Damage Strengthening Constitutive Model of Cemented Paste Backfill

In order to consider the influence of mesoscopic characteristics of materials on the constitutive model of cemented paste backfill (CPB), the uniaxial compression variables and the damage constitutive model, considering the influence of porosity and pore size of filling materials, were derived based on the strain equivalence principle and Weibull probability distribution function. 2e nuclear magnetic resonance (NMR) tests and unconfined compression strength (UCS) tests were carried out on 8 groups of CPB specimens with different slurry concentrations and cement-tailings ratios. 2en, the expression of damage strengthening coefficient is determined, and the stress-strain curves measured by the theoretical model were compared with the experimental ones. 2e results show that the uniaxial compression constitutive model proposed is in good agreement with UCS test results and can effectively describe the damage evolution law and the development process of stress-strain curve of CPB under uniaxial compression. 2e 28-day compressive strength of CPB can reach 8MPa, the residual strength is about 1∼2MPa, the elastic modulus is about 200∼2000MPa, and the porosity is about 3∼5%. 2e CPB with slurry concentration of 74% and 76% and cement-tailings ratio of 1 : 4 and 1 : 6 is more reasonable, and the relevant mechanical parameters are more stable.


Introduction
In recent years, the global industrialization process is accelerating, the demand for mineral resources is increasing, the mining rate is increasing, and the tailings accumulation is increasing [1]. e storage of tailings wastes not only wastes land resources but also causes increasingly serious environmental problems (water pollution, air pollution, surface collapse, vegetation destruction, etc.) [2,3]. Backfill mining technique is widely used in underground mine engineering because of its advantages of saving tailings waste storage place, reducing environmental pollution, effectively controlling ground pressure in goaf, ensuring safe operation, and so on [4][5][6]. Cemented paste backfill (CPB) is a kind of multiphase material formed by mixing a certain proportion of tailings and water with cement as the main cementation material and through mixing, vibrating, curing, and other processes. It has the advantages of no pollution, low energy consumption, and good roof connection performance when used in underground mine filling [7,8]. Whether the strength of CPB meets the requirements is an important basis for the effective implementation of backfill mining technology [9,10].
At present, scholars have systematically studied the mechanical properties of CPB and achieved remarkable results. Hou et al. [11] studied the damage characteristics and energy dissipation analysis of CPB with different curing ages under uniaxial compression. Zhao et al. [12] explored the destruction process and mechanical properties of CPB with different slurry concentrations through uniaxial compression acoustic emission test. Yi et al. [13] discussed the damage and destruction evolution process of CPB with different waste rock contents through uniaxial compression real-time CTscanning mechanical test. In order to obtain the constitutive model of filling material, Liu et al. [14] and Zhao et al. [15] established the damage constitutive model of CPB by introducing the effective damage rate parameter on the basis of Weibull distribution law. Wang et al. [16] set up the damage evolution and constitutive model of CPB by using the damage mechanics theory and considering the delamination effect and studied the mechanical properties of different layered CPB. Cui and Fall [17] built an elasticplastic evolution model to research the important role of hydration of gelling agent on the mechanical behavior and property evolution of CPB. Wang et al. [18] established the paste damage constitutive model at different initial temperatures and proposed the paste temperature-time coupling damage constitutive model through parameter regression of the constitutive model. Cui and Fall [19] set up a thermohydro-mechanical chemical coupling model for CPB and studied the mechanical characteristics under multiphysical environment. Liu et al. [20] built the constitutive equation based on damage mechanics through the mechanical test of CPB with different cement-tailings ratios and discussed the reasonable matching between CPB and rock.
Wittmann et al. [21] believed that due to the differences in representational scales and research methods, according to the internal structure characteristics of the cemented tailings backfill, the mechanical properties of the backfill can be generally described in three different scales (macroscale, mesoscale, and microscale). In macroscale, the cemented tailings backfill is a single homogeneous body formed by mixing cement, tailings, and water cementing. Studies at this scale cannot reveal the relationship between the internal structure, composition, and mechanical properties of the backfill [22]. In mesoscale, the cemented tailings backfill can be regarded as a multiphase composite material composed of tailings, gel matrix, and initial defects (pores and cavities). Existing researches on the constitutive model of CPB mostly consider the influence of external factors such as material composition and ratio, external environment, and loading mode. In other words, the mechanical properties of backfill were studied from the macroscopic scale, while the influence of microscopic properties such as pore defects in the material on the mechanical effects of backfill was ignored. During the process of hydration and hardening, the intercalated pores of hydrated calcium silicate (C-S-H) gel, capillary pores formed by evaporation and loss of water not involved in hydration reaction, and bubble pores formed by residual air during slurry mixing formed in CPB [23,24].
is makes the CTB have the properties of porous material, the pore distribution is complex, and the pore size spans the microcosmic and microscale. e formation, destruction, and expansion of initial pores will have a significant impact on the strength, stiffness, damage failure, and other basic mechanical parameters [25][26][27][28].
Considering the influence of mesoscopic pore characteristics of CPB, a damage constitutive model based on damage strengthening coefficient is derived. en, the effectiveness of the model is verified by combining nuclear magnetic resonance (NMR) test and unconfined compression strength (UCS) test, and the damage evolution law of CPB under uniaxial compression is analyzed, which provides a basis for understanding the basic mechanical properties of CPB.

Damage Strengthening Coefficient
Porosity and pore size are important parameters affecting the mechanical properties of CPB [29][30][31]. In this paper, the porosity and pore size of the CPB specimen are taken as the initial defect measurement index of the material, and the damage strengthening coefficient of the CPB is defined as where α is the damage strengthening coefficient; P is the porosity; and d is the pore size.
Referring to the functional relationship between pore size and strength of concrete material [31], the relationship between damage strengthening coefficient of CPB and porosity and pore size is defined as where G, H, and c are the test parameter, which are related to the slurry concentration, cement-tailings ratio, tailings type, cement type, etc.

Model Establishment.
According to the principle of strain equivalence proposed by Professor Lemaitre [32], a famous French scholar, any stress-strain constitutive relation of damaged materials under uniaxial loading can be derived from the constitutive equation of nondestructive materials, as long as the nominal stress in the constitutive relation of nondestructive materials is replaced by the effective stress after damage. Assuming that the effective bearing area of the CPB specimen is A in the nondestructive state and A 1 after loading damage, the nominal stress of the section under loading is as follows: e effective stress σ * on the effective section is In combination with equations (3)-(5), it is obtained that . (6) en, From σ * � Eε, the damage constitutive equation of CPB can be obtained as follows: 2 Advances in Civil Engineering where E is the elastic modulus of CPB. Previous studies [14,15] have shown that the mechanical properties of mesoscopic heterogeneity of quasibrittle materials obey a certain statistical law. According to the shape characteristics of stress-strain curve of CPB, the nominal damage variable D 0 is selected to obey the two-parameter Weibull distribution equation: where ε is the strain; m and a are the coefficient related to the physical and mechanical properties of CPB, and it is not negative.
At the initial stage of compression, the pores in the CPB are compacted. e existence of pore structure weakens the material properties of CPB and accelerates the damage rate. In this paper, the influence of pore structure on the damage degree of CPB specimen is characterized by the damage strengthening coefficient as shown in equation (2), and the damage variable D is defined as By introducing equation (9) into equation (11), we obtain By introducing equation (11) into equation (8), it is obtained that e results are as follows: Under the action of stress, the CPB specimens are gradually damaged, and the internal structure is destroyed. When the strain exceeds a certain limit and the external stress is at a low stress level again, the internal structural damage tends to be stable, but the specimen still has a certain residual strength. Based on this, the damage threshold c is introduced. When the strain is c, the damage variable in the CPB reaches the maximum damage D c , and the corresponding stress is residual strength. en, the two-stage damage variable and damage constitutive equation are defined:

Model Establishment.
According to the damage constitutive equation of CPB, the stress-strain curve of the whole process is obtained as shown in Figure 1. It can be seen from Figure 1 that the constitutive curve satisfies the following four boundary conditions: (3)σ � σ pk , ε � ε pk ; (4)σ � σ pk , dσ/dε � 0, where σ pk , ε pk, and E are the peak stress, peak load strain, and elastic modulus.
By introducing condition ③ into equation (13), it is obtained that e derivation of (13) is obtained: By substituting condition (4) into equation (17), it is obtained that Because of the elastic modulus E ≠ 0, then, e result is obtained from simultaneous solution equations (16) and (17): Make the equation t � (σ pk /Eε pk ) − (1 − a) true; we can get that  Figure 2(a) shows the particle size distribution of tailings measured by laser particle size distribution analyzer. e figure shows that d 10 � 8.54 µm, d 20 � 66.9 µm, d 50 � 129 µm, d 60 � 163 µm, the nonuniformity coefficient C u � 19.08, and the curvature coefficient C c � 3.22. e grading curve of tailings is smooth and continuous, the slope is gentle, the grading is good, the compactness is easy to obtain, the compressibility is low, the strength is high, and the engineering property is excellent. Figure 2(b) shows the chemical composition of tailings measured by X-ray fluorescence spectrometer (XRF). Among them, CaO content is less than 10%, which is low calcium tailings.

Specimen
Making. According to GB/T 50266-2013 "standard for test methods of engineering rock mass" [35], eight groups of cylinder specimens with cement-tailings ratios of 1 : 4, 1 : 6, 1 : 8, and 1 : 10, slurry concentration of 70%, 72%, 74%, 76%, and 78%, and curing age of 28 days under standard environment were made. e number of specimens in each group is 4, including 3 UCS tests and 1 NMR test. e slurry composition of CPB is shown in Table 1, and the specific test idea and process are shown in Figure 3.

Analysis on the Influence of Slurry Concentration and
Cement-Tailings ratio Figure 4 shows the influence of slurry concentration and cement-tailings ratio on porosity and pore size of CPB. It can be seen from Figure 4(a) that with the increase of the slurry concentration, the porosity of the CPB gradually decreases. When the slurry concentration increases from 72% to 74%, the porosity obviously decreases with a larger gradient, while with the continuous increase of the slurry concentration, the porosity remains about 3%. It can be seen from Figure 4(b) that with the decrease of the cement-tailings ratio, the porosity of the CPB gradually increases. When the cement-tailings ratio decreases from 1 : 8 to 1 : 10, the porosity increases obviously with a larger gradient, while when the cement-tailings ratio increases from 1 : 8 to 1 : 4, the porosity remains about 3%. It can be seen from Figures 4(a) and 4(b) that the proportion of large pore (>50 nm) gradually increases and that of small pore (<50 nm) gradually decreases with the increase of slurry concentration or cement-tailings ratio of CPB. e porosity of CPB body is about 3∼5%. From the point of view of microscopic characteristics, the slurry concentration with 74% and 76% and cement-tailings ratio with 1 : 4 and 1 : 6 are reasonable. Figure 5 shows the influence of slurry concentration and cement-tailings ratio of CPB on elastic modulus, peak strength, and residual strength. It can be seen from Figure 5 that the elastic modulus, peak strength, and residual strength of the CPB increase with the increase of the slurry concentration or the cement-tailings ratio. e 28-day compressive strength can reach 8 MPa, residual strength can reach 1∼2 MPa, and elastic modulus is approximately 200∼2000 MPa, respectively. When the slurry concentration is 74% and 76%, the mechanical properties are similar.

5.1.
eoretical Model Validation. e basic mechanical parameters such as elastic modulus, peak stress, and peak load strain can be obtained from the UCS test of CPB. Combined with the model parameter equation (equations (14), (20), and (21)), the damage strengthening coefficient a and damage threshold c of 8 groups of CPB specimens under different slurry concentrations and cement-tailings ratios can be fitted, and the corresponding Weibull statistical distribution parameters m and a can be calculated, as shown in Table 2. e elastic modulus of CPB is calculated by E 50 method [18,36]. E 50 refers to 50% of the maximum stress of concrete materials in the whole process from loading to destruction divided by its corresponding strain value. e residual strength is taken as the maximum curvature point in the descending section of the stress-strain curve and the average stress after the point. e damage threshold is the strain value at the same stress value as the residual strength in the theoretical curve.
In order to validate the correctness of the damage constitutive model of CPB based on the damage strengthening coefficient established in this paper, the constitutive model calculated by the theoretical model is compared with the UCS test results, and the evolution of damage variables in the whole stress-strain process is analyzed, as shown in Figure 6.

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It can be seen from Figure 6 that the theoretical curve obtained from the damage constitutive calculation based on the damage strengthening coefficient proposed in this paper is in good agreement with the UCS test curve, which can effectively reflect the basic mechanical characteristics of the CPB under uniaxial compression. It can be seen from the distribution of damage variables in Figure 6 that the damage development trend of CPB with different cement-tailings ratios is similar, and they all approximate to the growth trend of the shape of the word "factory." With the increase of axial strain, the damage variable increases gradually. When the axial strain reaches the peak load strain, the damage increases exponentially. When the axial strain reaches the damage threshold, the damage variable tends to 90%. When the damage variable is about 0.25, the stress reaches the peak. e ratio of peak load strain to damage variable corresponding to damage threshold is about 0.25 under different cement-tailings ratios.
e results show that when the damage variable reaches 1/4 of the threshold damage variable, the stress-strain curve shows a downward trend, the   Advances in Civil Engineering damage growth rate is accelerated, and the CPB is easy to be destroyed.

Analysis of Damage Strengthening Coefficient.
According to the analysis of the NMR test results, the main pore type of CPB is capillary pore, and the pore size range is 2.5∼10 4 nm. When analyzing the influence of pore size on material strength, the pore size should be classified and the influence coefficient should be calculated in different pore size areas. In this paper, the pore size is taken as the average value, and then the expression of damage strengthening coefficient and the relevant parameters in equation (2) are taken with reference to [31], and then equation (2) is expressed as MATLAB is used to fit equation (22) with two parameters, and the fitting equation of damage strengthening coefficient is obtained in equation (23); the results are shown in Figure 7. (b) cement-tailings ratio is 1 : 4 and slurry concentration is 72%; (c) cement-tailings ratio is 1 : 4 and slurry concentration is 74%; (d) cementtailings ratio is 1 : 4 and slurry concentration is 76%; (e) cement-tailings ratio is 1 : 4 and slurry concentration is 78%; (f ) cement-tailings ratio is 1 : 6 and slurry concentration is 76%; (g) cement-tailings ratio is 1 : 8 and slurry concentration is 76%; (h) cement-tailings ratio is 1 : 10 and slurry concentration is 78%.

Conclusion
In this paper, a damage constitutive model based on the damage strengthening coefficient is proposed, considering the influence of microcosmic pore characteristics of CPB. e validity of the theoretical model is verified by UCS test and NMR test. e exponential expression of damage strengthening coefficient is given, which can effectively describe the stress-strain relationship and damage evolution process of CPB under uniaxial compression. e main conclusions are as follows: (1) Under uniaxial compression, when the damage variable is about 0.25, the stress reaches the peak value. e ratio of peak load strain to damage variable corresponding to damage threshold is about 0.25. (2) e 28-day compressive strength of CPB can reach 8 MPa, the residual strength is about 1∼2 MPa, the elastic modulus is about 200∼2000 MPa, the porosity is about 3∼5%, the damage strengthening coefficient is about 1∼1.2, and the damage threshold is about 1∼1.5%. (3) From the perspective of microscopic characteristics, the CPB with slurry concentration of 74% and 76% and cement-tailings ratio of 1 : 4 and 1 : 6 is more reasonable, and the relevant mechanical parameters are more stable.

Data Availability
Data are available from the corresponding author upon request.

Conflicts of Interest
Liu Lang, Cheng Kangli, Tu Bingbing, Zhang Bo, and Qiu Huafu declare that they have no conflicts of interest.  Advances in Civil Engineering 9