Relationship among Welding Defects with Convection and Material Flow Dynamic Considering Principal Forces in Plasma Arc Welding

The material flow dynamic and velocity distribution on the melted domain surface play a crucial role on the joint quality and formation of welding defects. In this study, authors investigated the effects of the low and high currents of plasma arc welding on the material flow and thermodynamics of molten pool and its relationship to the welding defects. The high-speed video camera (HSVC) was used to observe the convection of the melted domain and welded-joint appearance. Furthermore, to consider the Marangoni force activation, the temperature on the melted domain was measured by a thermal HSVC. The results revealed that the velocity distribution on the weld pool surface was higher than that inside the molten weld pool. Moreover, in the case of 80 A welding current, the convection speed of molten was faster than that in other cases (120 A and 160 A). The serious undercut and humping could be seen on the top surface (upper side) and unstable weld bead was visualized on the back side (bottom surface). In the case of 160 A welding current, the convection on the weld pool surface was much more complex in comparison with 80 A and 120 A cases. The excessive convex defect at the bottom side and the concave defect at the top surface were observed. In the case of 120 A welding current, two convection patterns with the main flow in the backward direction were seen. Almost no welding defect could be found. The interaction between the shear force and Marangoni force played a solid state on the convection and heat transportation processes in the plasma arc welding process.

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Relationship Among Welding Defects with Convection and Material Flow Dynamic Considering Principal Forces in Plasma Arc Welding

10.20944/preprints202107.0701.v1 ◽

2021 ◽

Author(s):

Loc Nguyen ◽

Anh Nguyen Van ◽

Han Le Duy ◽

Thanh-Hai Nguyen ◽

Shinichi Tashiro ◽

...

Keyword(s):

Velocity Distribution ◽

Material Flow ◽

Arc Welding ◽

Welding Current ◽

Plasma Arc Welding ◽

Plasma Arc ◽

Flow Dynamic ◽

Welding Defects ◽

Marangoni Force ◽

The Difference

The material flow dynamic and velocity distribution on the melted domain surface play a crucial role on the joint quality and formation of welding defects. In this study, authors investigated the effects of the low and high currents of plasma arc welding on the material flow and thermodynamics of molten pool and its relationship to the welding defects. The high-speed video camera (HSVC) was used to observe the convection of the melted domain and welded-joint appearance. Furthermore, to consider the Marangoni force activation, the temperature on the melted domain was measured by a thermal HSVC. The results revealed that the velocity distribution on the weld surface was higher than that inside the molten weld pool due to the difference of the massive density between the air and the steel. Moreover, in the case of low welding current (80A) the convection speed of molten was faster than that of the high welding current case (160A) owing to the difference of main driving forces direction and strength, which leading to undercut and humping defects on the weld surface and excessive convex (burn-through) defect at the bottom weld side, respectively. The medium welding current (120A) had two convection patterns with the main flow in backward direction, which resulted in better welding quality without defect. The interaction between the shear force and Marangoni force played a solid state on the convection and heat transportation processes in the plasma arc welding process.

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Material Flow Behavior on Weld Pool Surface in Plasma Arc Welding Process Considering Dominant Driving Forces

Applied Sciences ◽

10.3390/app10103569 ◽

2020 ◽

Vol 10 (10) ◽

pp. 3569 ◽

Cited By ~ 2

Author(s):

Manh Ngo Huu ◽

Anh Nguyen Van ◽

Tuan Nguyen Van ◽

Dang Tran Hai ◽

Thanh Nguyen Van ◽

...

Keyword(s):

Weld Pool ◽

Material Flow ◽

Arc Welding ◽

Shear Force ◽

Driving Forces ◽

Flow Behavior ◽

Shielding Gas ◽

Pool Surface ◽

Marangoni Force ◽

Weld Pool Surface

In this study, the effect of oxygen in the shielding gas on the material flow behavior of the weld pool surface was discussed to clarify the dominant driving weld pool force in keyhole plasma arc welding (KPAW). To address this issue, the convection flow on the top surface of weld pool was observed using a high-speed video camera. The temperature distribution on the surface along keyhole wall was measured using the two-color pyrometry method to confirm the Marangoni force activity on the weld pool. The results show that the inclination angle of the keyhole wall (keyhole shape) increased especially near the top surface due to the decrease in the surface tension of weld pool through surface oxidation when a shielding gas of Ar + 0.5% O2 was used. Due to the change in the keyhole shape, the upward and backward shear force compositions created a large inclination angle at the top surface of the keyhole. From the temperature measurement results, the Marangoni force was found to alter the direction when 0.5% O2 was mixed with the shielding gas. The shear force was found to be the strongest force among the four driving forces. The buoyant force and Lorentz force were very weak. The Marangoni force was stronger than the Lorentz force but was weaker than shear force. The interaction of shear force and Marangoni force controlled the behavior and speed of material flow on the weld pool surface. A strong upward and backward flow was observed in the case of mixture shielding gas, whereas a weak upward flow was observed for pure Ar. The heat transportation due to the weld pool convection significantly changed when only a small amount of oxygen was admixed in the shielding gas. The results can be applied to control the penetration ratio in KPAW.

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Weld Pool and Keyhole Detection Based on Visual Sensors in Plasma Arc Welding

Applied Mechanics and Materials ◽

10.4028/www.scientific.net/amm.536-537.309 ◽

2014 ◽

Vol 536-537 ◽

pp. 309-313

Author(s):

Wen Jian Ren ◽

Xin Feng Liu ◽

Jin Qiang Gao

Keyword(s):

Weld Pool ◽

Arc Welding ◽

Welding Current ◽

Observation System ◽

Welding Parameters ◽

Plasma Arc Welding ◽

Plasma Arc ◽

Ccd Cameras ◽

Keyhole Behavior ◽

Observation Results

An observation system is developed with three ordinary industrial CCD cameras to capture the images of the weld pool and the keyhole. Experiments are conducted to evaluate the affecting relationship between welding parameters (welding current and welding speed) and the size of weld pool and keyhole. The observation results lay foundation to understand the weld pool and the keyhole behavior in PAW process and to design the future control system.

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Numerical Analysis of Keyhole and Weld Pool Behaviors in Ultrasonic-Assisted Plasma Arc Welding Process

Materials ◽

10.3390/ma14030703 ◽

2021 ◽

Vol 14 (3) ◽

pp. 703

Author(s):

Junnan Qiao ◽

Chuansong Wu ◽

Yongfeng Li

Keyword(s):

Shear Stress ◽

Weld Pool ◽

Arc Welding ◽

Acoustic Radiation ◽

Radiation Force ◽

Acoustic Radiation Force ◽

Plasma Arc Welding ◽

Plasma Arc ◽

Arc Pressure ◽

Ultrasonic Assisted

The acoustic radiation force driving the plasma jet and the ultrasound reflection at the plasma arc-weld pool interface are considered to modify the formulas of gas shear stress and plasma arc pressure on the anode surface in ultrasonic-assisted plasma arc welding (U-PAW). A transient model taking into account the dynamic changes of heat flux, gas shear stress, and arc pressure on the keyhole wall is developed. The keyhole and weld pool behaviors are numerically simulated to predict the heat transfer and fluid flow in the weld pool and dynamic keyhole evolution process. The model is experimentally validated. The simulation results show that the acoustic radiation force increases the plasma arc velocity, and then increases both the plasma arc pressure and the gas shear stress on the keyhole wall, so that the keyholing capability is enhanced in U-PAW.

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A novel electrode-arc-weld pool model for studying the keyhole formation in the keyhole plasma arc welding process

Journal of Physics D Applied Physics ◽

10.1088/1361-6463/aafeb0 ◽

2019 ◽

Vol 52 (16) ◽

pp. 165203 ◽

Cited By ~ 9

Author(s):

Dongsheng Wu ◽

Shinichi Tashiro ◽

Xueming Hua ◽

Manabu Tanaka

Keyword(s):

Weld Pool ◽

Arc Welding ◽

Welding Process ◽

Plasma Arc Welding ◽

Plasma Arc ◽

Pool Model ◽

Arc Welding Process

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Experimental Analysis of Welding Parameters on Variable Polarity Plasma Arc Pressure

Advanced Materials Research ◽

10.4028/www.scientific.net/amr.651.355 ◽

2013 ◽

Vol 651 ◽

pp. 355-360 ◽

Cited By ~ 7

Author(s):

Yi Jiang ◽

Ming Liu ◽

Yao Hui Lu ◽

Bin Shi Xu

Keyword(s):

Arc Welding ◽

Gas Flow ◽

Welding Current ◽

Welding Parameters ◽

Plasma Arc Welding ◽

Plasma Arc ◽

Arc Pressure ◽

Variable Polarity ◽

Reversed Polarity ◽

Variable Polarity Plasma Arc

Variable polarity plasma arc welding has been widely used to manufacture industries. The effects of welding current and plasma gas flow as the most important parameters on variable polarity plasma arc pressure were discussed experimentally. To welding current, two experimental were designed to discuss the effects of straight polarity current and reversed polarity current on arc pressure respectively. It could be concluded that arc pressure is quadratic with welding current. To plasma gas flow, both experimental and numerical analysis are used to discuss the mechanisms of plasma gas flow to arc pressure, and it could be conclude that arc pressure is quadratic with plasma gas flow rather than linear.

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