Trans. Nonferrous Met. Soc. China 25(2015) 1043-1049
Springback and tensile strength of 2A97 aluminum alloy during age forming
Hong-ying LI, Xiao-chao LU
School of Materials Science and Engineering, Central South University, Changsha 410083, China
Received 7 January 2014; accepted 17 December 2014
Abstract: The analysis of variance (ANOVA), multiple quadratic regression and radial basis function artificial neural network (RBFANN) methods were used to study the springback and tensile strength in age forming of 2A97 aluminum alloy based on orthogonal array. The ANOVA analysis indicates that the springback reaches the minimum value when age forming is performed at 210 °C for 20 h using a single-curvature die with a radius of 400 mm, and the tensile strength reaches the maximum value when age forming is performed at 180 °C for 15 h using a single-curvature die with a radius of 1000 mm. The orders of the importance for the three factors of pre-deformation radius, aging temperature and aging time on the springback and tensile strength were determined. By analyzing the predicted results of the multiple quadratic regression and RBFANN methods, the prediction accuracy of the RBFANN model is higher than that of the regression model.
Key words: aluminum alloy; age forming; springback; tensile strength; orthogonal experiment; artificial neural network
1 Introduction
Al-Li alloys have been widely applied in aircraft manufacturing due to their low density, high elastic modulus and high specific strength {Decreus, 2013 #1}[1,2]. 2A97 alloy was developed primarily in an attempt to be used for plates and forgings as a promising aerospace material [3]. However, there are some limits in forming integral aircraft wing panels by traditional forming techniques (such as brake forming, roll forming and shot peen forming) due to their poor assembling ability and the increase of mass. Therefore, a new forming technique is a key for 2A97 alloys to be used to manufacture complex-shaped panel parts. Age forming technique has then been regarded for it can form large integrally stiffened light mass structures [4,5].
Age forming, combining both the aging treatment and forming process, is currently applied to the production of aerospace metal structures. And it has been proven to be very useful for forming components with these shape characteristics and good mechanical properties [6,7]. One of the greatest challenges to improve the efficiency of the age forming technique is to predict the exact amount of springback that will arise, in order that a tool shape may be defined to compensate for it. While in age forming process, springback can be influenced by many parameters, such as aging temperature, aging time and pre-deformation radius. The prediction of the ultimate mechanical properties is also necessary for optimizing the process schedule of age forming. The predictive model can be created using the regression and artificial neural network (ANN) methods based on orthogonal array. Orthogonal design is a method for test design aiming to multifactor and multilevel based on orthogonal theory. Since it presents equilibrium distribution and regular comparability, the optimum scheme can be rapidly obtained by analysis of variance, largely reducing testing number, shortening test time, and minimizing cost. The regression method has successfully been used for obtaining the machining performance by many researchers [8,9]. On the other hand, the ANN has the ability to approximate many functions accurately and hence is suitable for the use in model development of highly non-linear processes. Unlike the regression methods, an artificial neural network does not need to postulate a mathematical model or identify its parameters [10,11]. The ANN learns from training data and recognizes patterns in a series of input and output values without any prior assumptions about their nature and interrelations [12]. They have been successfully applied to solving many practical problems [13,14].
However, the study about the age forming of 2A97 aluminum alloy has not been found. It is of great significance to determine the relationship between the two parameters (springback and tensile strength) and the three factors (pre-deformation radius, aging temperature and aging time) in age forming of 2A97 aluminum alloy. In the present work, the analysis of variance (ANOVA), multiple quadratic regression and radial basis function artificial neural network (RBFANN) methods were carried out based on orthogonal array. And the prediction capacities of the multiple quadratic regression and RBFANN models were compared.
2 Experimental
2.1 Materials and procedures
The experiments were carried out on a 2A97 alloy rolled plate with composition (mass fraction) of 3.7% Cu, 1.5% Li, 0.50% Zn, 0.37% Mg, 0.30% Mn, 0.14% Zr and balance Al. Sheet specimens with dimensions of 400 mm × 80 mm × 1.5 mm were used for age forming tests. All specimens under as-received conditions were solution treated at 520 °C for 1.5 h before water quenched to room temperature, and the transfer time must be less than 15 s. Then, the processed samples were kept under a refrigerated condition to prevent from natural aging. In the end, age forming was performed under controlled conditions of temperature and time, using single-curvature dies with different radii. The bended direction was along the rolling direction. The experimental procedures are shown in Fig. 1.
Fig. 1 Material preparation and test program
The amount of springback (SP) is defined by
(1)
where Rf is the radius after springback, and R0 is pre-deformation radius. SP=0 indicates the absence of springback, and SP=1 indicates a complete springback of the plate.
Tensile tests were carried out according to ASTM standard E-8M to evaluate the mechanical properties of the samples. The tensile samples were machined directly from the sheets after age forming. The samples were taken in the longitudinal (L) orientation (parallel to the rolling direction). The gauge length was 60 mm. These samples were stretched at room temperature and a constant extension rate of 1 mm/min. Three tensile tests were performed for every specimen to ensure the reproducibility of the tensile results.
2.2 Experimental design
In the experimental plan, the factors selected as controllable ones in this work were the pre-deformation radius (R0), aging temperature (θ) and aging time (t), and four levels for each factor were selected. The factors and levels are tabulated in Table 1. Normally, one needs to conduct 43(64) experiments with three factors, and each varies at four levels considered, using full factorial experimental design. In order to save experimental cost and time, orthogonal array was applied to obtaining the springback (SP) and tensile strength (Rm) of the specimen after age forming. An L16 (43) orthogonal array was found to be appropriate and was chosen in this work. The layout of the L16 (43) orthogonal array and the measured values of the SP and Rm are shown in Table 2.
Table 1 Assignment of levels to factors
Table 2 Orthogonal array L16 (43) and experimental results
3 Results and discussion
3.1 Analysis of variance (ANOVA)
An ANOVA of the data was done with the springback and the tensile strength for analyzing the influence of the pre-deformation radius, aging temperature and aging time of the contact on the total variance of the results, respectively. Tables 3 and 4 show the results of the ANOVA with the springback and tensile strength, respectively. The last columns of Tables 3 and 4 show the percentage of contribution (P) of each factor to the total variation indicating the degree of influence on the result. From Table 3, we can observe that factor B, the aging temperature, with ontribution of 56.49%, has the greatest influence on the springback. The relative influence of the factors on the springback was in the following order: aging temperature > aging time > pre-deformation radius.
Table 3 Analysis of variance for springback test
Table 4 Analysis of variance for tension test
From Table 4, it can be observed that the percentage of contribution (P=51.75%) of factor B, the aging temperature, is much larger compared with that for the other two factors, viz., the pre-deformation radius and aging time. The relative influence of the factors on the tensile strength is in the following order: aging temperature >> pre-deformation radius > aging time.
Fig. 2 Performance of individual factor at different levels for springback and tensile strength
The performance of the individual factor (the pre-deformation radius, aging temperature and aging time) at different levels for the springback (SP) and tensile strength (Rm) is depicted in Fig. 2. It can be seen from Fig. 2(a) that the springback and tensile strength constantly increase with the increase of pre-deformation radius. As for the factor of the aging temperature in Fig. 2(b), the increase of the aging temperature leads to a significant decrease of the springback. The tensile strength increases with the increase of the aging temperature, reaches the maximum value at the aging temperature of 180 °C, and then decreases. It can be seen from Fig. 2(c) that the springback constantly decreases with the increase of aging time, and the tensile strength increases at first and then decreases with the increase of aging time. It can be found that the springback reaches the maximum at the pre-deformation radius of 1000 mm, aging temperature of 120 °C and aging time of 5 h, respectively, and the tensile strength reaches the maximum value at the pre-deformation radius of 1000 mm, aging temperature of 180 °C and aging time of 15 h, respectively. Therefore, it can be concluded that the springback reaches the minimum value when age forming is performed at 210 °C for 20 h using a single-curvature die with a radius of 400 mm and the tensile strength specimen reaches the maximum value when age-forming is performed at 180 °C for 15 h using a single-curvature die with a radius of 1000 mm.
3.2 Regression analysis
The correlations between the factors (pre- deformation radius, aging temperature and aging time) and the measured parameters (the springback and tensile strength) were obtained by multiple quadratic regressions, respectively. The equations obtained are as follows:
SP=0.013R0+0.783θ-0.743t+5.297×10-6R02-0.03θ2+0.091t2+5.608×10-5R0θ-0.013θt-0.001R0t+12.149,
R=0.996 (2)
Rm=-0.249R0+4.685θ+21.245t+5.056×10-5R02-0.014θ2-0.363t2+0.001R0θ-0.044θt-0.001R0t
-31.822, R=0.897 (3)
In order to confirm the verification of regression model, the comparison was done between the predicted values from the regression models (Eqs. (2) and (3)), with the values obtained experimentally. The errors calculated with respect to the calculated results were also given. The results are shown in Tables 5 and 6. It is clear that the errors of experimental results with respect to the calculated ones lie in the range of 1.23%-22.34% for the springback, 2.91%-19.57% for the tensile strength.
Table 5 Comparison of RBFANN and regression model results for springback with experimental values
Table 6 Comparison of RBFANN and regression model results for tensile strength with experimental values
3.3 Artificial neural network
Artificial neural networks (ANNs) are the best known methods for solving non-linear problems. Their potential has been investigated with topics ranging from image processing and speech recognition to financial forecasting, as well as with material processing [14,15]. Among neural networks, the most popular one is the multilayer feed-forward net with the back-propagation areificial neural network (BPANN) learning algorithm. Recently, the radial basis function artificial neural network (RBFANN) model has been noted for its simple network structure that avoids lengthy calculations as compared with the BPANN, and has good robustness, as well as improved sensitivity to noisy data. In this work, the values of orthogonal arrays in Table 2 have been used to construct the RBFANN model. Two RBFANN models were established with three inputs (pre-deformation radius, aging temperature and aging time) and one output (either springback or tensile strength) for the prediction of springback and tensile strength, respectively. Before the training of the network, both input and output variables should be normalized within the range from 0 to 1 in order to obtain a usable form for the network to read. The following equation was used widely for unification:
(4)
where x is the original data, x′ is the unified data of the corresponding x, xmin and xmax are the minimum and maximum values of x, respectively.
The parameter SPREAD is a unique parameter which needs to be determined for establishing reliable RBFANN models of the springback or tensile strength, respectively. According to the experience, the parameter SPREAD=2 was selected for the springback and SPREAD=10 was selected for the tensile strength.
In order to confirm the verification of two RBFANN models, the comparison was done between the predicted values from the two RBFANN models, with the values obtained experimentally. The errors calculated with respect to the calculated results are also given (Tables 5 and 6). It is clear that the errors of the springback and tensile strength for the RBFANN are very small. Furthermore, other four tests were performed for investigating the prediction capacity of RBFANN model. The four experiment test data and the corresponding values predicted by RBFANN models as well as the errors are listed in Table 7. It can be seen that the error is very low, which shows that the well-trained RBFANN model has a great accuracy in predicting the springback and tensile strength.
3.4 Comparison between RBFANN and regression results
From Tables 5 and 6, we can observe that the test errors for the RBFANN model are lower than those of the regression model. This indicates that the RBFANN model is more suitable for estimating the springback and tensile strength in an acceptable error range. Furthermore, for the comparison of the prediction capacity of the RBFANN model and regression model, Fig. 3 shows the simulation variation of the springback and tensile strength as a function of the pre-deformation radius by the regression model and RBFANN model at θ=120 °C and t=10 h; θ=150 °C and t=20 h; θ=180 °C and t=15 h; θ=210 °C and t=5 h, respectively. Figure 4 shows the simulation variation of the springback and tensile strength as a function of the aging temperature by the regression model and RBFANN model at R0=400 mm and t=20 h; R0=600 mm and t=15 h; R0=800 mm and t=5 h; R0=1000 mm and t=10 h, respectively. Figure 5 shows the simulation variation of the springback and tensile strength as a function of the aging time by the regression model and RBFANN model at R0=400 mm and θ=150 °C; R0=600 mm and θ=180 °C; R0=800 mm and θ=210 °C; R0=1000 mm and θ=120 °C, respectively. From Figs. 3-5, most of the simulation results deviate from the experimental values. Nevertheless, the simulation results of the RBFANN models are in good agreement with the experimental results under all the conditions. This indicates that the prediction accuracy of the RBFANN model is higher than that of the regression model.
Table 7 Results of experiment tests and predictions by RBFANN
Fig. 3 Simulation variation of springback (a) and tensile strength (b) as function of pre-deformation radius by regression model and RBFANN model, respectively
Fig. 4 Simulation variation of springback (a) and tensile strength (b) as function of aging temperature by regression model and RBFANN model, respectively
Fig. 5 Simulation variation of springback (a) and tensile strength (b) as function of aging time by regression model and RBFANN model, respectively
4 Conclusions
1) The ANOVA indicates that the springback reaches the minimum value under age forming conditions of 210 °C for 20 h using a single-curvature die with a radius of 400 mm and the tensile strength reaches the maximum value at under age-forming conditions of 180 °C for 15 h using a single-curvature die with a radius of 1000 mm.
2) The importance order for the factors to the springback, in sequence, is the aging temperature, the aging time, and the pre-deformation radius. The importance order to the tensile strength, in sequence, is the aging temperature, the pre-deformation radius and the aging time.
3) Both the regression and RBFANN methods can be used to obtain the model; however, the predicted results of the RBFANN models are in better agreement with the experimental results under any conditions. This indicates that the prediction accuracy of the RBFANN model is higher than that of the regression model.
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2A97铝合金时效成形过程中的回弹量和抗拉强度
李红英,鲁晓超
中南大学 材料科学与工程学院,长沙 410083
摘 要:基于正交实验,运用方差分析、多元二次回归和径向人工神经网络研究2A97铝合金时效成形过程中的回弹量和抗拉强度。方差分析结果表明,在预弯半径为400 mm、时效温度为210 °C时效20 h后试样具有最小的回弹量;而在预弯半径为1000 mm、时效温度为180 °C下时效15 h后试样具有最大的抗拉强度。确定了预弯半径、时效温度和时效时间这3个因素对试样回弹量和抗拉强度影响大小的顺序。多元二次回归方法和径向人工神经网络的预测结果表明,径向人工神经网络模型具有更高的预测精度。
关键词:铝合金;时效成形;回弹量;抗拉强度;正交试验;人工神经网络
(Edited by Wei-ping CHEN)
Corresponding author: Hong-ying LI; Tel: +86-731-88836328; E-mail: lhying@csu.edu.cn
DOI: 10.1016/S1003-6326(15)63696-2