乐山大佛胸部渗水病害特征研究

doi:10.3969/j.issn.0258-2724.20210194

孙博^{1, 2,},
张虎元¹,
张鹏²,
申喜旺²,
杨天宇³

1.
兰州大学土木工程与力学学院，甘肃兰州 730000
2.
中铁西北科学研究院有限公司，甘肃兰州 730000
3.
乐山大佛风景名胜区管理委员会，四川乐山 614000

基金项目:国家自然科学基金（51808246）；国家重点研发计划（2019YFC1520500）

详细信息

作者简介:
孙博（1984—），男，工程师，研究方向为石质文物保护，E-mail：xbysunbo@163.com

中图分类号:P642.5
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出版历程
- 收稿日期:2021-03-23
- 修回日期:2022-03-21
- 网络出版日期:2023-05-27
- 刊出日期:2022-03-24

Study on Characteristics of Water Seepage in Chest of Leshan Giant Buddha

1.
College of Civil Engineering and Mechanics, Lanzhou University, Lanzhou 730000, China
2.
Northwest Research Institute Co., Ltd., of C. R. E. C, Lanzhou 730000, China
3.
Management Committee of Leshan Giant Buddha Scenic Area, Leshan 614000, China

摘要

摘要:
为给乐山大佛渗水病害治理及后期保护研究提供科学依据，本研究首次对乐山大佛渗水及大气降水进行定量监测采样，分析大佛渗水来源及其特征，并结合水化学性质和岩石组成对“大佛砂岩”风化机理进行了研究. 研究表明：乐山大佛胸部渗水在平水期与枯水期主要补给来源为地下水，丰水期主要补给来源为大气降水；大佛胸部渗水含有大量溶解质组分，pH平均值为7.70，2009年之后乐山市降水年平均pH＞5.60且逐年增高，至2015年全年降水pH平均值大于7.00，降水已由酸性转为碱性；大佛胸部渗水水化学类型为碳酸盐类-钙组-Ⅱ型与硫酸盐类-钙组-Ⅲ型，阳离子以Ca^{2 +}为主，阴离子以SO₄²⁻与HCO₃⁻为主；大佛胸部岩石主要成分为CaCO₃和SiO₂，在空气和水存在的情况下容易发生溶蚀，岩石风化对大佛渗水中离子贡献超过90%，H₂CO₃与H₂SO₄共同参与了“大佛砂岩”的风化.
- 乐山大佛/
- 渗水监测/
- 大气降水/
- 岩石风化
Abstract:
In order to provide a scientific basis for water seepage control and later protection research of Leshan Giant Buddha, this study conducts quantitative monitoring and sampling of water seepage and atmospheric precipitation of Leshan Giant Buddha for the first time, analyzes the source and characteristics of water seepage, and studies the weathering mechanism of sandstone combined with water chemical properties and rock composition.The study shows that groundwater is the main source of water supply to water seepage in the chest of Leshan Giant Buddha during the level and dry periods, and atmospheric precipitation is the main source of water supply during the wet period. Abundant solute compositions are found in water seepage samples, with the pH value being 7.70. Since 2009, the annual average pH value of precipitation in Leshan City is higher than 5.60 and increases year by year. Until 2015, the annual average pH value of precipitation is higher than 7.00, and the precipitation has changed from acidic to alkaline. The hydrochemical type of water seepage in the chest of Leshan Giant Buddha is carbonate-calcium-type Ⅱ and sulfate-calcium-type Ⅲ. The cation is mainly Ca^{2 +}, and the anion is SO₄²⁻and HCO₃⁻. The rock in the chest of Leshan Giant Buddha is mainly composed of CaCO₃and SiO_2.Therefore, the rock is prone to being corroded after being exposed to air and water. Rock weathering contributes more than 90% of the ions in the seepage water sample, and H₂CO₃and H₂SO₄jointly affect the weathering of sandstone in Buddha.
- Leshan Giant Buddha/
- water seepage monitoring/
- atmospheric precipitation/
- rock weathering

HTML全文

图 1乐山大佛胸部渗水点位

Figure 1.Seepage points of Leshan Giant Buddha′s chest

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图 2大佛胸部渗水量

Figure 2.Seepage water in the chest of giant Buddha

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图 3渗水量与降水强度随时间变化曲线

Figure 3.Variation curves of seepage water and rainfall intensity with time

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图 4乐山大佛降水历年pH变化

Figure 4.PH changes of Leshan Giant Buddha precipitation over the years

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图 52019年大气中SO₂和NO₂含量

Figure 5.SO₂and NO₂in the atmosphere in 2019

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图 6pH随时间变化

Figure 6.PH changes with time

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图 7渗水EC值随时间变化

Figure 7.EC value of seepage water changes with time

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图 8渗水TDS随时间变化

Figure 8.TDS of seepage water changes with time

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图 9渗水中各离子浓度随时间变化

Figure 9.Concentration of ions in seepage water changes with time

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图 10岩石采样位置

Figure 10.Rock sampling location

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图 11扫描电子显微镜

Figure 11.Scanning Electron Microscope

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图 12渗水（Ca^{2 +}+ Mg^{2 +}）/（HCO₃⁻+ SO₄²⁻）当量比值

Figure 12.（Ca^{2 +}+ Mg^{2 +}）/（HCO₃⁻+ SO₄²⁻） of water seepage

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表 1渗水离子贡献

Table 1.Contributions to seepage ions

离子	渗水/ (mmol•L)⁻¹	大气降水/ (mmol•L)⁻¹	降水贡献/%	岩石风化贡献/%
Ca^{2 +}	19.92	0.034	1	99
K⁺	0.88	0	0	100
Mg^{2 +}	2.72	0	0	100
Na⁺	1.24	0.028	6	94
CI⁻	1.19	0.033	9	91
NO₃⁻	1.80	0.018	14	86
HCO₃⁻	1.07	0.031	11	89
SO₄²⁻	19.00	0.132	4	96
注：0代表离子浓度低于仪器检测限.

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表 2X射线荧光

Table 2.X-Ray fluorescence %

样品	SiO₂	CaO	Al₂O₃	MgO	Na₂O	K₂O	Fe₂O
46B	55.41	13.28	9.87	2.08	1.46	1.96	2.59
46C	56.32	15.25	8.85	2.75	2.65	1.45	2.32
46D	56.32	15.25	8.85	2.75	2.65	1.45	2.32
46+B	49.53	15.06	9.81	2.77	1.54	1.69	2.73
46+C	52.35	13.16	10.54	2.26	1.60	1.89	2.94
46+D	52.54	13.52	10.28	2.02	1.63	1.78	3.08
47B	55.84	10.15	12.03	3.78	1.51	2.26	3.35
47C	50.36	9.99	14.31	2.75	1.45	1.79	2.85
47D	59.49	10.39	8.85	2.98	1.53	2.08	2.98
47+B	55.08	10.65	11.61	3.14	1.51	2.06	3.53
47+C	55.09	10.65	11.61	3.14	1.51	2.06	3.59
47+D	54.36	11.45	10.67	3.08	1.55	2.11	3.72
48B	55.62	11.49	10.29	2.04	1.57	1.86	2.66
48C	55.09	10.65	11.61	3.14	1.51	2.06	3.53
48D	54.36	10.67	11.45	3.08	1.55	2.11	3.72

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