An in-process multi-feature data fusion nondestructive testing approach for wire arc additive manufacturing

Purpose The major problem that limits the widespread use of WAAM technology is the forming quality. However, most of the current research focuses on post-process detections that are time-consuming, expensive and destructive. This paper aims to achieve the on-line detection and classification of the common defects, including hump, deposition collapse, deviation, internal pore and surface slag inclusion. Design/methodology/approach This paper proposes an in-process multi-feature data fusion nondestructive testing method based on the temperature field of the WAAM process. A thermal imager is used to collect the temperature data of the deposition layer in real-time. Efficient processing methods are proposed in this paper, such as the temperature stack algorithm, width extraction algorithm and a classification model based on a residual neural network. Some features closely related to the forming quality were extracted, containing the profile image and width curve of the deposition layer and abnormal temperature features in longitudinal and cross-sections. These features are used to achieve the detection and classification of defects. Findings Thermal non-destructive testing is a potentially superior technology for in-process detection in the industrial field. Based on the temperature field, extracting the most relevant features of the defect information is crucial. This paper pushes current infrared (IR) monitoring methods toward real-time detection and proposes an in-process multi-feature data fusion non-destructive testing method based on the temperature field of the WAAM process. Originality/value In this paper, the single-layer and multi-layer WAAM samples are preset with various defects, such as hump, deposition collapse, deviation, pore and slag inclusion. A multi-feature nondestructive testing methodology is proposed to realize the in-process detection and classification of the defects. A temperature stack algorithm is proposed, which improves the detection accuracy of profile change and solves the problem of uneven temperature from arc striking to arc extinguishing. The combination of residual neural network greatly improves the accuracy and efficiency of detection.

[1]  L. Quintino,et al.  Non-destructive testing for wire + arc additive manufacturing of aluminium parts , 2019, Additive Manufacturing.

[2]  S. Pierce,et al.  Ultrasonic phased array inspection of a Wire + Arc Additive Manufactured (WAAM) sample with intentionally embedded defects , 2019, Additive Manufacturing.

[3]  Prahalada K. Rao,et al.  Heterogeneous sensor-based condition monitoring in directed energy deposition , 2019 .

[4]  Nikhil R. Pal,et al.  Artificial neural network approach for estimating weld bead width and depth of penetration from infrared thermal image of weld pool , 2008 .

[5]  Deyong You,et al.  WPD-PCA-Based Laser Welding Process Monitoring and Defects Diagnosis by Using FNN and SVM , 2015, IEEE Transactions on Industrial Electronics.

[6]  Zheng Chen,et al.  Porosity defect detection based on FastICA-RBF during pulsed TIG welding process , 2017, 2017 13th IEEE Conference on Automation Science and Engineering (CASE).

[7]  Guilan Wang,et al.  End lateral extension path strategy for intersection in wire and arc additive manufactured 2319 aluminum alloy , 2019, Rapid Prototyping Journal.

[8]  Ryan R. Dehoff,et al.  Effect of Process Control and Powder Quality on Inconel 718 Produced Using Electron Beam Melting , 2014 .

[9]  Xiaoyan Zeng,et al.  Laser opto-ultrasonic dual detection for simultaneous compositional, structural, and stress analyses for wire + arc additive manufacturing , 2020 .

[10]  Wang Guilan,et al.  HDMR technology for the aircraft metal part , 2016 .

[11]  Yellapu V. Murty,et al.  In situ defect detection in selective laser melting via full-field infrared thermography , 2018, Additive Manufacturing.

[12]  Bintao Wu,et al.  A review of the wire arc additive manufacturing of metals: properties, defects and quality improvement , 2018, Journal of Manufacturing Processes.

[13]  Geoffrey E. Hinton,et al.  Rectified Linear Units Improve Restricted Boltzmann Machines , 2010, ICML.

[14]  Jun Xiong,et al.  Forming appearance control of arc striking and extinguishing area in multi-layer single-pass GMAW-based additive manufacturing , 2016 .

[15]  Runsheng Li,et al.  Investigation, modeling and optimization of abnormal areas of weld beads in wire and arc additive manufacturing , 2020 .

[16]  Sadek Crisóstomo Absi Alfaro,et al.  Characterization of “Humping” in the GTA welding process using infrared images , 2015 .

[17]  Yaoyu Ding,et al.  Process Development for a Robotized Laser Wire Additive Manufacturing , 2017 .

[18]  Ying Zhang,et al.  3D-printing process design of lattice compressor impeller based on residual stress and deformation , 2020, Scientific Reports.

[19]  Michael Towrie,et al.  In situ X-ray imaging of defect and molten pool dynamics in laser additive manufacturing , 2018, Nature Communications.

[20]  K. P. Karunakaran,et al.  Low cost integration of additive and subtractive processes for hybrid layered manufacturing , 2010 .

[21]  Fanrong Kong,et al.  A review on wire-arc additive manufacturing: typical defects, detection approaches, and multisensor data fusion-based model , 2021, The International Journal of Advanced Manufacturing Technology.

[22]  Guoming Chen,et al.  Improving defect visibility in square pulse thermography of metallic components using correlation analysis , 2018 .

[24]  Shujun Chen,et al.  Process planning strategy for wire-arc additive manufacturing: Thermal behavior considerations , 2020 .

[25]  D. Howard,et al.  Synthesis of a Vocal Sound from the 3,000 year old Mummy, Nesyamun ‘True of Voice’ , 2020, Scientific Reports.

[26]  Shian Gao,et al.  Revealing internal flow behaviour in arc welding and additive manufacturing of metals , 2018, Nature Communications.

[27]  Wang Guilan,et al.  Optimization of surface appearance for wire and arc additive manufacturing of Bainite steel , 2017 .

[29]  Satoshi Kishimoto,et al.  Evaluation of 3D-Printed titanium alloy using eddy current testing with high-sensitivity magnetic sensor , 2019, NDT & E International.

[30]  José Pedro Sousa,et al.  Non-destructive testing application of radiography and ultrasound for wire and arc additive manufacturing , 2018 .

[31]  Hongkun Wu,et al.  Damage detection techniques for wind turbine blades: A review , 2020 .

[32]  Xizhang Chen,et al.  A Review and Preliminary Experiment on Application of Infrared Thermography in Welding , 2014 .

[33]  Ricardo J. Miragaia,et al.  A rapid and robust method for single cell chromatin accessibility profiling , 2018, Nature Communications.

[34]  Baldev Raj,et al.  Estimating bead width and depth of penetration during welding by infrared thermal imaging , 2005 .