強降雨條件下孔隙氣壓作用的高臺階排土場滲流與穩定性

崔博; 王光進; 劉文連; 胡斌; 艾嘯韜; 崔周全; 王孟來; 周宗紅

doi:10.13374/j.issn2095-9389.2020.09.01.005

強降雨條件下孔隙氣壓作用的高臺階排土場滲流與穩定性

doi: 10.13374/j.issn2095-9389.2020.09.01.005

崔博¹,
王光進^{1, 2, ,},
劉文連³,
胡斌⁴,
艾嘯韜¹,
崔周全⁵,
王孟來⁵,
周宗紅^{1, 2}

1.
昆明理工大學國土資源工程學院，金屬礦尾礦資源綠色綜合利用國家地方聯合工程研究中心，昆明 650093
2.
云南省中-德藍色礦山與特殊地下空間開發利用重點實驗室，昆明 650093
3.
中國有色金屬工業昆明勘察設計研究院有限公司，云南省巖土工程與地質災害重點實驗室，昆明 650051
4.
武漢科技大學資源與環境工程學院，武漢 430081
5.
云南磷化集團有限公司，國家磷資源開發利用工程技術研究中心，昆明 650113

基金項目: 國家重點研發計劃資助項目（2017YFC0804600）；國家自然科學基金（聯合基金）重點資助項目（U1802243）；國家自然科學基金面上資助項目（41672317）；巖土力學與工程國家重點實驗室開放基金資助課題（Z018017）

詳細信息

通訊作者:
E-mail：wangguangjin2005@163.com

中圖分類號: TD804
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出版歷程
- 收稿日期: 2020-09-01
- 刊出日期: 2021-03-26

Seepage and stability analysis of pore air pressure on a high-bench dump under heavy rainfall

1.
National and Local Joint Engineering Research Center for Green Comprehensive Utilization of Metal Ore Tailings Resources, Faculty of Land Resources Engineering, Kunming University of Science and Technology, Kunming 650093, China
2.
Yunnan Key Laboratory of Sino-German Blue Mining and Utilization of Special Underground Space, Kunming 650093, China
3.
Yunnan Key Laboratory of Geotechnical Engineering and Geohazards, Kunming Prospecting Design Institute of China Nonferrous Metal Industry Co., Ltd, Kunming 650051, China
4.
School of Resources and Environmental Engineering, Wuhan University of Science and Technology, Wuhan 430081, China
5.
National Engineering and Technology Center for Development & Utilization of Phosphate Resources, Yunnan Phosphate Group Co., LTD, Kunming 650113, China

More Information

Corresponding author: E-mail: wangguangjin2005@163.com

摘要

摘要: 強降雨作用下排土場非飽和帶中的孔隙氣壓力會阻礙散土體的雨水入滲，從而進一步影響排土場的安全穩定。然而傳統分析方法往往將孔隙氣壓力視為大氣壓力而忽略其對排土場安全的影響。本文依托江西某礦山高臺階排土場工程，基于現場實驗和調查結果，結合水平分層的排土場典型剖面，分析了傳統方法與考慮孔隙氣壓力的高臺階排土場滲流規律及其安全穩定性，探討了強降雨條件下孔隙氣壓對高臺階排土場濕潤鋒、孔隙水壓力和邊坡安全系數的影響。研究結果表明：降雨入滲初期的孔隙氣壓不顯著，其對高臺階排土場穩定性不產生直接影響；但隨著降雨的持續，孔隙氣壓作用開始顯現，使得高臺階排土場的入滲速率降低，濕潤鋒下移速度變慢，孔隙水壓上升變緩，強降雨對高臺階排土場穩定性的影響也出現一定延時；在降雨入滲中期，孔隙氣壓將保持恒定，延時效應會隨入滲深度的增加而增強；在降雨入滲后期，當濕潤鋒下移至分層臨界面時，孔隙氣壓平衡被破壞，將繼續增大直至新的恒定值，對高臺階排土場的影響加劇；在濕潤鋒下移至相同深度時，孔隙氣壓作用下的高臺階排土場安全系數明顯降低。研究成果將為強降雨條件下的高臺階排土場的長期安全運行和災害監測預警提供理論依據。
- 高臺階排土場 /
- 強降雨入滲 /
- 濕潤鋒 /
- 孔隙氣(水)壓 /
- 邊坡穩定性
Abstract: Under heavy rainfall, the pore air pressure in the unsaturated zone of a dump hinders rainwater infiltration in loose soil, which further affects the safety and stability of the dump. However, traditional analysis methods often regard pore air pressure as atmospheric pressure and ignore its impact on dump safety. Relying on the high bench dump project of a copper mine in Jiangxi, basing on the field test and survey results and combing with the horizontal slice of a typical dump profile, the seepage law and safety stability of a high bench dump with traditional methods while considering the pore air pressure were analyzed. Moreover, the influence of pore air pressure on a wet front, pore water pressure, and slope safety factors of high bench dump under heavy rainfall conditions were discussed. The research results show that pore air pressure at the initial stage of rainfall infiltration is not significant, and pore air pressure does not have a direct impact on the stability of the high bench dump. However, as the rainfall continues, the effect of the pore air pressure begins to appear, reducing the infiltration rate of the high bench dump. Further, the downward movement speed of the wetting front becomes slower, the pore water pressure rises slowly, and the influence of the heavy rainfall delays the stability of the high bench dump. In the middle of rainfall infiltration, the pore air pressure remains constant, the delay effect varies, and the penetration depth increases. In the late stage of rainfall infiltration, when the wetting front moves down to the critical plane of the layering, the pore air pressure balance is destroyed, continuing to increase to a new constant value, which increases the impact on the high bench dump. When the traditional method of wetting front and considering the pore air pressure of wetting front move down to the same depth, the safety factor of the high bench dump under the action of pore air pressure is obviously reduced. The research results provide a theoretical basis for long-term safe operation and disaster monitoring and early warning of high bench dump under heavy rainfall conditions.
- high bench dump /
- heavy rainfall /
- wetting front /
- pore air (water) pressure /
- slope stability

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圖 1 降雨條件下排土場邊坡受力分析圖（不考慮孔隙氣壓）

Figure 1. Force analysis of the dump under rainfall conditions (without considering the pore air pressure)

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圖 2 降雨條件下排土場邊坡受力分析圖（考慮孔隙氣壓）

Figure 2. Force analysis of the dump under rainfall conditions (considering the pore air pressure)

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圖 3 粒徑隨排土場堆積高度變化規律。（a）顆粒尺寸≥100 mm；（b）0.1 mm<顆粒尺寸<100 mm

Figure 3. Diameter changes with the dump height: (a) particles size ≥ 100 mm; (b) 0.1 mm < particles size < 100 mm

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圖 4 高臺階排土場三維模型及剖面線位置

Figure 4. 3D model and section line of the high dump

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圖 5 1-1計算剖面圖(單位：m)

Figure 5. Sectional drawing of the 1-1 profile (Unit: m)

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圖 6 2-2計算剖面圖(單位：m)

Figure 6. Sectional drawing of a 2-2 profile (Unit: m)

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圖 7 滲透系數曲線

Figure 7. Permeability coefficient curves

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圖 8 土水特征曲線

Figure 8. Soil–water characteristic curves

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圖 9 濕潤鋒時程曲線

Figure 9. Wetting front time curves

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圖 10 強降雨條件下不同時段孔隙水壓力分布情況

Figure 10. Distribution of pore water pressure indifferent periods

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圖 11 降雨時長與安全系數的關系

Figure 11. Relationship between rainfall duration and safety factor

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圖 12 濕潤鋒與安全系數的關系

Figure 12. Relationship between wetting front and safety factor

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表 1 高臺階排土場滲透系數計算結果

Table 1. Permeability coefficient of the high dump

Testing position	Permeability coefficient/(cm·s^?1)
Step 239 m	3.51 × 10^?3
Step 223 m	3.49 × 10^?3
Top of the step 200 m	2.50 × 10^?3
Middle of the step 200 m	4.70 × 10^?3
Bottom of the step 200 m	5.00 × 10^?3

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表 2 高臺階排土場巖土力學參數

Table 2. Mechanical parameters of the high dump

Rock–soil layer	Natural unit weight, γ/(kN·m^?3)	Saturated unit weight, γ_s/(kN·m^?3)	Water-bearing condition	Cohesion, C/kPa	Internal friction angle, Φ/(o)	Permeability coefficient, k/(m·s^?1)
Unclassified waste rock	19.20	20.50	Saturated	42.4	30.3	3.50 × 10^?3
Unclassified waste rock	19.20	20.50	Natural	63.0	35.6	3.50 × 10^?3
Top of the packing material	18.60	19.70	Saturated	31.7	27.8	2.50 × 10^?3
Top of the packing material	18.60	19.70	Natural	55.0	33.0	2.50 × 10^?3
Middle of the packing material	19.40	20.70	Saturated	39.0	27.0	4.70 × 10^?3
Middle of the packing material	19.40	20.70	Natural	65.0	36.0	4.70 × 10^?3
Bottom of the packing material	19.80	21.00	Saturated	44.7	32.3	5.00 × 10^?3
Bottom of the packing material	19.80	21.00	Natural	68.0	37.2	5.00 × 10^?3
Weathered layer	20.00	21.50	Saturated	55.0	31.7	5.20 × 10^?7
Bedrock	23.50	24.50	Natural	350.0	40.0	1.20 × 10^?8

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表 3 降雨工況設計

Table 3. Design of the rainfall condition

Rainfall condition	Rainfall intensity/ (mm·d^?1)	Duration/ h	Total precipitation/ mm
Rainstorm	311.7	6	77.925
		12	155.850
		18	233.775
		24	311.700
		30	389.625

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表 4 高臺階排土場安全系數計算結果

Table 4. Safety factor of the high dump

Profile	Duration of rainfall/h	Safety factor		Influence degree of pore air pressure/%
Profile	Duration of rainfall/h	Without considering pore air pressure	Considering pore air pressure	Influence degree of pore air pressure/%
1-1 profile	0	1.815	1.815	0
	3	1.638	1.656	1.06
	6	1.545	1.600	3.44
	12	1.426	1.486	4.01
	18	1.364	1.425	4.26
	24	1.343	1.377	2.45
	30	1.339	1.355	1.20
2-2 profile	0	1.789	1.789	0
	3	1.581	1.597	1.00
	6	1.464	1.525	3.98
	12	1.309	1.384	5.42
	18	1.253	1.302	4.76
	24	1.210	1.245	2.81
	30	1.194	1.218	1.98

下載: 導出CSV

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