Difference between revisions of "Projects:2019s2-20001 Using Machine Learning to Determine Deposit Height and Defects for Wire + Arc Additive Manufacture (3D printing)"

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[[Category:Final Year Projects]]
 
[[Category:Final Year Projects]]
 
[[Category:2019s2|24501]]
 
[[Category:2019s2|24501]]
Abstract here
 
 
== Introduction ==
 
== Introduction ==
3D  printing  is  an  emerging  technology  that  has  the  potential  to  significantly  reduce  material  usage  through  the production of near net-shape parts. Many of the systems for 3D printing are based on lasers and powders; however the  deposition  rate  with  such  systems  is  very  low  making  the  production  of  large-scale  parts  difficult. AML Technologies  specialises  in  the  use  of  Wire  +  Arc  Additive  Manufacture  (WAAM)  where  deposition  is  based  on  arc welding processes and the deposition rates are an order of magnitude greater. When building 3D printed parts, even a relatively small layer height error of only 0.1 mm can produce large build height errors when multiplied across the many layers of a typical build.  This can make path planning difficult, so in-process layer height measurement is an essential building block of any production 3D printing system. A variety of techniques can be used for monitoring the layer height including laser scanners, and arc monitoring.  It is the latter technique that will be explored in this project due to its robustness, and low cost of implementation – it only requires the measurement of arc current and voltage. Furthermore, it can potentially be used to detect defects by identifying waveform irregularities.  
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3D  printing  is  an  emerging  technology  that  has  the  potential  to  significantly  reduce  material  usage  through  the production of near net-shape parts. Many of the systems for 3D printing are based on lasers and powders; however the  deposition  rate  with  such  systems  is  very  low  making  the  production  of  large-scale  parts  difficult. AML Technologies  specialises  in  the  use  of  Wire  +  Arc  Additive  Manufacture  (WAAM)  where  deposition  is  based  on  arc welding processes and the deposition rates are an order of magnitude greater. When building 3D printed parts, even a relatively small layer height error of only 0.1 mm can produce large build height errors when multiplied across the many layers of a typical build.  This can make path planning difficult, so in-process layer height measurement is an essential building block of any production 3D printing system. A variety of techniques can be used for monitoring the layer height including laser scanners, and arc monitoring.  It is the latter technique that will be explored in this project due to its robustness, and low cost of implementation – it only requires the measurement of arc current and voltage. Furthermore, it can potentially be used to detect defects by identifying waveform irregularities. This project is sponsored by AML3D.
 
=== Project team ===
 
=== Project team ===
 
==== Project students ====
 
==== Project students ====
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* Dr. Paul Colegrove (AML3D)
 
* Dr. Paul Colegrove (AML3D)
  
[[File:aml3d_logo.jpg]]
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== References ==
=== Objectives ===
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[1] a, b, c, "Simple page", In Proceedings of the Conference of Simpleness, 2010.
The objective of this project is to increase the efficiency of the manufacture process at AML3D. In order to do so, the team will investigate into the possibility of automating and optimising the quality control processes. The two quality control processes that are currently being implemented at AML3D are measuring layer height using laser sensors, and human supervision for detecting defects. These processes add overhead into production time and usage of human resource, which is not desired. To achieve the goal, it is expected that machine learning methods will be used extensively to analyse the electrical signatures of the weld process.
 
 
 
== Background ==
 
=== Wire Arc Additive Manufacturing ===
 
Wire and Arc Additive Manufacturing (WAAM) is a type of additive manufacturing that uses electric arc as the heat source and material wire to feed the manufacture process <ref name="WAAM"> S. W. Williams, F. Martina, A. C. Addison, J. Ding, G. Pardal & P. Colegrove (2016) Wire + Arc Additive Manufacturing, Materials Science and Technology, 32:7, 641-647, DOI: 10.1179/1743284715Y.0000000073 </ref>. WAAM has been investigated since the 1990s <ref name="WAAM" />, but only recently that it received more attention from the manufacture world.
 
 
 
Its significant comes from the ability to manufacture complex model with less time and less material. Figure 1a and 1b show real parts that was manufactured by AML3D. Such custom made parts might takes months before be ready to be shipped, but with WAAM, the production time can reduce down to weeks. Currently, the industries that benefit the most from WAAM are maritime and aerospace.
 
 
 
Similar to other additive manufacture methods, WAAM achieves such results by sliding the models into multiple layers, and then build the model layer by layer. The movement control is normally handled by a robotic arm (AML3D uses ABB's Arc Welder robot), and the welding path is generated by a Computer Aid Manufacture (CAM) software.
 
 
 
[[File:welding_part1.JPG|thumb|Figure 1a: A propeller]]
 
[[File:welding_part2.jpg|thumb|Figure 1b: Another part of the ship]]
 
[[File:abb_robot.jpg|thumb|Figure 2: ABB's IRB 1520ID Arc Welder]]
 
 
 
=== Gas metal arc welding (GMAW) ===
 
 
 
==== Pulse Arc Welding ====
 
 
 
==== Cold Metal Transfer ====
 
 
 
=== Machine Learning ===
 
 
 
==== Support Vector Machine ====
 
  
== Method ==
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[2] ...
 
 
== Results ==
 
 
 
== Conclusion ==
 
 
 
== References ==
 
<references />
 

Latest revision as of 12:15, 2 June 2020

Introduction

3D printing is an emerging technology that has the potential to significantly reduce material usage through the production of near net-shape parts. Many of the systems for 3D printing are based on lasers and powders; however the deposition rate with such systems is very low making the production of large-scale parts difficult. AML Technologies specialises in the use of Wire + Arc Additive Manufacture (WAAM) where deposition is based on arc welding processes and the deposition rates are an order of magnitude greater. When building 3D printed parts, even a relatively small layer height error of only 0.1 mm can produce large build height errors when multiplied across the many layers of a typical build. This can make path planning difficult, so in-process layer height measurement is an essential building block of any production 3D printing system. A variety of techniques can be used for monitoring the layer height including laser scanners, and arc monitoring. It is the latter technique that will be explored in this project due to its robustness, and low cost of implementation – it only requires the measurement of arc current and voltage. Furthermore, it can potentially be used to detect defects by identifying waveform irregularities. This project is sponsored by AML3D.

Project team

Project students

  • Anh Tran
  • Nhat Nguyen

Supervisors

  • Dr. Brian Ng
  • Dr. Paul Colegrove (AML3D)

References

[1] a, b, c, "Simple page", In Proceedings of the Conference of Simpleness, 2010.

[2] ...

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