Methodology to Estimate Mass of 4 Types of Flammable Forest Fuels in Southwest Forest Areas of China

Abstract

Abstract: According to the mass dynamic changing characteristic of live leaf of Pinus yunnanensis,Pinus yunnanensis var.pygmaea,Pinus armandii in forest fire season and irregular distribution pattern of Eupatorium adenophorum,morphological index and fuel mass of branch section with flammable live leaves of the 3 species conifer plants and stem of Eupatorium adenophorum were measured,then the equations of correlation between fuel mass and morphology index were fitted.The testing result showed that there was no obvious difference between factual value and calculated value of the equations,and it was feasible to estimate flammable fuel mass according to morphological index of branch and stem.

Key words: flammable fuel, morphological index, branch, stem

CLC Number:

S762

ZHENG Yongbo, LI Zhi, LIAO Zhouyu, SHU Lifu, ZHANG Jialin, MAO Shundong, LI Shiyou. Methodology to Estimate Mass of 4 Types of Flammable Forest Fuels in Southwest Forest Areas of China[J]. FOREST RESOURCES WANAGEMENT, 2013, (1): 98-101.

References

[1]李世友.昆明“3·29”森林火灾对防控林区火灾的启示[J].中国安全生产科学技术,2009,5(6):48-52.
[2]李世友,刘文胜,李眉慧,等.紫茎泽兰分布区应慎修生土隔离带[J].森林防火,2009(1):49-51.
[3]李世友,邱红伟,陈文龙,等.利用森林可燃物制炭的初步研究[J].山东林业科技,2009,39(1):48-49.
[4]Sikkink P G,Keane R E.A comparison of five sampling techniques to estimate surface fuel loading in montane forests[J].International Journal of Wildland Fire,2008,17(3):363-379.
[5]Stephens S L,Finney M A,Schantz H.Bulk density and fuel loads of ponderosa pine and white fire forest floors:impacts of leaf morphology[J].Northwest Science,2004,78:93-100.
[6]Pearce H G,Anderson W R,Fogarty L G,et al.Linear mixed-effects models for estimating biomass and fuel loads in shrublands[J].Canadian Journal of Forest Research,2010,40(10):2015-2026.
[7]Pereira J M C,Sequeira N M S,Carreiras J M B.Structural properties and dimensional relations of some Mediterranean shrub fuels[J].International Journal of Wildland Fire,1995,5(1):35-42.
[8]张国防,欧文琳,陈瑞炎,等.杉木人工林地表可燃物负荷量动态模型的研究[J].福建林学院学报,2000,20(2):133-135.
[9]邓湘雯,聂绍元,文定元,等.南方杉木人工林可燃物负荷量预测模型的研究[J].湖南林业科技,2002,29(1):24-27.
[10]袁春明,文定元.马尾松人工林可燃物负荷量和烧损量的动态预测[J].东北林业大学学报,2000,28(6):24-27.
[11]林贤松.马尾松人工林地表可燃物负荷量动态模型的研究[J].福建林业科技,2007,34(3):42-44.
[12]李世友,张凯,刘会龙,等.一种快速测定云南松和华山松林下细小可燃物负荷量的方法[J].福建林业科技,2009,36(3):110-113.
[13]于冠所,孟海波,韩增强.油松纯林地表可燃物状况的初步研究[J].河南林业科技,1999,19(4):16-18.
[14]单延龙,张敏,胡海清.大兴安岭地区樟子松林地表可燃物模型[J].东北林业大学学报,2005,3(2):74-75,97.
[15]刘晓东,王军,张东升,等.大兴安岭地区兴安落叶松林可燃物模型的研究[J].森林防火,1995(3):7-9,32.
[16]王刚,杜嘉林.大兴安岭森林可燃物载量与林分因子关系的研究[J].森林防火,2004(2):17-19.
[17]邸学颖,王宏良,姚树人,等.大兴安岭森林地表可燃物生物量与林分因子关系的研究[J].森林防火,1994(2):16-18.
[18]单延龙,舒立福,李长江.森林可燃物参数与林分特征关系[J].自然灾害学报,2004,13(6):70-75.
[19]胡海清.利用林分特征因子预测森林地被可燃物载量的研究[J].林业科学,2005,41(5):96-100.