采用模拟试验研究水位涨落影响下的坡面波浪侵蚀过程

doi:10.16843/j.sswc.2020.01.007

摘要
图/表
参考文献
相关文章 (15)

全文: HTML (1 KB)
输出: BibTeX | EndNote (RIS)

摘要为了研究3种水位涨落条件下（水位下落、固定、上涨）波浪对岸坡侵蚀的特征，为水土流失预测及防治提供科学参考，采用水槽模拟试验，通过采集各水位条件下坡面微地形数据，对坡面侵蚀-沉积时空变化特征进行了研究。研究结果表明：1）3种水位条件下侵蚀过程明显不同；水位下落时，坡面上形成阶梯状浪蚀龛，而水位上涨和固定时只形成一级浪蚀龛并消失，且消失的过程有所不同。2）水位涨落时坡面侵蚀量约是固定时的1.5倍；水位上涨时侵蚀主要发生在前30 min，水位固定和下落时侵蚀率呈减小趋势，且水位固定时减小更快。3）水位下落时侵蚀主要发生在中坡位，而水位固定和上涨时侵蚀主要发生在上坡位，且水位固定时有少量泥沙沉积在下坡位。因此，波浪作为坡岸侵蚀的重要外营力，其回落的范围影响着泥沙输移及沉积的范围，且水位涨落造成破波点移动，进而增加波浪对坡岸的冲击作用，故侵蚀加强。

	服务

	把本文推荐给朋友
	加入我的书架
	加入引用管理器
	E-mail Alert
	RSS
	作者相关文章
	谷举
	刘刚
	师宏强
	李海茹
	陈鸿

关键词 ：波浪破碎, 微地形, 浪蚀龛, 坡岸侵蚀, 空间分布

Abstract：[Background] The bank slopes of the reservoirs or lakes suffer from severe erosion owing to the appearance of water-level-fluctuating zone. However, the processes and quantified impacts of wave-induced erosion on slopes remain unclear. This paper focuses on the characteristics of wave-induced slope erosion under three water level-fluctuation conditions:dropping (WLD), fixed (WLF) and rising (WLR), to provide a scientific reference for predicting the soil loss and protecting the bank.[Methods] A steel tank with glass pane was used to simulate the wave-induced slope erosion in the three treatments. The slope elevation data were collected by using the method of the pin meter for every 15 minutes from the beginning to the end, a total of 5 times during all treatments. These data were processed by using software (Surfer 9.0) to get the slope micro-topography and the erosion volume. Then the temporal and spatial change of slope erosion-deposition can be analyzed according to the erosion amount or erosion rate calculated based on bulk density of slope soil.[Results] 1)The micro-topography of slope was dramatically different among three treatments. Two layers of wave-cut notch was formed on the slope for the WLD, while a layer of wave-cut notch was formed and then disappeared later in the WLF and WLR, but the processes of disappearance were different between them. 2)The erosion amounts in the WLR and WLD were similar, and its value was about 1.5 times larger than that of the WLF. The erosion primarily happened in the first 30 minutes for the WLR. The erosion rates were gradually decreased for both the WLF and WLD, but the decreasing rate of the WLF was larger than the WLD. 3)For the spatial variation of erosion-deposition, the middle part of slope was the major source of sediment for the WLD. The upper part of slope was the major source of sediment in the WLF and WLR, and partial sediment deposited in the lower part for the WLF.[Conclusions] Wave is one of the important external forces to cause bank slope erosion, while the extent of wave fallback affects sediment transport and the extent of sedimentation. The time-spatial variations of slope erosion-deposition vary, mainly as a result of the combined effects of the movement of wave breaking point caused by water level fluctuation and the change in the injection angle of the wave caused by topographic variation. Moreover, the fluctuation of water level may raise the impact of the waves on the slope, which thus increases the erosion. Therefore, water level fluctuation should be taken into consideration, and the damage effect of wave breaking on bank slopes should be reduced in the prevention of the soil erosion on reservoir bank.

Key words： wave breaking micro-topography wave-cut notch bank erosion spatial distribution

收稿日期: 2019-01-14

PACS:

S157

基金资助:陕西省创新能力支撑计划青年科技新星项目"土壤团聚体稳定性对坡面侵蚀过程的影响"（2017KJXX-83）

通讯作者: 刘刚(1982-),男,博士,研究员。主要研究方向:土壤侵蚀。E-mail:gliu@foxmail.com E-mail: gliu@foxmail.com

作者简介: 谷举(1993-),男,硕士研究生。主要研究方向:水土保持。E-mail:gujuo111@foxmail.com

引用本文:

谷举, 刘刚, 师宏强, 李海茹, 陈鸿. 采用模拟试验研究水位涨落影响下的坡面波浪侵蚀过程[J]. 中国水土保持科学, 2020, 18(1): 49-56.
GU Ju, LIU Gang, SHI Hongqiang, LI Hairu, CHEN Hong. Using simulated experiments to study the processes of wave-induced slope erosion under different water level-fluctuation conditions. SSWC, 2020, 18(1): 49-56.

链接本文:

http://journal12.magtechjournal.com/Jweb_stbc/CN/10.16843/j.sswc.2020.01.007 或 http://journal12.magtechjournal.com/Jweb_stbc/CN/Y2020/V18/I1/49

[1]	艾丽皎, 吴志能, 张银龙. 水体消落带国内外研究综述[J]. 生态科学, 2013, 32(2):259. AI Lijiao, WU Zhineng, ZHANG Yinlong. A summary of water-level-fluctuating zone[J]. Ecological Science, 2013, 32(2):259.
[2]	王彬俨, 文安邦, 严冬春. 三峡水库干流消落带泥沙沉积影响因素[J]. 中国水土保持科学, 2016, 14(1):12. WANG Binyan, WEN Anbang, YAN Dongchun. Factors influencing sedimentation in the riparian zone of the Three Gorges Reservoir[J]. Science of Soil and Water Conservation, 2016, 14(1):12.
[3]	鲍玉海, 贺秀斌. 三峡水库消落带土壤侵蚀问题初步探讨[J]. 水土保持研究, 2011, 18(6):190. BAO Yuhai, HE Xiubin. Preliminary study on soil erosion at the water-level-fluctuating zone of the Three Gorges Reservoir[J]. Research of Soil and Water Conservation, 2011, 18(6):190.
[4]	PUNNING J M, TERASMAA J, VAASMA T. The impact of lake-level fluctuations on the sediment composition[J]. Water, Air and Soil Pollution, 2006, 6(5/6):515.
[5]	BAO Yuhai, HE Xiubin, WEN Anbang, et al. Dynamic changes of soil erosion in a typical disturbance zone of China's Three Gorges Reservoir[J]. Catena, 2018, 169:128.
[6]	DUAN J G, JULIEN P Y. Numerical simulation of meandering evolution[J]. Journal of Hydrology, 2010, 391(1/2):34.
[7]	吴良喜, 曾红娟. 水库消落带应算作破坏水土保持设施面积[J]. 水土保持通报, 2007, 27(4):141. WU Liangxi, ZENG Hongjuan. Hydro-fluctuation belt of reservoir should be regarded as destroyed area of soil and water conservation facilities[J]. Bulletin of Soil and Water Conservation, 2007, 27(4):141.
[8]	NANSON G C, Von KRUSENSTIERNA A, BRYANT E A, et al. Experimental measurements or river-bank erosion caused by boat-generated waves on the Gordon River, Tasmania[J]. River Research and Applications, 1994, 9(1):1.
[9]	COOPS H, GEILEN N, VERHEIJ H J, et al. Interactions between waves, bank erosion and emergent vegetation:an experimental wave tank[J]. Aquatic Botany, 1996, 53(3/4):187.
[10]	蒋昌波, 伍志元, 陈杰, 等. 波浪动力因素变化对沙质岸滩演变的影响[J]. 海洋学报, 2015, 37(3):106. JIANG Changbo, WU Zhiyuan, CHEN Jie,et al. Effects of wave dynamic factors on the evolution of sandy beach[J]. Acta Oceanologica Sinica, 2015, 37(3):106.
[11]	傅文通. 波浪对库岸防护块体大小的影响研究[J]. 水利与建筑工程学报, 2006, 4(2):61. FU Wentong. Study on influence of waves to size of reservoir bank revetment[J]. Journal of Water Resources and Architectural Engineering, 2006, 4(2):61.
[12]	蔡晓禹, 凌天青, 唐伯明, 等. 波浪对散体岸坡冲刷破坏的机理[J]. 重庆交通学院学报, 2006, 25(2):73. CAI Xiaoyu, LING Tianqing, TANG Baiming, et al. Mechanics of the wash-out of the particle bank slope by wave[J]. Journal of Chongqing Jiaotong University, 2006, 25(2):73.
[13]	莫伟伟, 徐平, 丁秀丽. 库水位涨落对滑坡稳定性影响研究进展[J]. 地下空间与工程学报, 2006, 2(6):997. MO Weiwei, XU Ping, DING Xiuli. Research advances on the influences of reservoir water level fluctuation on slope stability[J]. Chinese Journal of Underground Space and Engineering, 2006, 2(6):997.
[14]	朱良君, 张光辉. 地表微地形测量及定量化方法研究综述[J]. 中国水土保持科学, 2013, 11(5):114. ZHU Liangjun, ZHANG Guanghui. Review of measurement and quantification of surface micro-topography[J]. Science of Soil and Water Conservation, 2013, 11(5):114.
[15]	唐敏, 杨春华, 雷波. 基于GIS的三峡水库不同坡度消落带分布特征[J]. 三峡环境与生态, 2013, 35(3):8. TANG Min, YANG Chunhua, LEI Bo. Spatial distribution investigation on the water level fluctuating zone slope in the Three Gorges Reservoir areas based on GIS[J]. Environment and Ecology in the Three Gorges, 2013, 35(3):8.
[16]	康义, 郭泉水, 程瑞梅, 等. 三峡库区消落带土壤物理性质变化[J]. 林业科学, 2010, 46(6):1. KANG Yi, GUO Quanshui, CHENG Ruimei, et al. Changes of the soil physical properties in hydro-fluctuation belt of the Three Gorges reservoir[J]. Scientia Silvae Sinicae, 2010, 46(6):1.
[17]	肖海, 刘刚, 刘普灵. 集中流作用下黄土坡面剥蚀率对侵蚀动力学参数的响应[J]. 农业工程学报, 2016, 32(17):106. XIAO Hai, LIU Gang, LIU Puling. Response of detachment rate of loess slope to hydrodynamic characteristics under concentrate flow condition[J]. Transactions of the CSAE, 2016, 32(17):106.
[18]	金永德, 冯守珍, 周兴华, 等. 强冲刷侵蚀岸段水深地形变化成因分析[J]. 海洋测绘, 2005, 25(6):54. JIN Yongde, FENG Shouzhen, ZHOU Xinghua, et al. Research on the topography in eroded seashore[J]. Hydrographic Surveying and Charting, 2005, 25(6):54.
[19]	李影. 库水位周期性变化对簸箕石滑坡的影响评价[J]. 长江科学院院报, 2017, 34(9):132. LI Ying. Assessment of the influence of cyclical water level variation on Bojishi landslide[J]. Journal of Yangtze River Scientific Research Institute, 2017, 34(9):132.
[20]	张弛, 郑金海, 王义刚. 波浪作用下沙坝剖面形成过程的数值模拟[J]. 水科学进展, 2012, 23(1):104. ZHANG Chi, ZHENG Jinhai, WANG Yigang. Numerical simulation of wave-induced sandbar formation[J]. Advances in Water Science, 2012, 23(1):104.
[21]	陆永军, 左利钦, 季荣耀, 等. 水沙调节后三峡工程变动回水区泥沙冲淤变化[J]. 水科学进展, 2009, 20(3):318. LU Yongjun, ZUO Liqin, JI Rongyao, et al. Changes of sediment deposition and erosion at Chongqing reach in backwater area of Three Gorges Project after reservoir adjusting of the upstream in the Yangtze River[J]. Advances in Water Science, 2009, 20(3):318.
[22]	陈洪凯, 赵先涛, 唐红梅, 等. 基于浪蚀龛和土体临界高度的修正的卡丘金法及其工程应用[J]. 岩土力学, 2014, 35(4):1095. CHEN Hongkai, ZHAO Xiantao, TANG Hongmei, et al. Modified Kachugin method based on wave cut notch and critical height of soil and its engineering application[J]. Rock and Soil Mechanics, 2014, 35(4):1095.
[23]	KHALIFA M A, ZAHRA K A. Collective review in particular reference to soil erosion around maritime structures, effects of the angle of wave:Attack on coastal areas formation and variation on transport rates[J]. American Journal of Marine Science, 2014, 2(1):25.
[24]	DORO E O, AIDUN C K. Interfacial waves and the dynamics of backflow in falling liquid films[J]. Journal of Fluid Mechanics, 2013(726):261.
[25]	SAMBE A N, SOUS D, GOLAY F, et al. Numerical wave breaking with macro-roughness[J]. European Journal of Mechanics-B/Fluids, 2011, 30(6):577.
[26]	OKAMURA M. Impulsive pressure due to wave impact on an inclined plane wall[J]. Fluid Dynamics Research, 1993, 12(4):215.
[27]	许光祥, 钟亮, 刘志伟. 波浪作用下岸坡泥沙起动机理初探[J]. 南昌工程学院学报, 2006, 25(1):48. XU Guangxiang, ZHONG Liang, LIU Zhiwei. A primary study on the threshold motion mechanism of bank sediment under wave action[J]. Journal of Nanchang Institute of Technology, 2006, 25(1):48.
[28]	周国臣. 河岸滑坡治理若干地质问题的分析及处理方法[J]. 资源信息与工程, 2017, 32(6):181. ZHOU Guochen. Analysis and treatment of some geological problems in river bank landslide control[J]. Resources Information and Engineering, 2017, 32(6):181.
[29]	吴昌广, 吕华丽, 周志翔, 等. 三峡库区土壤侵蚀空间分布特征[J]. 中国水土保持科学, 2012, 10(3):15. WU Changguang, LV Huali, ZHOU Zhixiang, et al. Spatial distribution analysis of soil erosion in the Three Gorges Reservoir area[J]. Science of Soil and Water Conservation, 2012, 10(3):15.
[30]	周明涛, 杨平, 许文年, 等. 三峡库区消落带植物治理措施[J]. 中国水土保持科学, 2012, 10(4):90. ZHOU Mingtao, YANG Ping, XU Wennian, et al. Plant management measures on water level fluctuating zone in Three Gorges Reservoir area[J]. Science of Soil and Water Conservation, 2012, 10(4):90.
[31]	薛秀, 王金鹏. 蓄水及降雨条件下库岸边坡变形机理研究[J]. 科学技术与工程, 2015, 15(34):110. XUE Xiu, WANG Jinpeng. An analysis on the deformation mechanism of slope in the process of reservoir and rainfall[J]. Science Technology and Engineering, 2015, 15(34):110.