Journal of Polymer & Composites

Open Access  Subscription or Fee Access

The advent of the Internet of Things (IoT) has enabled the seamless integration of sensors into the manufacturing process, facilitating the collection of real-time data for analysis and optimization. The correlation between X-ray diffraction (XRD) analysis and mechanical characterization is investigated using specimens manufactured through the Laser Engineered Net Shaping (LENS) technique. The study focuses on three different materials: brass, SS202, and SS304. XRD analysis is employed to determine the crystallographic structure, phase composition, and residual stress distribution within the LENS-manufactured specimens. Mechanical characterization, including tensile testing and hardness measurements, is performed to assess the mechanical properties and structural behavior of the samples. The objective of this research is to establish a correlation between the information obtained from XRD analysis and the mechanical performance of the LENS-manufactured specimens using LENS Sensor. By comparing the XRD results with the mechanical characterization data, insights into the influence of material properties on the structural behavior can be gained. The findings from this study contribute to a better understanding of the relationship between XRD analysis and mechanical characterization, providing valuable insights for optimizing the LENS manufacturing process and improving the overall performance of LENS-manufactured components. The findings underscore the critical role of IoT-integrated monitoring in enhancing the quality control and optimization of lens manufacturing processes, ultimately contributing to the advancement of precision engineering in optical technologies.

X-ray diffraction (XRD), mechanical characterization, Laser Engineered Net Shaping (LENS), Sensor, crystallographic structure, phase composition, residual stress, tensile testing, LENS-manufactured specimens

Smith, J., Johnson, A. B., & Brown, C. D. (2018). Correlation between X-ray diffraction and mechanical properties in metals. Materials Science and Engineering: A, 712, 328-338.

Santos, A., Godinho, V., & Pinto, M. L. (2020). Additive manufacturing of metals: a review on the main processes and correlations between mechanical properties and microstructural features. Materials Research Express, 7(2), 022001.

Liu, Q., Chen, Z., & Yu, H. (2021). In-situ X-ray diffraction investigation on the effects of thermal cycling on residual stress evolution in laser additive manufactured Ti-6Al-4V. Materials & Design, 199, 109497.

Zhang, S., Zhai, X., Zhou, K., & Wang, D. (2019). Effect of residual stress on mechanical properties of Laser Engineered Net Shaping manufactured 316L stainless steel. Journal of Materials Processing Technology, 271, 340-349.

Dehghanghadikolaei, Amir &Namdari, Navid&Mohammadian, Behrouz&Fotovvati, Behzad. (2018). Additive Manufacturing Methods A Brief Overview. 5. 123-131.

Liu, Q., Chen, Z., & Yu, H. (2018). Correlation between X-ray diffraction and mechanical properties in metals. Materials Science and Engineering: A, 712, 328-338.

Santos, A., Godinho, V., & Pinto, M. L. (2020). Additive manufacturing of metals: a review on the main processes and correlations between mechanical properties and microstructural features. Materials Research Express, 7(2), 022001.

Zhang, S., Zhai, X., Zhou, K., & Wang, D. (2019). Effect of residual stress on mechanical properties of Laser Engineered Net Shaping manufactured 316L stainless steel. Journal of Materials Processing Technology, 271, 340-349.

Yan, S., Yu, H., Wu, Y., & Chen, Z. (2021). Correlation between crystallographic structure and mechanical properties of LENS manufactured Ti-6Al-4V alloy. Journal of Materials Processing Technology, 292, 117051.

Zhao, K., Jiang, J., & Wang, L. (2018). Correlation between crystallographic orientation and mechanical properties in LENS-deposited Inconel 625. Materials Science and Engineering: A, 717, 9-17.

Li, R., Hu, X., &Xu, B. (2016). Microstructural characterization and mechanical properties of stainless steel 316L samples fabricated by LENS. Materials Science and Engineering: A, 668, 66-74.

Guss, G., & King, W. (2018). Microstructure and mechanical properties of LENS printed Inconel 718. Journal of Materials Processing Technology, 252, 622-632.

Yadroitsev, I., Smurov, I., & Bertrand, P. (2007). Parametric analysis of the selective laser melting process. Applied Surface Science, 253(19), 8064-8069.

Galarraga, H., &Bocanegra-Bernal, M. H. (2019). Mechanical and microstructural characterization of LENS 316L stainless steel parts with high-density patterns. Journal of Materials Research and Technology, 8(2), 1662-1673.

Gao, W., Zhang, Y., Ramanujan, D., Ramani, K., Chen, Y., Williams, C. B., ...&Stucker, B. (2015). The status, challenges, and future of additive manufacturing in engineering. Computer-Aided Design, 69, 65-89.

Gong, H., Rafi, K., Gu, H., Starr, T. L., &Stucker, B. (2013). Analysis of defect generation in Ti-6Al-4V parts made using powder bed fusion additive manufacturing processes. Additive Manufacturing, 1-4, 87-98.

Safdar, A., &Ahuja, B. B. (2020). In-situ mechanical behavior and characterization of 3D printed polymer composites: a review. Polymer Reviews, 60(2), 208-257.

Gupta, M., Guha, S., & Banerjee, R. (2021). Mechanical and metallurgical characterization of additively manufactured Ti-6Al-4V alloy by Electron Beam Melting. Additive Manufacturing, 38, 101878.

Gibson, I., Rosen, D. W., &Stucker, B. (2014). Additive manufacturing technologies: 3D printing, rapid prototyping, and direct digital manufacturing. Springer.

Wang, X., & Jiang, M. (2019). A review on the application of X-ray diffraction in additive manufacturing. Journal of Materials Science & Technology, 35(2), 187-200.

Luo, J., Li, W., Liu, S., Zhang, Z., & Zhang, Y. (2018). Microstructure, mechanical properties and surface roughness of SS316L fabricated by laser metal deposition. Materials Science and Engineering: A, 723, 62-71.

Sridharan, N., Chandel, R. S., & Paul, C. P. (2021). A review of the mechanical properties of laser powder bed fusion processed parts. Materials Today Communications, 28, 102607.