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An Analytical Model to Predict Residual Stress Field Induced by Laser Shock Peening

Hu, Yongxiang ; Yao, Zhenqiang ; Hu, Jun

ASME International ; 2009

In: Journal of Manufacturing Science and Engineering Vol. 131, No. 3 ( 2009-06-01)

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In: Journal of Manufacturing Science and Engineering, ASME International, Vol. 131, No. 3 ( 2009-06-01)

Abstract: Laser shock peening (LSP) is an innovative surface treatment technique similar to shot peening. An analytical model to predict the residual stress field can obtain the impact effect much quickly, and will be invaluable in enabling a close-loop process control in production, saving time and cost of processing. A complete analytical model of LSP with some reasonable simplification is proposed to predict residual stresses in depth by a sequential application of a confined plasma development model and a residual stress model. The spatial distribution of the shock pressure and the high strain rate effect are considered in the model. Good agreements have been shown with several experimental measured results for various laser conditions and target materials, thus proving the validity of the proposed model.

Type of Medium: Online Resource

ISSN: 1087-1357 , 1528-8935

URL: Article

DOI: 10.1115/1.3139219

Language: English

Publisher: ASME International

Publication Date: 2009

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Predictive Modeling and Uncertainty Quantification of Laser Shock Processing by Bayesian Gaussian Processes With Multiple Outputs

Hu, Yongxiang ; Li, Zhi ; Li, Kangmei ; [et al.]

ASME International ; 2014

In: Journal of Manufacturing Science and Engineering Vol. 136, No. 4 ( 2014-08-01)

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In: Journal of Manufacturing Science and Engineering, ASME International, Vol. 136, No. 4 ( 2014-08-01)

Abstract: Accurate numerical modeling of laser shock processing, a typical complex physical process, is very difficult because several input parameters in the model are uncertain in a range. And numerical simulation of this high dynamic process is very computational expensive. The Bayesian Gaussian process method dealing with multivariate output is introduced to overcome these difficulties by constructing a predictive model. Experiments are performed to collect the physical data of shock indentation profiles by varying laser power densities and spot sizes. A two-dimensional finite element model combined with an analytical shock pressure model is constructed to obtain the data from numerical simulation. By combining observations from experiments and numerical simulation of laser shock process, Bayesian inference for the Gaussian model is completed by sampling from the posterior distribution using Morkov chain Monte Carlo. Sensitivities of input parameters are analyzed by the hyperparameters of Gaussian process model to understand their relative importance. The calibration of uncertain parameters is provided with posterior distributions to obtain concentration of values. The constructed predictive model can be computed efficiently to provide an accurate prediction with uncertainty quantification for indentation profile by comparing with experimental data.

Type of Medium: Online Resource

ISSN: 1087-1357 , 1528-8935

URL: Article

DOI: 10.1115/1.4027539

Language: English

Publisher: ASME International

Publication Date: 2014

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Numerical Modeling and Mechanism Analysis of Hybrid Heating and Shock Process for Laser-Assisted Laser Peen Forming

Luo, Mingsheng ; Hu, Yongxiang ; Qian, Dong ; [et al.]

ASME International ; 2018

In: Journal of Manufacturing Science and Engineering Vol. 140, No. 11 ( 2018-11-01)

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In: Journal of Manufacturing Science and Engineering, ASME International, Vol. 140, No. 11 ( 2018-11-01)

Abstract: Laser-assisted laser peen forming (LALPF) is proposed as a hybrid process to combine laser heating and laser peening to improve the bending capability of laser peen forming (LPF) effectively. To predict LALPF-induced bending deformation and mechanism of bending capability improvement, a sequentially coupled modeling approach is established by integrating three models, i.e., a thermoelastic-plastic model to predict the temperature, a dynamic model to obtain the eigenstrain of laser shock, and an eigenstrain model to predict the bending deformation. The effects of temperature, thermal stress, and thermal plastic strain of laser heating and the coupling effects on the bending deformation were investigated. The results show that the interaction of temperature and thermal stress are the dominant factors contributing to the improvement of bending capability.

Type of Medium: Online Resource

ISSN: 1087-1357 , 1528-8935

URL: Article

DOI: 10.1115/1.4040914

Language: English

Publisher: ASME International

Publication Date: 2018

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Three-Dimensional Numerical Simulation and Experimental Study of Sheet Metal Bending by Laser Peen Forming

Hu, Yongxiang ; Han, Yefei ; Yao, Zhenqiang ; [et al.]

ASME International ; 2010

In: Journal of Manufacturing Science and Engineering Vol. 132, No. 6 ( 2010-12-01)

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In: Journal of Manufacturing Science and Engineering, ASME International, Vol. 132, No. 6 ( 2010-12-01)

Abstract: Laser peen forming (LPF) is a purely mechanical forming method achieved through the use of laser energy to form complex shapes or to modify curvatures. It is flexible and independent of tool inaccuracies that result from wear and deflection. Its nonthermal process makes it possible to form without material degradation or even improve them by inducing compressive stress over the target surface. In the present study, a fully three-dimensional numerical model is developed to simulate the forming process of laser peen forming. The simulation procedure is composed of several steps mainly including the shock pressure prediction, the modal analysis, and the forming process calculation. System critical damping is introduced to prevent unnecessary long post-shock residual oscillations and to greatly decrease the solution time for simulation. The bending profiles and angles with different thicknesses are experimentally measured at different scanning lines and scanning velocities to understand the process and validate the numerical model. The calculated bending profiles and angles agree well with the trend of the measured results. But it is found that simulations with the Johnson–Cook model are more consistent, matching the experimental results for the thick sheet metal with a convex bending, while the elastic-perfectly-plastic model produces a better agreement even though with underestimated values for the thinner sheet metal with a concave bending. The reason for this phenomenon is discussed, combining the effects of strain rate and feature size. Both the simulation and the experiments show that a continuous decrease in bending angle from concave to convex is observed with increasing specimen thickness in general. Large bending distortion is easier to induce by generating a concave curvature with LPF, and the angle of bending distortion depends on the number of laser shocks.

Type of Medium: Online Resource

ISSN: 1087-1357 , 1528-8935

URL: Article

DOI: 10.1115/1.4002585

Language: English

Publisher: ASME International

Publication Date: 2010

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Shape Prediction for Laser Peen Forming of Fiber Metal Laminates by Experimentally Determined Eigenstrain

Zhang, Zhengyu ; Hu, Yongxiang ; Yao, Zhenqiang

ASME International ; 2017

In: Journal of Manufacturing Science and Engineering Vol. 139, No. 4 ( 2017-04-01)

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In: Journal of Manufacturing Science and Engineering, ASME International, Vol. 139, No. 4 ( 2017-04-01)

Abstract: Laser peen forming (LPF) is a promising method to fabricate fiber metal laminates (FMLs) with its design flexibility to produce complex shapes. Eigenstrain-based modeling is a helpful method to predict deformation after LPF, while determining eigenstrain is very difficult because of its complex constituents and high-dynamic loading of process. An effective experiment-based method is proposed in this work to obtain eigenstrain induced by LPF in metal layers of FMLs. An analytical beam model is developed to relate the deflection profile generated by specific scanning strategy to equivalent bending moment. Based on the determined bending moment from the measured deflection profiles, the generated eigenstrain can be inversely calculated by the proposed beam model describing the relationship between the eigenstrain and the bending moment. Chemical etching to remove sheets layer by layer is used to obtain the relaxed deflection profile to calculate the eigenstrain in each metal layer. Furthermore, an approximate model of plate is established to predict deformation after LPF based on determined eigenstrain. The results show that the predictive deformed shape agrees very well with both experiments and finite model prediction.

Type of Medium: Online Resource

ISSN: 1087-1357 , 1528-8935

URL: Article

DOI: 10.1115/1.4034891

Language: English

Publisher: ASME International

Publication Date: 2017

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