A short Literature Review on Sawlog and Pulpwood Transport Efficiency and Fuel Consumption

Q3 Engineering

European Journal of Forest Engineering Pub Date : 2023-06-30 DOI:10.33904/ejfe.1315293

Riley Small, M. Ghaffariyan

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引用次数: 0

Abstract

Timber transport is one of the main components of woody supply chain, which causes high costs and considerable emissions depending on truck size, type, transport distance, and payload. A cradle-to-gate life cycle assessment of Softwood plantations and regrowth hardwood native forests estimated that the most significant contributor to total greenhouse emissions per unit of wood production in softwood plantation was log haulage at 37%. For regrowth native hardwood forests, log transportation contributed 23% of greenhouse gas emissions. This research, built on existing literature, focused on how timber harvesting transportation costs and emissions to the environment can be reduced, specifically, the transport of the industrial timber logs from the Forest Stockpile to the processing facility or unloading points. The review summarized the data and highlighted that the efficiency and emissions data could be categorized into five themes: Higher Capacity Transportation (HCT), Road Networks & Surfaces, Logistics and Planning, Fleet Replacement, and Fuel efficiency technologies. Fuel efficiency improvements across these themes ranged from 3% to 43% within the reviewed case studies. Several studies researched the fuel efficiency of High Capacity Transport indicated that the fuel consumption in liters per ton kilometer was 8-11% lower in the 92-tonne combination HCT compared to a 72-tonne combination HCT due to the increased payload for High Capacity Transport. Road networks and the composition of the surfaces have been shown to have a strong correlation to emissions. Studies have shown a 16.7% increase in emissions from a network of predominantly highways to a higher proportion of Forrest and Gravel roads. Studies that included data on vehicle age found efficiency improvements of up to 26% when new vehicles’ fuel consumption was compared to older vehicles. Newer truck fleets incorporate newer technologies, with reports showing fuel consumption improvements of up to 43% with less than a two-year payback period.

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关于锯木和纸浆运输效率和燃料消耗的简短文献综述

木材运输是木材供应链的主要组成部分之一，根据卡车的大小、类型、运输距离和有效载荷，运输成本高，排放量大。对针叶人工林和再生阔叶林进行的从摇篮到大门的生命周期评估估计，针叶人工林单位木材生产的温室气体总排放量的最大贡献者是原木运输，占37%。对于再生的原生阔叶林，原木运输贡献了23%的温室气体排放。这项研究以现有文献为基础，重点是如何减少木材采伐运输成本和对环境的排放，特别是将工业木材原木从森林储备运输到加工设施或卸货点。该报告总结了这些数据，并强调效率和排放数据可以分为五个主题:高容量运输(HCT)、道路网络和路面、物流和规划、车队更换和燃油效率技术。在审查的案例研究中，这些主题的燃油效率提高幅度从3%到43%不等。几项关于高容量运输燃油效率的研究表明，由于高容量运输的有效载荷增加，与72吨组合HCT相比，92吨组合HCT每吨公里的燃油消耗(升数)降低了8-11%。道路网和路面成分已被证明与排放有很强的相关性。研究表明，一个以高速公路为主的路网的排放量增加了16.7%，而森林和砾石路的比例更高。包括车辆年龄数据在内的研究发现，与旧车相比，新车的燃油消耗量提高了26%。较新的卡车车队采用了较新的技术，报告显示，在不到两年的投资回收期内，燃油消耗提高了43%。

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来源期刊

European Journal of Forest Engineering Agricultural and Biological Sciences-Forestry

CiteScore

1.30

自引率

0.00%

发文量