Ingemar Olofsson scite author profile

PostprintThis is the accepted version of a paper published in Fuel processing technology. This paper has been peer-reviewed but does not include the final publisher proof-corrections or journal pagination.Citation for the original published paper (version of record):Weiland, F., Nordwaeger, M., Olofsson, I., Wiinikka, H., Nordin, A. (2014) Entrained flow gasification of torrefied wood residues. In this work, four different fuels were gasified in a pressurized entrained flow pilot plant 12 gasifier at approximately 270 kW th . The different fuels were; two torrefied wood 13 residues, one raw wood residue and one torrefied stem wood. The system pressure and 14 oxygen equivalence ratio (!) were held constant for all four gasification experiments. It 15 was found that the torrefaction pretreatment significantly reduced the milling energy 16 consumption for fuel size reduction, which in turn contributed to increased gasification 17 plant efficiency. Furthermore, the results indicate that the carbon conversion efficiency • The torrefaction pretreatment reduced the milling energy consumption. 2• Torrefaction pretreatment contributed to increased gasification plant efficiency. 3• The fuel carbon conversion efficiency was affected by torrefaction pretreatment. 4• The CH 4 yield from gasification was reduced for severely torrefied fuel. 5

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Effects of moisture content, torrefaction temperature, and die temperature in pilot scale pelletizing of torrefied Norway spruce

Larsson

Rudolfsson

Nordwaeger

et al. 2013

Applied Energy

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Analysing biomass torrefaction supply chain costs

Svanberg

Olofsson

Flodén

et al. 2013

Bioresource Technology

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PostprintThis is the accepted version of a paper published in Bioresource Technology. This paper has been peerreviewed but does not include the final publisher proof-corrections or journal pagination.Citation for the original published paper (version of record):Svanberg, M., Olofsson, I., Floden, J., Nordin, A. (2013) Analysing biomass torrefaction supply chain costs. Abstract: The objective of the present work was to develop a techno-economic system model to evaluate how logistics and production parameters affect the torrefaction supply chain costs under Swedish conditions. The model consists of four sub-models: (1) supply system, (2) a complete energy and mass balance of drying, torrefaction and densification, (3) investment and operating costs of a green field, stand-alone torrefaction pellet plant, and (4) distribution system to the gate of an end user. The results show that the torrefaction supply chain reaps significant economies of scale up to a plant size of about 150-200 kiloton dry substance per year (ktonDS/year), for which the total supply chain costs accounts to 31.8 euro per megawatt hour based on lower heating value (€/MWhLHV). Important parameters affecting total cost are amount of available biomass, biomass premium, logistics equipment, biomass moisture content, drying 2 technology, torrefaction mass yield and torrefaction plant capital expenditures (CAPEX).

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Mechanisms Behind the Positive Effects on Bed Agglomeration and Deposit Formation Combusting Forest Residue with Peat Additives in Fluidized Beds

et al. 2009

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A compilation was made of the composition of peat from different areas in Sweden, of which a selected set was characterized and co-combusted with forest residue in controlled fluidized-bed agglomeration tests with extensive particle sampling. The variation in ash-forming elements in the different peat samples was large; thus, eight peat samples were selected from the compilation to represent the variation in peat composition in Sweden. These samples were characterized in terms of botanical composition, analyzed for ash-forming elements, and oxidized using a low-temperature ashing procedure, followed by characterization using scanning electron microscopy/electron-dispersive spectroscopy (SEM/EDS) and X-ray diffraction (XRD). The selected peat samples had in common the presence of a small fraction of crystalline phases, such as quartz, microcline, albite, and calcium sulfate. The controlled fluidized-bed agglomeration tests that co-combusted forest residue with peat resulted in a significant increase in agglomeration temperatures compared to combusting forest residue alone. Plausible explanations for this were an increase of calcium, iron, or aluminum in the bed particle layers and/or the reaction of potassium with clay minerals, which prevented the formation of low-melting bed particle layers. The effects on particle and deposit formation during co-combustion were reduced amounts of fine particles and an increased number of coarse particles. The mechanisms for the positive effects were a transfer and/or removal of potassium in the gas phase to a less reactive particular form via sorption and/or a reaction with the reactive peat ash (SiO 2 and CaO), which in most cases formed larger particles (>1 μm) containing calcium silicon and potassium.

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Biomass conversion through torrefaction

Nordin¹,

Pommer²,

Olofsson³

et al. 2013

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Quality Assurance of Torrefied Biomass Using RGB, Visual and near Infrared (Hyper) Spectral Image Data

Lindstrom

Nilsson

Nordin

et al. 2014

Journal of Near Infrared Spectroscopy

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Visible and near infrared imaging techniques for analysing characteristics of torrefied biomass were evaluated for possible use in future online process control. The goal of such a control system is to identify products with the desired properties and reject products outside the specification. Two pushbroom hyperspectral cameras with different wavelength regions and a commercial digital colour camera were evaluated. The hyperspectral cameras, short wave infrared (SWIR) and visible-near infrared (VNIR), covered the ranges of 1000-2500 nm and 400-1000 nm, respectively. The biomass was produced according to an experimental design in a torre faction pilot plant at different temperatures, residence times, and nitrogen and steam flow rates to obtain a wide range of different characteristics and qualities of torrefied material. Chemical characteristics, heating values and milling energy of the different torrefied materials were analysed or calculated using standardized procedures and were used for calibration. For the hyperspectral images, a principal-component analysis was performed on the absorbance spectra. The score plots and score images were used interactively to separate background, outlier pixels and shading effects from sample signal. Averaged spectra of individual torrefied woodchips were used. Partial leastsquares regression was used to relate average spectra to heating values and chemical characteristics of the torrefied biomass. Owing to the small size of the data sets, cross-validation using leave-one-out validation was used for testing the models. The ratio of standard error of prediction to sample standard deviation (RPD) values were used for comparing the imaging techniques. For RGB images, all RPD values were 4 or lower. The RPD values for the VNIR technique were all below 5, while the SWIR images produced RPD values above 5 for eight of the 13 properties. The promising results of the SWIR technique strongly suggested that the torrefied biomass undergoes changes to chemical structures, which are not necessarily manifested as changes to the colour of the material.

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Parametric Study of Pilot-Scale Biomass Torrefaction

Nordwaeger¹,

Håkansson²,

Li³

et al. 2010

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