大粒径骨料心墙沥青混凝土剪胀特性及影响分析

doi:10.11988/ckyyb.20240476

raybet体育在线院报 ›› 2025, Vol. 42 ›› Issue (7): 164-173.DOI: 10.11988/ckyyb.20240476

大粒径骨料心墙沥青混凝土剪胀特性及影响分析

何建新¹^,²(), 杨寒冰¹(), 陈朋朋¹, 丁鑫昱¹, 王亚楠¹, 刘亮¹^,³

¹ 新疆农业大学水利与土木工程学院,乌鲁木齐 830052
² 堤坝工程安全及灾害防治兵团重点实验室,乌鲁木齐 830052
³ 新疆水利工程安全与水灾害防治重点实验室,乌鲁木齐 830052

收稿日期:2024-05-09 修回日期:2024-11-13 出版日期:2025-07-01 发布日期:2025-07-01
通信作者:
杨寒冰(1999-),男,甘肃天水人,硕士研究生,主要从事岩土与水工材料研究。E-mail:725312096@qq.com
作者简介:
何建新(1973- ),男,河南周口人,教授,博士,主要从事水利水电工程研究。E-mail: 604690896@qq.com
基金资助:
新疆维吾尔自治区自然科学基金项目(2022D01A200)

Dilatancy Characteristics and Influencing Factors of Large-Aggregate Core Wall Asphalt Concrete

HE Jian-xin¹^,²(), YANG Han-bing¹(), CHEN Peng-peng¹, DING Xin-yu¹, WANG Ya-nan¹, LIU Liang¹^,³

¹ School of Water Conservancy and Civil Engineering, Xinjiang Agricultural University, Urumqi 830052, China
² Key Laboratory of Dam Construction Safety and Disaster Prevention of Xinjiang Production and Construction Corps, Urumqi 830052, China
³ Xinjiang Key Laboratory of Hydraulic Engineering Security and Water Disaster Prevention, Urumqi 830052, China

Received:2024-05-09 Revised:2024-11-13 Published:2025-07-01 Online:2025-07-01

摘要/Abstract

摘要：

为推广大粒径骨料沥青混凝土在水利工程中的应用,探究了相同配合比,不同影响因素条件下大粒径骨料沥青混凝土的应力应变、剪胀特性,在剪切大变形条件下(轴向应变ε_a=30%)对最大粒径D_max分别为26.5、31.5、37.5 mm沥青混凝土进行了静三轴试验研究,为进一步比较D_max分别为19、37.5 mm沥青混凝土心墙的差异性,基于未考虑心墙和堆石体接触的有限元模型对新疆某典型工程沥青混凝土心墙进行了对比分析,结果表明:随着骨料粒径增大,沥青混凝土的应力-应变曲线由软化型转为硬化型;相同围压条件下,大粒径骨料(D_max>19 mm)沥青混凝土的切线模量E_t低于D_max=19 mm沥青混凝土,围压增加时,D_max=37.5 mm沥青混凝土的最大偏应力、最大体应变相较于D_max=19 mm沥青混凝土都有所下降,适当增大最大骨料粒径可以减弱剪胀性;提出了初始物理参数(围压、不同最大粒径)计算相变应力比M_pt的表达式,可作为大粒径沥青混凝土剪缩剪胀转化的判断依据,M_pt越大,剪胀性越强;大粒径沥青混凝土心墙沉降率、最大小主应力和最大大主应力均几乎无差异。研究成果有助于推动大粒径沥青混凝土在高应力、深厚覆盖层条件的高坝工程的应用。

关键词: 大粒径沥青混凝土, 静三轴试验, 相变应力比, 剪胀特性, 有限元分析

Abstract:

[Objective] To promote the application of large-aggregate asphalt concrete in water conservancy projects, this study investigates the stress-strain and dilatancy characteristics of large-aggregate asphalt concrete under the same mix ratio but under varying influencing factors. [Methods] Under large shear deformation conditions (ε_a=30% ), static triaxial tests were carried out on asphalt concrete with D_max=26.5, 31.5, and 37.5 mm. The dilatancy characteristics were elucidated from the perspectives of confining pressure and different maximum aggregate sizes. The relationship between the phase transformation stress ratio (M_pt) of asphalt concrete and confining pressure as well as different maximum aggregate sizes was comparatively analyzed, and an expression for determining whether dilatancy occurred in the specimen based on initial parameters was established. To further demonstrate the applicability of large-aggregate asphalt concrete, the D_max=19 mm asphalt concrete in the core wall was replaced with D_max=37.5 mm asphalt concrete. Based on a finite element model that ignored the contact and dilatancy between the core wall and the rockfill body, stress-deformation calculations were performed on the asphalt concrete core wall of a typical project in Xinjiang to simulate the behavior of the core wall with large-aggregate asphalt concrete and analyze the influence of maximum aggregate size on the calculation parameters. [Results] (1) With increasing aggregate size, the stress-strain curve of asphalt concrete changed from the softening type to the hardening type. (2) Under the same confining pressure conditions, the tangent modulus E_t of large-aggregate asphalt concrete was lower than that of D_max=19 mm asphalt concrete. As the confining pressure increased, both the maximum deviatoric stress and the maximum volumetric strain of D_max=37.5 mm asphalt concrete decreased compared to D_max=19 mm asphalt concrete, indicating that appropriately increasing the maximum aggregate size could weaken the shear dilatancy. (3) An empirical expression for calculating the phase transformation stress ratio M_pt based on initial physical parameters (confining pressure, different maximum aggregate sizes) was proposed, which could serve as a criterion for the transformation between shear contraction and dilatancy in asphalt concrete. A larger M_pt value indicated stronger shear dilatancy. (4) Furthermore, the finite element analysis results showed that there were almost no differences in settlement rate, maximum minor principal stress, and maximum major principal stress of the core walls. The dilatancy characteristics of large-aggregate asphalt concrete met the requirements of high-stress and deep overburden conditions for high dam projects. [Conclusion] Under the conditions of this study, increasing the maximum aggregate size in the asphalt concrete core wall has almost no effect on its stress condition. The experimental results provide a theoretical basis for the promotion and application of large-aggregate asphalt concrete in high dam projects under high-stress and deep overburden conditions.

Key words: large-aggregate asphalt concrete, static triaxial test, phase transformation stress ratio, dilatancy characteristics, finite element analysis

中图分类号:

TV431.5

何建新, 杨寒冰, 陈朋朋, 丁鑫昱, 王亚楠, 刘亮. 大粒径骨料心墙沥青混凝土剪胀特性及影响分析[J]. raybet体育在线院报, 2025, 42(7): 164-173.

HE Jian-xin, YANG Han-bing, CHEN Peng-peng, DING Xin-yu, WANG Ya-nan, LIU Liang. Dilatancy Characteristics and Influencing Factors of Large-Aggregate Core Wall Asphalt Concrete[J]. Journal of Changjiang River Scientific Research Institute, 2025, 42(7): 164-173.

图/表 15

图1 级配曲线

Fig.1 Grading curves

表1 矿料配合比

Table 1 Mix proportions of aggregates

矿料	不同最大粒径的各级矿料占比/%
矿料	19 mm	26.5 mm	31.5 mm	37.5 mm
[31.5,37.5)mm粗骨料	—	—	—	6.3
[26.5,31.5)mm粗骨料	—	—	6.3	5.9
[19,26.5)mm粗骨料	—	13.5	12.5	11.6
[9.5,19)mm粗骨料	25.0	19.6	18.2	16.9
[4.75,9.5)mm粗骨料	16.6	14.8	13.7	12.7
[2.36,4.75)粗骨料	15.2	13.1	12.2	11.3
[0.075, 2.36)mm细骨料	31.5	27.3	25.2	23.4
填料	12.0	12.0	12.0	12.0
90^#沥青	6.6	6.6	6.6	6.6

表2 90#沥青各项技术性能

Table 2 Technical properties of 90# asphalt

试验项目	单位	规范SL 501— 2010要求	样品检测结果
针入度(25 ℃,100 g,5 s)	0.1 mm	80~100	86.4
延度(5 cm/min,10 ℃)	cm	≥20	>100
延度(5 cm/min,15 ℃)	cm	—	>150
软化点(环球法)	℃	≥44	50.4
溶解度	%	≥99.5	99.85
闪点	℃	≥245	310
蜡含量(蒸馏法)	%	≤2.2	1.9
薄膜烘箱加热后质量变化	%	≤±0.8	-0.08
残留针入度比(25 ℃)	%	≥57	82.0
残留延度(5 cm/min,10 ℃)	cm	≥8	32.8

图2 WYS-2000大型多功能动静三轴试验机

Fig.2 WYS-2000 large-scale multifunctional dynamic and static triaxial testing machine

图3 沥青混凝土在不同围压下的CD试验曲线

Fig.3 Consolidated drainage test curves of asphalt concrete under different confining pressures

图4 剪切变形下的沥青混凝土最大偏应力与围压的关系

Fig.4 Maximum deviatoric stress of asphalt concrete versus confining pressure under shear deformation

图5 Mpt -σ3/Pa关系曲线

Fig.5 Mpt - σ3/Pa relationship curves

图6 Mpt - Di/D1的关系曲线

Fig.6 Mpt - Di/D1 relationship curves

图7 相变应力比Mpt与σ3/Pa、Di/D1的拟合三维视图

Fig.7 Fitted 3D plot of Mpt versus σ3/pa and Di/D1

图8 大坝及沥青混凝土心墙的网格剖面

Fig.8 Grid profile of dam and asphalt concrete core wall

表3 沥青混凝土心墙E-μ模型参数

Table 3 E-μ model parameters of asphalt concrete core wall

最大骨料粒径/ mm	K	n	R_f	c/ kPa	φ/ (°)	G	D	F
19	847.17	0.097	0.896	325.32	27.746	0.513	0.456	0.029 8
37.5	485.64	0.134	0.861	251.24	26.281	0.504	0.273	0.017 2

表4 沥青混凝土心墙E-B模型参数

Table 4 E-B model parameters of asphalt concrete core wall

最大骨料粒径/ mm	K	n	R_f	c/ kPa	φ/ (°)	K_b	m₀
19	847.17	0.097	0.896	325.32	27.746	1 121.222	0.563
37.5	485.64	0.134	0.861	251.24	26.281	1 044.815	0.519

图9 满蓄期沥青混凝土心墙大、小主应力分布

Fig.9 Cloud diagrams of major and minor principal stresses of asphalt concrete core wall during full-storage period

图10 满蓄期沥青混凝土心墙位移分布

Fig.10 Displacement distributions of asphalt concrete core wall during full-storage period

表5 沥青混凝土心墙三维静力计算结果极值

Table 5 Extreme values of 3D static calculation results of asphalt concrete core wall

最大粒径 D_max/ mm	心墙应力/ MPa		心墙位移/m
最大粒径 D_max/ mm	大主应力	小主应力	顺河向上游	顺河向下游	横河向左岸	横河向右岸	竖向(垂直)沉降
19	1.44	2.24	0.001 1	0.103 4	0.037 6	0.045 7	0.261 8
37.5	1.52	2.14	0.001 2	0.103 7	0.038 3	0.046 3	0.263 5

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大粒径骨料心墙沥青混凝土剪胀特性及影响分析

Dilatancy Characteristics and Influencing Factors of Large-Aggregate Core Wall Asphalt Concrete

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