Laser Doppler in Green Compact Density Inspection of Powder Metallurgy

Wang Yuan; Wang Po Yung; Huang Yun Ju; Yang Kang Hung; Chiu Sheng Kuei; Chen Chin Yi

doi:10.4028/p-Wlpol7

Paper Titles

Corrosion Resistance Enhancement of Reinforced Concrete in Marine Environment by Partial Replacement of Black Rice Husk Ash
p.137

Characterization of Coconut Husk Ash as Potential Substitute for Fly Ash in Geopolymer Concrete
p.145

Analysis of the Effect of Slenderness Ratio on Nominal Moment in T Section
p.155

Lateral Torsional Buckling Strength Analysis of Single Symmetric I-Beam Section
p.161

Air Preheater Performance Analysis: Installation of Soft Seal Material to Improve Air Preheater Leakage
p.169

Effects of Holding Time and Temperature of Creasing Knife on Crease Bending Characteristics of Milk Carton Subjected to Indentation of Flat-Edge Creasing Knife
p.179

An Accurate Detection and Location of Weld Surface Defect Based on Laser Vision
p.197

Research on the Repair Quality of Crack in Concrete Structures by Stress Waves
p.209

Laser Doppler in Green Compact Density Inspection of Powder Metallurgy
p.215

HomeKey Engineering MaterialsKey Engineering Materials Vol. 963Laser Doppler in Green Compact Density Inspection...

Laser Doppler in Green Compact Density Inspection of Powder Metallurgy

Abstract:

The density of green compact in powder metallurgy (PM) is a critical characteristic to determine the strength and tenacity of the product. Due to the fragility and sensitivity to the humidity of green compact, detection method triggers by knocking or immersion cannot be applied. Current inspection method for green compact is to use a densitometer with Archimedes Principle, which has to immerse green compact into water. This action considers a destructive test due to the porosity of the PM product, and the oxidation reaction of metal particles inside products cannot be controlled. Since the current detection method is destructive, most of the inspection on forming process of PM only complies after setup of compaction machine. The next non-destructive test is executed after sintering, such as Acoustic emission testing (AE) and Magnetic Testing (MT), which require a solid object for knocking or liquid immersion. To reduce defective compaction flow into the manufacturing process, a Non-destructive test in forming process is a prerequisite. Laser Doppler Vibrometer (LDV) takes advantage of measuring without damaging the test object and obtaining characteristic spectrum signal from the sample for further analysis, which is preferable for green compact of PM. The LDV test setup included a Polytec PSV-400 scanning laser vibrometer with a crystal resonator attached to the test product to generate reference vibration. Integrate spectrum in the frequency range 0 - 5000 Hz was recorded from 30 points of an annular pattern. Comparison of the spectrum and statistical analysis from defective specimens demonstrate that velocity increases within a specific frequency, which is different from with normal samples. Increases in velocity refer to uneven density distribution with an absence of particles inside product decline. The study approves the possibility of density detection in green compact using an LDV. Further studies aim to construct a relational model of specimen and compaction machine and determine a fundamental database for Advance Process Control (APC) of forming process in PM.

You might also be interested in these eBooks

7th International Conference on Material Engineering and Manufacturing & 6th International Conference on Materials Design and Applications

View Preview

View Preview

Info:

Periodical:

Key Engineering Materials (Volume 963)

Pages:

215-222

DOI:

https://doi.org/10.4028/p-Wlpol7

Citation:

Cite this paper

Online since:

October 2023

Authors:

Wang Yuan*, Wang Po Yung, Huang Yun Ju, Yang Kang Hung, Chiu Sheng Kuei, Chen Chin Yi

Keywords:

Density, Laser Doppler Vibrometer, Non-Destructive Test, Powder Metallurgy

Export:

RIS, BibTeX

Price:

Permissions CCC:

Request Permissions

Permissions PLS:

Request Permissions

Сopyright:

Citation:

* - Corresponding Author

References

[1] Angelo, P., Subramanian, R., & Ravisankar, B. (2022). Powder metallurgy: science, technology and applications. PHI Learning Pvt. Ltd.

Google Scholar

[2] Araoyinbo, A., Ishola, F., Salawu, E., Biodun, M., & Samuel, A. (2022). Overview of powder metallurgy process and its advantages. AIP Conference Proceedings

DOI: 10.1063/5.0092502

Google Scholar

[3] Bank, G., & Hathaway, G. (1980). A revolutionary 3-D interferometric vibrational mode display. Audio Engineering Society Convention 66

Google Scholar

[4] Bogy, D., Bouchard, G., Chang, W.-R., & Talke, F. (1986). Use of the laser Doppler vibrometer to measure the surface topography of magnetic disks. Wear, 107(3), 227-244.

DOI: 10.1016/0043-1648(86)90227-9

Google Scholar

[5] Davis, Q. V., & Kulczyk, W. K. (1969). Vibrations of Turbine Blades measured by Means of a Laser. Nature, 222(5192), 475-476

DOI: 10.1038/222475a0

Google Scholar

[6] Du Plessis, A., MacDonald, E., Waller, J. M., & Berto, F. (2021). Non-destructive testing of parts produced by laser powder bed fusion. In Fundamentals of Laser Powder Bed Fusion of Metals (pp.277-300). Elsevier.

DOI: 10.1016/b978-0-12-824090-8.00016-0

Google Scholar

[7] Halliwell, N., Pullen, L., & Baker, J. (1983). Diesel engine health: laser diagnostics. SAE transactions, 986-994.

DOI: 10.4271/831324

Google Scholar

[8] Samal, P., & Newkirk, J. (2015). Powder metallurgy methods and applications. ASM handbook of powder metallurgy, 7.

Google Scholar

[9] Sawyer, S. F. (2009). Analysis of variance: the fundamental concepts. Journal of Manual & Manipulative Therapy, 17(2), 27E-38E.

DOI: 10.1179/jmt.2009.17.2.27e

Google Scholar

[10] Tatarinov, A., Kurtenoks, V., & Mironovs, V. (2021). Detection of cracks in green products of. powder metallurgy by means of laser vibrometry. IOP Conference Series: Materials Science and Engineering

DOI: 10.1088/1757-899x/1140/1/012045

Google Scholar