OALib Journal期刊
ISSN: 2333-9721
费用：99美元

投递稿件

查看量	下载量

相关文章
更多...

大气科学 2012

高风速相干结构对通量输送影响的实验研究

DOI: 10.3878/j.issn.1006-9895.2012.11164

郭云谦 GUO Yunqian,袁仁民 YUAN Renmin,罗涛 LUO Tao,孙鉴泞 SUN Jianning,蒋维楣 JIANG Weimei

Keywords: 高风速相干结构,小波变换,sweep运动,动量通量,感热通量

Full-Text Cite this paper Add to My Lib

Abstract:

切变湍流的相干结构是湍流研究中的重大发现,它表明湍流运动并非完全随机,其中具有可检测的有序结构.本文通过处理南京浦口地区大气边界层观测数据,来分析不稳定层结中高风速相干结构特征.本次观测项目包括对场地中央的气象铁塔上2m和40m高度上超声风速仪的脉动速度、温度测量以及风廓线雷达对边界层风速廓线的测量.对超声水平风速时间序列数据进行小波变换(时间尺度400s),通过阈值来识别这种高风速相干结构.与多普勒风廓线雷达测量结果对比后发现,这种方法确定的相干结构符合常规的认识,具有较长的时间尺度和较大的垂直尺度(接近边界层厚度).分析三天相干结构特性得到无量纲空间间隔约为6,即每隔6个边界层厚度的水平位置出现一个高速相干结构.通过与垂直风速小波系数的比较,发现高风速相干结构与向下垂直风速之间有较好相关,这与湍流中“阵风”现象的研究结论相似.使用四象限分析方法分类得到两种动量通量输送为负的运动：较小水平风速的上扬(ejection)运动(简称为上扬运动)和较大水平风速的下扫(sweep)运动(简称为下扫运动),这两种运动在整个湍流活动中处于主导地位.高风速相干结构通过促进下扫运动和抑制上扬运动来影响动量通量的输送.

References

[1]	Antonia R A, Chambers A J, Friehe C A, et al. 1979. Temperature ramps in the atmospheric surface layer [J]. J. Atmos. Sci., 36 (1): 99-108.
[2]	Barthlott C, Drobinski P, Fesquet C, et al. 2007. Long-term study of coherent structures in the atmospheric surface layer [J]. Bound.-Layer Meteor., 125 (1): 1-24
[3]	陈炯, 郑永光, 胡非. 2003. 用连续子波变换提取城市冠层大气湍流的相干结构 [J]. 大气科学, 27 (2): 182-190. Chen Jiong, Zheng Yongguang, Hu Fei. 2003. Isolating the coherent structure in atmospheric turbulence in the rough urban canopy layer by using continuous wavelet transform [J]. Chinese Journal of Atmospheric Sciences (in Chinese), 27 (2): 182-190.
[4]	Chen J, Hu F. 2003. Coherent structures detected in atmospheric boundary-layer turbulence using wavelet transforms at Huaihe River basin, China [J]. Bound.-Layer Meteor., 107 (2): 429-444.
[5]	Chen W J, Novak M D, Black T A, et al. 1997. Coherent eddies and temperature structure functions for three contrasting surfaces. Part I: Ramp model with finite microfront time [J]. Bound.-Layer Meteor., 84 (1): 99-124.
[6]	程雪玲, 曾庆存, 胡非, 等. 2007. 大气边界层强风的阵性和相干结构 [J]. 气候与环境研究, 12 (3): 227-243. Cheng Xueling, Zeng Qingcun, Hu Fei. 2007. Gustness and coherent structure of strong wind in the atmospheric boundary layer [J]. Climatic and Environmental Research (in Chinese), 12 (3): 227-243.
[7]	Collineau S, Brunet Y. 1993. Detection of turbulent coherent motions in a forest canopy. Part 1: Wavelet analysis [J]. Bound.-Layer Meteor., 65 (4): 357-379
[8]	Drobinski P, Carlotti P, Newsom R K, et al. 2004. The structure of the near-neutral atmospheric surface layer [J]. J. Atmos. Sci., 61 (6): 699-714.
[9]	Farge M. 1992. Wavelet transforms and their applications to turbulence [J]. Annu. Rev. Fluid. Mech., 24 (1): 395-458.
[10]	Foster R C, Vianey F, Drobinski P, et al. 2006. Near-surface coherent structures and the vertical momentum flux in a large-eddy simulation of the neutrally-stratified boundary layer [J]. Bound.-Layer Meteor., 120 (2): 229-255.
[11]	Gao W, Li B L. 1993. Wavelet analysis of coherent structures at the atmosphere-forest interface [J]. J. Appl. Meteor., 32 (11): 1717-1725.
[12]	Gao W, Shaw R H, Paw U K T. 1989. Observation of organized structure in turbulent flow within and above a forest canopy [J]. Bound.-Layer Meteor., 47 (1-4): 349-377.
[13]	Horiguchi M, Hayashi T, Hashiguchi H, et al. 2010. Observations of coherent turbulence structures in the near-neutral atmospheric boundary layer [J]. Bound.-Layer Meteor., 136 (1): 25-44.
[14]	胡非. 1998. 大气边界层湍流涡旋结构的小波分解 [J]. 气候与环境研究, 3 (2): 97-105. Hu Fei. 1998. Atmospheric boundary layer eddy structure identification by orthonormal wavelet expansion [J]. Climatic and Environmental Research (in Chinese), 3 (2): 97-105.
[15]	胡非, 洪钟祥, 雷孝恩. 2003. 大气边界层和大气环境研究进展 [J]. 大气科学, 27 (4): 712-728. Hu Fei, Hong Zhongxiang, Lei Xiaoen. 2003. Recent progress of atmospheric boundary layer physics and atmospheric environment research in IAP [J]. Chinese Journal of Atmospheric Sciences (in Chinese), 27 (4): 712-728.
[16]	Katul G, Kuhn G, Schieldge J, et al. 1997. The ejection-sweep character of scalar fluxes in the unstable surface layer [J]. Bound.-Layer Meteor., 83 (1): 1-26.
[17]	Kline S J, Reynolds W C, Schraub F A, et al. 1967. The structure of turbulent boundary layers [J]. The Journal of Fluid Mechanics, 30 (4): 741-773.
[18]	Krusche N, De Oliveira A P. 2004. Characterization of coherent structures in the atmospheric surface layer [J]. Bound.-Layer Meteor., 110 (2): 191-211.
[19]	Liu Gang, Sun Jianning. 2010. Impact of surface variations on the momentum flux above the urban canopy [J]. Theor. Appl. Climatol., 101 (3-4): 411-419.
[20]	刘罡, 孙鉴泞, 蒋维楣, 等. 2009. 城市大气边界层的综合观测研究——实验介绍与近地层微气象特征分析 [J]. 中国科学技术大学学报, 39 (1): 24-32. Liu Gang, Sun Jianning, Jiang Weimei, et al. 2009. Comprehensive observation research on urban atmospheric boundary layer—Description of field experiment and analysis of micrometeorological properties in the surface layer [J]. Journal of University of Science and Technology of China (in Chinese), 39 (1): 24-32.
[21]	Mahrt L. 1991. Eddy asymmetry in the sheared heated boundary layer [J]. J. Atmos. Sci., 48 (3): 472-492.
[22]	McNaughton K G, Brunet Y. 2002. Townsend’s hypothesis, coherent structures and Monin-Obukhov similarity [J]. Bound.-Layer Meteor., 102 (2): 161-175.
[23]	Oke T R. 2004. Initial guidance to obtain representative meteorological observations at urban sites [R]. Report No., Td. Geneva: World Meteorological Organization.
[24]	Rao K N, Narasimha R, Badri Narayanan M A. 1971. The ‘bursting’ phenomenon in a turbulent boundary layer [J]. J. Fluid. Mech., 48 (2): 339-352.
[25]	是勋刚. 1994. 湍流 [M]. 天津: 天津大学出版社, 255pp. Shi Xungang. 1994. Turbulence [M]. Tianjin: Tianjin University Press, 255pp
[26]	Singh Khalsa S J, Greenhut G K. 1985. Conditional sampling of updrafts and downdrafts in the marine atmospheric boundary layer [J]. J. Atmos. Sci., 42 (23): 2550-2562.
[27]	Wallace J M, Eckelmann H, Brodkey R S. 1972. The wall region in turbulent shear flow [J]. J. Fluid. Mech., 54 (1): 39-48.
[28]	翁宁泉, 曾宗泳, 肖黎明, 等. 1999. 大气折射率结构常数垂直分布特征[J]. 强激光与粒子束, 11 (6): 673-676. Weng Ningquan, Zeng Zongyong, Xiao Liming, et al. 1999. Profile and characteristic of refractive index structure constant [J]. High Power Laser & Particle Beams (in Chinese), 11 (6): 673-676.
[29]	Wilczak J M, Oncley S P, Stage S A. 2001. Sonic anemometer tilt correction algorithms [J]. Bound.-Layer Meteor., 99 (1): 127-150.
[30]	Williams A G, Hacker J M. 1992. The composite shape and structure of coherent eddies in the convective boundary layer [J]. Bound.-Layer Meteor., 61 (3): 213-245.
[31]	Yuan Renmin, Kang M, Park S B, et al. 2011. Expansion of the planar-fit method to estimate flux over complex terrain [J]. Meteor. Atmos. Phys., 110 (3-4): 123-133.
[32]	Zeng Qingcun, Cheng Xueling, Hu Fei, et al. 2010. Gustiness and coherent structure of strong winds and their role in dust emission and entrainment [J]. Advances in Atmospheric Sciences, 27 (1): 1-13.
[33]	曾庆存, 胡非, 程雪玲. 2007. 大气边界层阵风扬尘机理 [J]. 气候与环境研究, 12 (3): 252-255. Zeng Qingcun, Hu Fei, Cheng Xueling. 2007. The mechanism of dust entrainment by gustwind [J]. Climatic and Environmental Research (in Chinese), 12 (3): 252-255.

Full-Text

Contact Us

service@oalib.com

QQ:3279437679

WhatsApp +8615387084133