Moderately) Hydrophobic Hydrophobic Hydrophobic Biological degradation Fast Moderate Slow None None Milling requirements Special Special Standard Standard Standard Product consistency Limited High High High High Transport cost High Medium Low Medium Low Abbreviations: db = dry basis LVH =Lower Heating Value sources: ECN (table, fig.1, 3), Pixelio (fig. 2, 5), OFI (fig. 4) 5

Torrefaction: state-of-the-art Torrefaction technology in demonstration phase with >10 demo-units and first commercial units in operation (total capacity > 0.5 Mton/a) Successful co-firing trials aid to build-up end-user confidence and allow product quality optimisation, e.g.: Buggenum IGCC (NUON, 2012) 1200 ton pellets Co-milling Up to 70% co-firing (energy basis) Amer 9 (Essent, end of 2013) 2300 tonne Topell pellets 5-25 wt% co-milling 1-4 wt% co-firing Studstrup 3 (DONG, March 2014) 200 tonne Andritz pellets Dedicated mill 33 wt% co-firing Helsingin Energia Hanasaaren (March 2014, November 2015) 140 tonne Torr-Coal pellets/79 tonne Topell pellets 14 wt% co-firing Image from Andritz 6

Torrefaction: Technologies Different technologies Moving bed (ECN) pilot Rotary drum / Auger (Umeå University) pilot Rotary drum (CENER) pilot Toroidal (Topell Energy) demo Production with available pilot scale facilities Typical test runs 50-100 hours Typical production per test few tonnes 3-6 different feedstocks Production with available demo plant Continuous operation Production of 100-200 tonnes Specific feedstock 7

Densification: Pilot-scale tests (CENER) Date Durability Pine Date Durability Straw October 2012 January 2013 88.8 92.3 Optimised parameters: Particle size of feedstock Moisture content of feedstock February Torrefaction 84.2 degree of feedstock 2013 Die diameter/length ratio Die rotation speed September 2013 94.3 June 2013 94.7 October 2013 96.6 November 2013 95.7 November 2013 97.6 Image from Andritz 8

Densification: Pilot-scale densification (DTI) Briquetting tests: Materials tested Spruce 240 C 260 C 280 C Bamboo 245 C 255 C 265 C Material torrefied at ECN: Spruce and Bamboo Briquetting tests DTI in cooperation with CF Nielsen 300 kg of each material Briquetting gets more challenging with increasing torrefaction degree Keeping the briquette hot and under pressure for extended time improves quality Good quality: Smooth surface, high density, stability but still optimization potential 9

Demonstration tests (Topell Energy) Proof of concept of Topell torrefaction system in 2013 at commercial scale for forest residues Demonstrated continuous production of torrefied pellets with the product quality required by end users (biomass co-firing biomass) Achieved and demonstrated full heat integration within the plant use of torgas to supply most of the heat demand of the plant, including drying and torrefaction Production for successful co-firing trial (2300 tonnes, 5-25 wt% comilling and co-firing in RWE/Essent Amer 9 power station) (conducted outside SECTOR) 10

Logistics: Small-scale tests (ECN) Biological degradation pellets (exposure 20ºC and RH 95%) 1.4% 1.2% 1.0% Mass Loss 0.8% 0.6% 13 days 20 days 0.4% 0.2% ECN 0.0% POPD-0B Torrefied Torrefied SPPD-0B Torrefied PIPD-0B Torrefied POPD-6B Torrefied SPPD-6B Torrefied PIPD-6B White Wood POPD-0B Torrefied + Poplar Spruce Pine Poplar Spruce Pine Poplar/ Coal Exposed Exposed Exposed Coal (50/50 w) Coal Image from Andritz 11

Logistics: Small-scale tests (ECN) Explosivity characteristics before/after torrefaction (pulverised torrefied pellets vs. pulverised raw material) ECN 12

Logistics: Outdoor storage tests (EON) Two outdoor storage piles built in June 2013 Peaked-topped pile Model the formation of piles after it has been delivered 4 tonnes 2.34 x 2.36 x 1.5 m 3 Flat-topped pile Model the formation of piles after compaction (though no compaction occurred) 3 tonnes 2.34 x 2.36 x 1.5 m 3 EON EON 13

Logistics: Outdoor storage tests (Topell) Pellet durability as function of height in pile Topell Image Andritz 14

Logistics: Outdoor storage tests (Topell) Moisture content as function of height in pile Topell Image Andritz 15

End use: Milling and feeding (ECN) Importance of particle morphology Glass beads Coal Raw Spruce Torrefied spruce chips Torrefied spruce pellets 16

End use: Co-firing in PF boilers (USTUTT) Emission measurements during (co-)firing of torrefied pellets CFD predictions of CO, O 2, CO 2 and NO X and temperature distribution (by PROCEDE) at furnace outlet match with experiments 11 types of torrefied biomass pellets were tested, with thermal firing share up to 100% USTUTT s KSVA, 500 kw, 8 m length 17

End use: (Co-)gasification in EF gasifiers (Vattenfall) NUON/Vattenfall Buggenum IGCC Plant: 253 MW e power plant, entered service in 1993 as a coal gasification demonstration plant, closed in 2013 Hard coal as main fuel with continuous cogasification of saw dust up to 15 wt% Trial (outside SECTOR, but results brought in): 1200 tonnes of torrefied biomass pellets cogasified with hard coal during 24 hours trial 70% torrefied biomass pellets on energy basis Main observations during tests in 2012: No large technical challenges during conveying, sluicing and milling of torrefied biomass pellets/coal blend Estimated to be possible to achieve at least 90% of the plant nominal capacity without major modifications in the fuel feeding system Higher heating value in the pellets connected to better milling properties but less advantageous dust formation behaviour 18

End use: Commercial pellet boilers (TFZ, BIOS, BE2020) Torrefied pellets can be used in commercial small-scale wood pellet boilers and may provide the same or even higher combustion efficiency as obtained with wood pellets: Slightly higher fixed carbon content in torrefied pellets vs. need for burnout time (adaptations of grate and burnout zone possibly required) Air ratio and air-staging may require some adaptations Pollutant emissions (CO, VOC, NOx and PM) depend on wood resources used, similar as for wood pellets Ash and slag related problems may occur earlier due to higher ash content or different ash composition Fuels need to be certified by boiler manufacturers, therefore field tests over a full heating period are needed to obtain approval 19

Fuel Specification and Standardisation (OFI, VTT) Round Robin test concluded: Validation of standard test methods for torrefied pellets: 43 participants, 18 countries, 11 parameters Ash, moisture content, chlorine and sulfur content, CHN analysis comparable to solid biofuels performance in BIONORM II Round Robin test Net calorific value reproducibility limit is higher than for solid biofuels Ash melting behaviour reproducibility of deformation temperature is high; subjective method Proposal for product standard for torrefied materials (thermally treated biomass): ISO 17225-1 publication date: April 2014 ISO 17225-8 work item will become a Technical Specification 20

Environmental analysis: GHG emissions end use GHG-emissions from electricity production Source: DBFZ GHG-mitigation potential of 72% - 86% Source: own Sector calculations & Ecoinvent 21

Environmental analysis: GHG emissions end use GHG-emissions from electricity production Source: DBFZ GHG-mitigation potential of 72% - 86% Source: own Sector calculations & Ecoinvent 22

Environmental analysis: Value chains Source: DBFZ 23

Conclusions Torrefaction technology is ready for commercial market introduction and the basic drivers for torrefaction still hold Several factors slowed down this introduction, including: European utility sector is facing difficult times It takes time and effort to build end-user confidence Instead of yielding immediately the ideal feedstock, torrefied biomass pellets development had to follow a learning curve, just as white wood pellets Many constructive and successful efforts have been made within this project to remove the barriers for market introduction Mature black pellet technology developers are actively pursuing tangible projects; gradually more commercial-scale black pellet plants will come online Near-future torrefaction R&D should focus on: Product quality characterisation, optimisation and standardisation (addressing torrefaction and densification) Broadening feedstock base (including lower-quality biomass: agroresidues, SRF, etc.) Separation/recycling of inorganic components 24

Karl-Heinz Liebisch/PIXELIO Thank you very much for your attention Coordination: Daniela Thrän Speaker: Michiel Carbo ECN Westerduinweg 3 1755 LE Petten The Netherlands carbo@ecn.nl SECTOR contact: Kay Schaubach t: +49 (0) 341 2434 468 e: info@sector-project.eu w: www.sector-project.eu 25

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