Modeling of MIG/MAG welding with experimental validation using an active contour algorithm applied on high speed movies

Planckaert, Jean-Pierre; Djermoune, El‐Hadi; Brie, David; Briand, Francis; Richard, F.

doi:10.1016/j.apm.2009.07.011

Cited by 32 publications

(12 citation statements)

References 12 publications

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“…Gas inert yang umumnya gas berbasis argon (pengelasan MIG) sedangkan gas aktif yang umumnya gas berbasis CO2 (pengelasan MAG) digunakan sebagai plasma untuk pencetus busur listrik dan sebagai gas pelindung untuk logam pada temperatur tinggi untuk menghidari kontaminasi dengan oksigen dan nitrogen. Generator pengelasan mensuplay energi listrik yang dibutuhkan untuk mencairkan logam dan pencetus busur dan menjaga kesinambungan aliran kawat dan benda kerja yang dilas [13]. Las SMAW adalah pengelasan dengan elektroda terbungkus dimana pelindung logam las adalah selaput pada elektroda, kekurangan dari las SMAW adalah pengelasannya yang potensi cacat las lebih besar karena pengaruh dari perlakukan elektroda seperti elektroda yang lembab dan harus dipanaskan, pengaruh coating dan panjang elektroda yang terbatas sehingga kurang efektif untuk proyek pengelasan, sedangkan las MAG elektrodanya merupakan gulungan tanpa ada pembungkus dengan menggunakan gas sebagai pelindung sehingga elektrodanya mudah dalam penggunaannya, dan bisa mengelas tanpa pergantian elektroda seperti SMAW untuk pengelasan material ukuran panjang.…”

Section: Metode Penelitianunclassified

Untitled

Azwinur¹,

Yudi²,

Zulkifli

2020

Jurnal POLIMESIN

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Temperatur media pendingin merupakan substansi yang berfungsi untuk menentukan kecepatan proses pendinginan terhadap material yang telah diberikan perlakuan panas dari hasil pengelasan. Pendinginan menjadi salah satu alternatif untuk memperbaiki dan meningkatkan sifat mekanik pada material pasca pengelasan. Pemilihan temperatur media pendingin sangatlah penting untuk mendapatkan kekuatan sambungan yang baik. Tujuan penelitian ini untuk mengetahui pengaruh media pendingin terhadap kekerasan dan ketangguhan sambungan material AISI 1050 menggunakan proses las MAG. Media pendingin yang divariasi adalah air biasa, air laut, dan udara. Proses las yang digunakan adalah proses las MAG (Metal active gas) dengan gas pelindung CO 2 , material yang digunakan jenis AISI 1050 dengan pengujian mekanik uji kekerasan dan impak. Hasil penelitian menunjukkan bahwa penggunaan jenis media pendingin mempengaruhi kekuatan sambungan pengelasan dari segi nilai kekerasan dan ketangguhan material menerima beban. Nilai kekerasan tertinggi pada daerah HAZ 1, HAZ 2 dan weld metal terjadi pada penggunaan media pendingin air laut dimana pada HAZ 1 sebesar 71, 63, HAZ 2 sebesar 73,5 dan weld metal sebesar 70, sedangkan nilai terendah pada penggunaan media pendingin udara dimana pada HAZ 1 sebesar 65,63, HAZ 2 sebesar 63,75 dan weld metal sebesar 58,83. Hasil pengujian ketangguhan impak didapatkan bahwa pada penggunaan media pendingin air laut mempunyai nilai ketangguhan yang tertinggi sebesar 1,83 joule/mm², kemudian diikuti dengan media udara sebesar 1,75 joule/mm², dan yang terendah pada penggunaan air biasa sebesar 1,50 joule/mm². Kata Kunci: media pendingin, las MAG, gas CO 2 , kekerasan, ketangguhan The effect of cooling media on the hardness and toughness of AISI 1050 material in the MAG welding process

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Section: Metode Penelitianunclassified

Untitled

Azwinur¹,

Yudi²,

Zulkifli

2020

Jurnal POLIMESIN

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“…Efforts are focused on addressing the phenomena involved at the metal transfer time during a short circuit. The model presented takes as reference the work developed by Doodman [18] and Planckaert et al [12] and considers its application for orbital welding.…”

Section: Gmaw-s Model Processmentioning

confidence: 99%

“…3into the current I that flows through the drop, we obtain Eq. (4) corresponding to the electromagnetic force; 0 is magnetic permeability ( 4 × 10 −7 N/A 2 ), r d the droplet radius, r e is the electrode radius, and f z is the variable term of the electromagnetic force [12,19] as indicated in Eq. (5).…”

Section: Model To Arc Periodmentioning

confidence: 99%

“…where corresponds to the linear resistivity and C 1 and C 2 are constants that describe the electrode heating, as results of arc heating and the Joule effect, respectively [12].…”

Section: Model To Arc Periodmentioning

confidence: 99%

“…In the same year, Modenesi et al [11] developed a numerical model to calculate the temperature along the electrode during GMAW-S welding. Planckaert et al [12] presented a study proposing a training and mass transfer model for the GMAW-S process in which the authors emphasize the need to use different models for both the short circuit and the arc phase in the metal transfer cycle. Modenesi et al and Zuo et al [11,13,14] presented a mathematical model capable of simulating the electrical aspects of GMAW-S welding.…”

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Modeling and simulation of the metal transfer on GMAW-S process

Meneses

Silva

Alfaro

2019

J Braz. Soc. Mech. Sci. Eng.

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The GMAW-S process occurs from sequences of arcing and short-circuit welding periods. For modeling purposes, many researchers believe that the metal transfer occurs only in the period of short circuit (consideration to be taken into account in the present work), in which the link between the electrode and the welding pool is generated through a liquid metal bridge. From this exact moment, it can be observed changes in the metal bridge geometry due to electromagnetic (pinch effect), gravitational, and surface tension forces. This paper is aimed to model the dynamic geometry of metal bridge during the shortcircuit period, considering the fusion and feed rate electrode wire balance. This model was represented by state equations building from applying Kirchoff's, Lorentz, Young-Laplace law, Bernoulli's principle, the equation of fluid continuity, and concepts of analytic geometry. The model implementation was developed in Simulink and could be used to study the metal transfer control, as well as, the appropriate welding parameters selection, aiming to achieve a higher level of welding quality.

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Dry hyperbaric welding of HSLA steel up to 35 bar ambient pressure with CMT arc mode

Bunaziv

Aune

Olden

et al. 2019

Int J Adv Manuf Technol

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Hyperbaric welding plays a significant role in subsea pipeline installations and repairs for transport of oil and gas from the offshore field to the market. The effect of ambient pressure, from 1 to 35 bar, on penetration depth and microstructure evolution in dry hyperbaric welding of X70 pipeline steel has been investigated. It was found that penetration depth is increasing with increased ambient pressure due to enhanced melt flow by using the cold metal transfer (CMT) arc mode. Increase ambient pressure lowered process stability causing more spattering strongly affecting current/voltage characteristics of the arc. Numerical simulation showed very fast cooling rate regardless ambient pressure effect causing hard microstructure. Application of lower alloyed wire provided lower hardenability and higher fraction of the allotriomorphic ferrite with high acicular ferrite volume fraction. Chemical analysis revealed positive effect of low oxygen/nickel with high silicon containing wire for acicular ferrite nucleation in weld metal at any process parameters due to higher activity of inclusions.

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Modeling of MIG/MAG welding with experimental validation using an active contour algorithm applied on high speed movies

Cited by 32 publications

References 12 publications

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Modeling and simulation of the metal transfer on GMAW-S process

Dry hyperbaric welding of HSLA steel up to 35 bar ambient pressure with CMT arc mode

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