Modeling an integrated market for sawlogs, pulpwood, and forest bioenergy

Kong, Jiehong; Rönnqvist, Mikael; Frisk, Mikael

doi:10.1139/x11-175

Cited by 23 publications

(5 citation statements)

References 18 publications

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“…However, evidence suggests that success of forest bioenergy business cases often hinges on a tight management of feedstock quality, an aspect that is often neglected in the bioenergy sector [43], especially when the feedstock is a byproduct or residue from other processes. The quality of the bioenergy end-product can be significantly improved, and production costs reduced, by close integration of production lines of conventional forest products (such as flooring) and bioenergy products [44]. Developing more formal relationships between the type of process that generates residues (e.g., planning, trimming, sawing), and the physical and chemical properties of residues hence generated (which can then be used to predict pellet quality), would greatly contribute to the optimization of pellet production by reducing uncertainty associated with the "trial-and-error" method too often used in current pellet production.…”

Section: Discussionmentioning

confidence: 99%

Optimizing Quality of Wood Pellets Made of Hardwood Processing Residues

Thiffault

Barrette

Blanchet

et al. 2019

Forests

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Small-scale wood pellet producers often use a trial-and-error approach for determining adequate blending of available wood processing residues and pelletizing parameters. Developing general guidelines for optimizing wood pellet quality and meeting market standards would facilitate their market entry and profitability. Four types of hardwood residues, including green wood chips, dry shavings, and solid and engineered wood sawdust, were investigated to determine the optimum blends of feedstocks and pelletizing conditions to produce pellets with low friction force, high density and high mechanical strength. The feedstock properties reported in this study included particle size distribution, wood moisture content, bulk density, ash content, calorific values, hemicelluloses, lignin, cellulose, extractives, ash major and minor elements, and carbon, nitrogen, and sulfur. All residues tested could potentially be used for wood pellet production. However, high concentrations of metals, such as aluminum, could restrict their use for accessing markets for high-quality pellets. Feedstock moisture content and composition (controlled by the proportions of the various residue sources within blends) were the most important parameters that determined pellet quality, with pelletizing process parameters having less overall influence. Residue blends with a moisture content of 9%-13.5% (dry basis), composed of 25%-50% of sawdust generated by sawing of wood pieces and a portion of green chips generated by trimming of green wood, when combined with a compressive force of 2000 N or more during pelletizing, provided optimum results in terms of minimizing friction and increasing pellet density and mechanical strength. Developing formal relationships between the type of process that generates residues, the properties of residues hence generated, and the quality of wood pellets can contribute to optimize pellet production methods. deliver 120 exajoules (EJ) (50% of the world's energy needs) for heat, 15% EJ for transport, and 18 EJ (7%) for electricity [2,3].In temperate and boreal countries, forest biomass, in the form of wood chips and wood pellets, is used for power and/or heat production, with boilers of various capacities ranging from small community heating systems up to large power plants. Relative to wood chips, pellets have a higher energy density per unit of mass and volume, are easier to store and handle in large volumes, and show less heterogeneity in physical and chemical properties [4,5]. Whereas wood chips are often preferred for small-scale facilities for which feedstock can be sourced over short distances, wood pellets can be used in larger-scale installations and/or for transport and trade over long distances (e.g., transatlantic and transpacific trade) [6].In the province of Quebec (Canada), the primary and secondary wood processing sectors generate large amounts of wood residues annually. In 2013, the hardwood flooring industry generated about 400 × 10 3 metric tons of wood residues including sawdust, wood chips, and wood...

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Section: Discussionmentioning

confidence: 99%

Optimizing Quality of Wood Pellets Made of Hardwood Processing Residues

Thiffault

Barrette

Blanchet

et al. 2019

Forests

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“…FBSC BSCs based on biomass conversion are seriously affected by the availability of biomass resources over time Kong et al 2012 To develop an optimization model to integrate the roundwood and forest biomass value chains in the initial stage of the forest biomass supply chain designs (FBSCs); minimizing costs of procurement, chipping, inventory, and transportation Sawlogs, pulpwood, forest residues, wood chips, and bark…”

Section: Discussionmentioning

confidence: 99%

Forest biomass supply chain optimization for a biorefinery aiming to produce high-value bio-based materials and chemicals from lignin and forestry residues: a review of literature

Dessbesell

Pulkki

et al. 2017

Can. J. For. Res.

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Technological development has enabled the production of new value-added products from lignocellulosic residues such as lignin. This has allowed the forest industry to diversify its product portfolio and maximize the economic returns from feedstock, while simultaneously working towards sustainable alternatives to petroleum-based products. Although previous research has explored industrial-scale production opportunities, many challenges persist, including the cost of woody biomass and its supply chain reliability. While numerous studies have addressed these issues, their emphasis has traditionally been on bioenergy, with little focus on biochemical, biomaterials, and bioproducts. This review seeks to address this gap through a systematic study of the work recently reported by researchers. A lot of work has been published from United States and Canada with an emphasis on bioenergy production (84.8%), 4.6% of the work is focused on biomass to materials and chemicals, and 10.6% addressed both. Between 2012 and 2015, the majority of published research focused on biomass to materials and chemicals and both biomass to energy and biomass to materials and chemicals. This fact highlights recent interests in diversified biorefinery portfolios. However, further work concerning forest biomass supply chain optimization and new high-value bio-based materials and chemicals is necessary.Key words: biomass to energy, biomass to materials and chemicals, economic optimization, lignocellulosic residues, value-added bio-based products.Résumé : Des avancées technologiques ont rendu possible la production de nouveaux produits à valeur ajoutée à partir de résidus lignocellulosiques tels que la lignine. Cela a permis à l'industrie forestière de diversifié sa gamme de produits et de maximiser les retombées économiques de la matière première tout en travaillant simultanément à développer des alternatives durables aux produits à base de pétrole. Bien que les travaux de recherche précédents aient exploré les opportunités de production à l'échelle industrielle, plusieurs défis persistent, incluant le coût de la biomasse ligneuse et la fiabilité de sa chaîne logistique. Alors que de nombreuses études se sont intéressées à ces questions, l'accent a traditionnellement été mis sur la bioénergie et très peu sur les bioproduits : produits biochimiques et biomatériaux. Cette revue de littérature vise à combler cette lacune par le biais d'une étude systématique des travaux récemment publiés par les chercheurs. Beaucoup de travaux publiés aux États-Unis et au Canada mettent l'accent sur la production de bioénergie (84,8 %), 4,6 % des travaux portent sur la transformation de la biomasse en matériaux et produits chimiques et 10,6 % s'intéressent aux deux sujets. La majorité des travaux de recherche publiés entre 2012 et 2015 portent sur la transformation de la biomasse en matériaux et produits chimiques et sur les deux sujets, soit la transformation de la biomasse en énergie, matériaux et produits chimiques. Cela met en évidence l'intérêt récen...

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“…However, spatially-explicit datasets are not available in many forestry environments around the world, including for hardwood forestry in subtropical eastern Australia. Additionally, log procurement in forestry OR models has tended focus on cost minimisation e.g., [24,[36][37][38], even though forestry investments are usually made on the basis of profitability [39].…”

Section: Introductionmentioning

confidence: 99%

Impact of Facility Location on the Financial Performance of Integrated and Distributed LVL Production in Subtropical Eastern Australia

Venn

Dorries²,

McGavin

et al. 2022

Forests

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In subtropical eastern Australia, the declining availability of traditional, large hardwood native forest logs has motivated hardwood sawmills to explore potentially utilising small logs in the manufacture of veneer-based engineered wood products (EWPs), such as laminated veneer lumber (LVL). An aspatial mathematical model that maximises net present value (NPV) over a 30-year project life has been applied to estimate the financial performance of LVL manufacture in this region. Of particular interest was how facility location affected financial performance, and whether distributed production of veneer (close to the log resource) and LVL (distant from the log resource) may be more profitable than integrated production under some circumstances. While integrated production of veneer and LVL near the resource maximised NPV, distributed production was found to be more profitable than integrated production in situations where the LVL manufacturing facility had to be located relatively far from the resource. Nevertheless, the level of value-adding and processing scale had a greater impact on financial performance than facility location. The analysis also highlighted that log procurement strategy substantially affected financial performance. Encouragingly for forest growers and wood processors, utilising large volumes of small diameter logs, was important for maximisation of NPV of larger-scale LVL facilities.

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Modeling an integrated market for sawlogs, pulpwood, and forest bioenergy

Cited by 23 publications

References 18 publications

Optimizing Quality of Wood Pellets Made of Hardwood Processing Residues

Optimizing Quality of Wood Pellets Made of Hardwood Processing Residues

Forest biomass supply chain optimization for a biorefinery aiming to produce high-value bio-based materials and chemicals from lignin and forestry residues: a review of literature

Impact of Facility Location on the Financial Performance of Integrated and Distributed LVL Production in Subtropical Eastern Australia

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