최소 단어 이상 선택하여야 합니다.
최대 10 단어까지만 선택 가능합니다.
다음과 같은 기능을 한번의 로그인으로 사용 할 수 있습니다.
NTIS 바로가기한국산림과학회지 = Journal of korean society of forest science, v.110 no.2, 2021년, pp.217 - 232
최윤성 (국립산림과학원 산림기술경영연구소) , 정인선 (국립산림과학원 산림기술경영연구소) , 조민재 (국립산림과학원 산림기술경영연구소) , 문호성 (국립산림과학원 산림기술경영연구소) , 오재헌 (국립산림과학원 산림기술경영연구소)
This study calculated the productivity and cost of extraction and processing of logging residues by cut-to-length (CTL) and whole-tree (WT) harvesting methods. In addition, the comparative analysis of the characteristics of wood chip fuel to examine whether it was suitable for the fuel conditions of...
Abe, F. 1986. Calorific value of Japanese coniferous wood. Forest Products Chemistry 36(388): 91-100.
Adebayo, A.B., Han, H.S. and Leonard, J. 2007. Productivity and cost of cut-to-length and whole-tree harvesting in a mixed-conifer stand. Forest Products Journal 57(6):59-69.
Brinker, R.W., Kinard, J., Rummer, B. and Lanford, B. 2002. Machine rate for selected forest harvesting machines. Circular 296(Revised). Alabama Agricultural Experimental Station, Auburn, Alabama, USA, pp. 32.
Cha, D.S., Hwang, J.S. and Oh, J.H. 2011. Power requirement and particle size distribution characteristic by crush condition of wood crusher. In Proceedings of the 2011 Winter Meeting of the Korean Forest Society, Gueongju, Korea, pp. 851-853.
Cho, M.J. 2019. Forest Biomass Supply Chain Management for Regional Self-Sufficient Thermal Energy Utilization. (Dissertation), Chun-Choen. Kangwon National University.
Cho, M.J., Cho, K.H., Choi, B.K. and Cha, D.S. 2018. Yarding productivity of tree-length harvesting using a small cable-yarder in steep slope. Forest Science and Technology. 14(3): 132-137..
Cho, M.J., Choi, Y.S., Paik, S.H., Mun, H.S., Cha, D.S., Han, S.K. and Oh, J.H. 2019. Comparison of Productivity and Cost between Two Integrated Harvesting Systems in South Korea. Forests 10(9): 763.
Choi, Y.S., Cho, M.J., Paik, S.H., Mun, H.S., Kim, D.H., Han, S.K. and Oh, J.H. 2019. Factors Affecting the Chipping Operation Based on the Screen Size of the Drum Chipper. Forest 10(11): 1029.
Construction Association of Korea. 2016. Report of the first half year on the actual condition of construction industry wage in the second half of 2016. Construction Association of Korea: Seoul, Korea, pp. 9-10.
Eliasson, L., Hofsten, H.V., Johannesson, T., Spinelli, R. and Thierfelder, T. 2015. Effects of sieve size on chipper productivity, fuel consumption and chip size distribution for open drum chippers. Croatian Journal of Forest Engineering: Journal for Theory and Application of Forestry Engineering 36(1): 11-17.
Euh, S.H., Oh, K.C., Oh, J.H. and Kim, D.H. 2014. The Formation Characteristics of Tar, Ash and Clinker due to Combustion of Wood Pellet and Performance Analysis of Wood pellet Boiler in terms of the Moisture contents Change of the Wood Pellet. Journal of Energy Engineering 23(3): 221-230.
Filippou, V., Philippou, I., Symeonidis, N., Eleftheriadis, I. and Tsiotas, K. 2018. Analysis of logging forest residues as an energy source. Journal of Agricultural Informatics 9(1): 14-25.
Gendek, A., Malat'ak, J. and Velebil, J. 2018. Effect of harvest method and composition of wood chips on their caloric value and ash content. Sylwan 162(3): 248-257.
Gendek, A. and Nawrocka, A. 2014. Effect of chipper knives sharpening on the forest chips quality. Annals of Warsaw University of Life Sciences-SGGW, Agriculture. pp. 97-107.
Gendek, A. and Nurek, T. 2016. Variability of energy woodchips and their economic effects. Folia Forestalia polonica, Series A-Forestry 58(2): 62-71.
Gendek, A. and Zychowicz, W. 2015. Analysis of wood chippings fractions utilized for energy purposes. Annals of Warsaw University of Life Sciences-SGGW, Agriculture. pp. 79-91.
Huber, C., Kroisleitner, H. and Stampfer, K. 2017. Performance of a Mobile Star Screen to Improve Wood chip Quality of Forest Residues. Forests 8(5): 171.
ISO 16948:2015-Solid Biofuels-Determination of Total Content of Carbon, Hydrogen and Nitrogen, International Organization for Standard, Geneva, Switzerland. pp. 1-9.
ISO 16968:2015-Solid Biofuels-Determination of Minor Elements; International Organization for Standard, Geneva, Switzerland. pp. 1-19.
ISO 17225-4:2021-Solid Biofuels-Fuel Specifications and Classes-Part 4: Graded Wood Chips; International Organization for Standardization: Geneva, Switzerland, Geneva, Switzerland. pp. 1-8.
ISO 17827-1:2016-Solid Biofuels-Determination of Particle Size Distribution for Uncompressed Fuels-Part1: Oscillating Screen Method Using Sieves with apertures of 3.15mm and Abobe; International Organization for Standard. Geneva, Switzerland. pp. 1-10.
ISO 18122:2015-Soild Biofuels-Determination of Ash Content. International Organization for Standard. Geneva, Switzerland. pp. 1-6.
ISO 18125:2017-Solid Biofuels-Determination of Calorific Value. Ineternational Organization for standard, Geneva, Switzerland. pp. 1-56.
ISO 18134-1:2015-Solid Biofuels-Determination of Moisture Content-Oven dry Method-Part1: Total Moisture-Reference Method. International Organization for Standardization, Geneva, Switzerland. pp. 12.
ISO 3310-2:2013-Test Sieves-Technical Requirements and Testing-Part2: Test Sieves of Perforated Metel Plate. International Organization for Standardization, Geneva, Switzerland. pp. 1-9.
Kang, S.B., Kim, J.J., Choi, K.S. and Lee, Y.J. 2008. Measurement of Efficiency and Flue Gas Concentration of 90kW Woodchip Boiler. Korean Society for New and Renewable Energy. pp. 194-197.
Kim, M.K. and Park, S.J. 2013. An Analysis of the Operational Cost in the Whole-tree and Cut-to-Length Logging Operation System. Journal of Korean Society of Forest Science 102(2): 229-238.
Kim, M.K. and Park, S.J. 2012. An Analysis of the Operational Time and Productivity in Whole-tree and Cut-to-Length Logging Operation System. Journal of Korean Society of Forest Science 101(3): 344-355.
Korea Forest Service (KFS). 2012. Forestry mechanization promotion. Korea Forest Service. pp. 24.
Korea National Oil Corporation. 2016. Domestic oil prices. http://www.knoc.co.kr/ (2016. 11. 22)
Kuptz, D. et al. 2019. Evaluation of combined screening and drying steps for the improvement of the fuel quality of forest residue wood chips-results from six case studies. Biomass Conversion and Biorefinery 9(1): 83-98.
Laitila, J. and Nuutinen, Y. 2015. Efficiency of Integrated Grinding and Screening of Stump Wood for Fuel at Roadside Landing with a Low-Speed Double-Shaft Grinder and a Star Screen. Croatian Journal of Forest Engineering: Journal for Theory and Application of Forestry Engineering 36(1): 19-32.
Loria, k. 2015. Watching Wood Dry, http://biomassmagazine.com/articles/12181/watching-wood-dry (2015. 07. 26).
Lee, C.G. et al. 2016. A study on the productivity and cost analysis of the timber and logging residue in CTL system of excavator yarding for using the woody resources. New Renene 12(3): 51-58.
Lee, E.J., Han, S.K. and Im, S.J. 2019. Performance Analysis of Log Extraction by a Small Shovel Operation in Steep Forests of South Korea. Forests 10(7): 585.
Lieskovsky, M., Jankovsky M., Trenciansky M., Merganic, J. and Dvorak, J. 2017. Ash content vs. the economics of using wood chip for energy: model based on data from central europe. Bio Resoureces 12(1): 1579-1592.
Miyata, E.S. 1980. Determining fixed and operating costs of logging equipment. U.S. Department of Agriculture Forest Service.
Moskalik, T. and Gendek, A. 2019. Production of Chips from Logging Residues and Their Quality for Energy: A Review of European Literature. Forests 10(3): 262.
Nati, C., Eliasson, L. and Spinelli, R. 2010. Effect of chip type, biomass type and blade wear on productivity, fuel consumption and product quality. Croatian Journal of Forest Engineering: Journal for Theory and Application of Forestry Engineering 35(1): 1-7.
Nati, C., Spinelli, R., and Fabbri, P. 2010. Wood chip size distribution in relation to blade wear and screen use. Biomass Bioenergy 34(5): 583-587.
National Geographic Information Institute. 2016. The National Atlas of KoreaII. National Geographic Information Institute, Suwon, Korea, pp. 76-77.
National Institute of Forest Science (NIFoS). 2020. Standards and Quality Standards of Wood Products(Wood chips); Notice article(2020-2): Seoul, Korea, pp. 4.
Nordhagen, E. 2014. Wood Fuel Chip Quality Properties of fuel wood Chips In Norway. FEC/FORMEC-2014: Forest Engineering Conference, pp. 1-7.
Pollex, A., Lesche, S., Kuptz, D., Zeng, T., Kuffer, G., Muhlenberg, J., Hartmann, H. and Lenz, V. 2020. Influence of Screening and Drying on Low-Quality Wood Chips for Application in Small-Scale Gasification Plants. Chemical Engineering & Technology 43(8): 1493-1505.
Raitila, J. and Heiskanen, V.P. 2015. Profitability of drying wood chips Integrated into fuelwood supply; Proceedings of the 48th FORMEC Symposium, pp. 143-146.
Smeets, E. and Faaij, A. 2007. Bioenergy potentials from forestry in 2050. Climatic Change 81(3): 353-390.
Spinelli, R. and Hartsough, B. 2001. A survey of Italian chipping operations. Biomass Bioenergy 21(6): 433-444.
Spinelli, R., Magagnotti, N. 2010. Comparision of two harvesting systems for the production of forest biomass from the thinning of picea abies plantations. Scandinavion Journal of Forest Research 25(1): 69-77.
Spinelli, R. and Visser, R. 2009. Analyzing and estimation delays in wood chipping operations. Biomass Bioenergy 33(3): 429-433.
Woo, B.M., Koh, D.H., Kim, J.S., Oh, K.C., Kwon, T.H., Ma, H.S., Kim, J.W., Lee, H.H. and Kim, N.C. 1990. Forest Engineering; Gwangilmunhwasa: Seoul, Korea, pp. 332-334.
Woo, H. 2015. Screening and Characterization of Comminuted Woody Biomass Feedstocks. (Dissertation). Arcata, USA, Humboldt State University.
*원문 PDF 파일 및 링크정보가 존재하지 않을 경우 KISTI DDS 시스템에서 제공하는 원문복사서비스를 사용할 수 있습니다.
Free Access. 출판사/학술단체 등이 허락한 무료 공개 사이트를 통해 자유로운 이용이 가능한 논문
※ AI-Helper는 부적절한 답변을 할 수 있습니다.