Matthew J. Darr scite author profile

The primary feedstock choice for most fi rst-generation commercial cellulosic biorefi neries in the Midwest is corn stover. Their rated capacities are between 76 and 114 million liters per year (MLPY). For uninterrupted operation of these plants, a year-round supply of corn stover needs to be secured, requiring a robust, effi cient, and cost-effective feedstock supply system. Thus, the main objective of this work is to stochastically analyze the techno-economics of corn stover supply system for a 114 MLPY cellulosic biorefi nery in the Midwest using production-scale experimental fi eld data collected in Iowa. This study analyzes the resources requirements (equipment, labor, fuel, and consumables) and costs of different components of the supply chain that include harvesting (windrowing and baling), in-fi eld bale collection and stacking at the fi eld-edge, handling and transportation of bales from the fi eld-edge to the distributed storage facilities and then to the biorefi nery plant, storage, and fi nally the audit of nutrients removed during stover collection from the fi eld. Additionally, this study identifi es and ranks different supply chain parameters based on their relative infl uence on the overall resources and costs requirements. A 114 MLPY cellulosic biorefi nery annually requires around 0.95 million corn stover bales supply, 250 000 hours equivalent of labor and 4.3 million L of diesel fuel. The average cost of biorefi nery gate delivered corn stover is estimated to be 121.9 $-std. t −1 . This cost is identifi ed to be the most sensitive to bale density followed by harvest rate, bale length, baler fi eld effi ciency, and annual harvest days.

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Biomass storage: an update on industrial solutions for baled biomass feedstocks

Darr

Shah

2012

Biofuels

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Effect of Torrefaction on Water Vapor Adsorption Properties and Resistance to Microbial Degradation of Corn Stover

et al. 2012

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The equilibrium moisture content (EMC) of biomass affects transportation, storage, downstream feedstock processing, and the overall economy of biorenewables production. Torrefaction is a thermochemical process conducted in the temperature regime between 200 and 300 °C under an inert atmosphere that, among other benefits, aims to reduce the innate hydrophilicity and susceptibility to microbial degradation of biomass. The objective of this study was to examine water sorption properties of torrefied corn stover. The EMC of raw corn stover, along with corn stover thermally pretreated at three temperatures, was measured using the static gravimetric method at equilibrium relative humidity (ERH) and temperatures ranging from 10 to 98% and from 10 to 40 °C, respectively. Five isotherms were fitted to the experimental data to obtain the prediction equation that best describes the relationship between the ERH and the EMC of lignocellulosic biomass. Microbial degradation of the samples was tested at 97% ERH and 30 °C. Fiber analyses were conducted on all samples. In general, torrefied biomass showed an EMC lower than that of raw biomass, which implied an increase in hydrophobicity. The modified Oswin model performed best in describing the correlation between ERH and EMC. Corn stover torrefied at 250 and 300 °C had negligible dry matter mass loss due to microbial degradation. Fiber analysis showed a significant decrease in hemicellulose content with the increase in pretreatment temperature, which might be the reason for the hydrophobic nature of the torrefied biomass. The outcomes of this work can be used for torrefaction process optimization, and decision-making regarding raw and torrefied biomass storage and downstream processing. ABSTRACT:The equilibrium moisture content (EMC) of biomass affects transportation, storage, downstream feedstock processing, and the overall economy of biorenewables production. Torrefaction is a thermochemical process conducted in the temperature regime between 200 and 300°C under an inert atmosphere that, among other benefits, aims to reduce the innate hydrophilicity and susceptibility to microbial degradation of biomass. The objective of this study was to examine water sorption properties of torrefied corn stover. The EMC of raw corn stover, along with corn stover thermally pretreated at three temperatures, was measured using the static gravimetric method at equilibrium relative humidity (ERH) and temperatures ranging from 10 to 98% and from 10 to 40°C, respectively. Five isotherms were fitted to the experimental data to obtain the prediction equation that best describes the relationship between the ERH and the EMC of lignocellulosic biomass. Microbial degradation of the samples was tested at 97% ERH and 30°C. Fiber analyses were conducted on all samples. In general, torrefied biomass showed an EMC lower than that of raw biomass, which implied an increase in hydrophobicity. The modified Oswin model performed best in describing the correlation between ERH and EMC. Corn stover torrefi...

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The Effects of Particle Size, Different Corn Stover Components, and Gas Residence Time on Torrefaction of Corn Stover

et al. 2012

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Large scale biofuel production will be possible only if significant quantities of biomass feedstock can be stored, transported, and processed in an economic and sustainable manner. Torrefaction has the potential to significantly reduce the cost of transportation, storage, and downstream processing through the improvement of physical and chemical characteristics of biomass. The main objective of this study was to investigate the effects of particle size, plant components, and gas residence time on the production of torrefied corn (Zea mays) stover. Different particle sizes included 0.85 mm and 20 mm. Different stover components included ground corn stover, whole corn stalk, stalk shell and pith, and corn cob shell. Three different purge gas residence times were employed to assess the effects of interaction of volatiles and torrefied biomass. Elemental analyses were performed on all of the samples, and the data obtained was used to estimate the energy contents and energy yields of different torrefied biomass samples. Particle density, elemental composition, and fiber composition of raw biomass fractions were also determined. Stalk pith torrefied at 280 °C and stalk shell torrefied at 250 °C had highest and lowest dry matter loss, of about 44% and 13%, respectively. Stalk pith torrefied at 250 °C had lowest energy density of about 18-18.5 MJ/kg, while cob shell torrefied at 280 °C had the highest energy density of about 21.5 MJ/kg. The lowest energy yield, at 59%, was recorded for stalk pith torrefied at 280 °C, whereas cob and stalk shell torrefied at 250 °C had highest energy yield at 85%. These differences were a consequence of the differences in particle densities, hemicellulose quantities, and chemical properties of the OPEN ACCESSEnergies 2012, 5 1200 original biomass samples. Gas residence time did not have a significant effect on the aforementioned parameters.

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Matthew J. Darr

Effects of torrefaction process parameters on biomass feedstock upgrading

A techno‐economic analysis of the corn stover feedstock supply system for cellulosic biorefineries

Biomass storage: an update on industrial solutions for baled biomass feedstocks

Effect of Torrefaction on Water Vapor Adsorption Properties and Resistance to Microbial Degradation of Corn Stover

The Effects of Particle Size, Different Corn Stover Components, and Gas Residence Time on Torrefaction of Corn Stover

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