基于Lade模型的生物酶改良膨胀土双屈服面本构关系

doi:10.13229/j.cnki.jdxbgxb20200383

Abstract

Abstract:

The elasto-plastic stress-strain behaviors with double yield surfaces of bioenzyme-treated expansive soil was studied based on Lade model. Firstly， a series of the isotropic consolidation drainage tests and the triaxial consolidated drained shear tests of bioenzyme-treated expansive soil under different ratio of bioenzyme-based soil stabilizer were conducted. Secondly， the expressions between the parameters of the Lade model and the ratio of bioenzyme-based soil stabilizer were fitted based on the triaxial test results. Finally， a Lade model based on the ratio of bioenzyme-based soil stabilizer was proposed. The study conclusions as follows： ①The bulk strain $ε v$ increases nonlinear with the average stress $p$ ， and decreases with the ratio of bioenzyme-based soil stabilizer at $p$ is constant. The test curves of $ε v$ - $p$ are nonlinear relationship. ②The axial strain $ε 1$ ， lateral strain $ε 3$ increases nonlinear with the deviator stress $q$ respectively， and $q$ increases with the ratio of bioenzyme-based soil stabilizer. The bulk strain $ε v$ decreases with the ratio of bioenzyme-based soil stabilizer. The test curves of $q$ - $ε 1$ 、 $ε 1$ - $ε v$ 、 $q$ - $ε 3$ are hyperbola respectively. The stress-strain relationships between $q$ and $ε 1$ are strain hardening， and the relationships between $q$ and $ε v$ are shrinkage. ③A Lade model based on the ratio of bioenzyme-based soil stabilizer can better describe the effects of the ratio of bioenzyme-based soil stabilizer on the elasto-plastic stress-strain behavior of bioenzyme-treated expansive soil， and can well predict the stress-strain relationship of bioenzyme-treated expansive soil under different ratio of bioenzyme-based soil stabilizer and confining pressures $σ 3$ .

Key words: road engineering, bioenzyme-treated expansive soil, constitutive model with double yield surfaces, Lade model, elasto-plastic stress-train relation

CLC Number:

U416.1

Chang-ping WEN,Huan-xia REN. Constitutive relation with double yield surfaces of bioenzyme⁃treated expansive soil based on Lade model[J].Journal of Jilin University(Engineering and Technology Edition), 2021, 51(5): 1716-1723.

Figures/Tables 7

Fig.1

Table 1

Physical and mechanical index of expansive soil test samples"

指标	数值	指标	数值
天然含水率w/%	29.0	标准吸湿含水率/%	5.9
液限/%	59.0	无荷膨胀率/%	8.9
塑限/%	26.0	胀缩总率/%	4.1
塑性指数I_p/%	33.0	CBR/%	2.15
最大干密度ρ_max/（g·cm^-3）	1.65	无侧限抗压强度/kPa	248
最佳含水率w_opt/%	18.0	$<$ 0.002 mm含量/%	18.5
自由膨胀率/%	64	活动度	1.78

Table 1

Fig.2

Fig.3

Fig.4

Table 2

Fig.5

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z/%	K₀	n₀	K₁	n₁	m	η₁	S	R	t	K	l	α	β
0	1.405	0.746	1.083	0.797	0.694	108.320	0.327	-1.055	1.502	0.645	1.736	2.652	-0.406
1	1.564	0.701	0.918	0.782	0.974	135.843	0.312	-2.377	4.953	0.606	1.932	2.801	-0.372
2	1.756	0.637	0.886	0.771	1.194	190.356	0.302	-4.058	8.956	0.551	2.170	2.913	-0.308
3	1.951	0.614	0.796	0.767	1.445	249.517	0.287	-5.312	12.327	0.531	2.411	3.002	-0.267
4	2.125	0.593	0.724	0.753	1.882	340.245	0.272	-6.719	15.904	0.513	2.626	3.165	-0.224
5	2.421	0.535	0.628	0.748	2.351	430.973	0.259	-8.803	19.352	0.463	2.991	3.237	-0.172

Constitutive relation with double yield surfaces of bioenzyme⁃treated expansive soil based on Lade model

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