A platform for research: civil engineering, architecture and urbanism
A platform for research: civil engineering, architecture and urbanism
Investigation on pulsed Nd:YAG laser welding of 49Ni–Fe soft magnetic alloy
Highlights ► In high temperature gradients, grains are oblong and coarse. ► Pulse overlap, duration time and focused beam diameter reduces penetration depth. ► Pulsed frequency increases heat input and decreases the penetration depth. ► Hot cracks produced due to weld pool shape and heat input induced during welding. ► Peak power density and pulse frequency determines weld crater and porosity.
Abstract Laser welding is one of the most popular methods for joining hot crack sensitive alloys and thin materials because of its low heat input and high heat intensity. In this study, a Nd:YAG pulsed micro laser machine with maximum 6J pulse energy was used for joining 49Ni–Fe soft magnetic alloy. Welding of samples was carried out autogenously by changing the pulse duration, focused beam diameter, voltage, frequency and welding speed. All samples were bead on plate welded. Scanning electron microscopy (SEM), optical microscopy and microhardness measurements were used for survey of results. Results show that weld bead size and grain size increase with voltage and heat input increase with pulse frequency. However, weld penetration depth and weld craters reduce with pulse frequency. The study shows that the average peak power density and pulse frequency are two important parameters that results in the formation of weld crater and porosity in the weld zone. Formation of hot cracks in the weld metal depends on the weld pool shape. Cylindrical weld pools are sensitive to hot cracks. Therefore, in order to reduce hot cracks in the weld bead, it is necessary to decrease voltage and increase pulse duration time, focused beam diameter and pulse frequency.
Investigation on pulsed Nd:YAG laser welding of 49Ni–Fe soft magnetic alloy
Highlights ► In high temperature gradients, grains are oblong and coarse. ► Pulse overlap, duration time and focused beam diameter reduces penetration depth. ► Pulsed frequency increases heat input and decreases the penetration depth. ► Hot cracks produced due to weld pool shape and heat input induced during welding. ► Peak power density and pulse frequency determines weld crater and porosity.
Abstract Laser welding is one of the most popular methods for joining hot crack sensitive alloys and thin materials because of its low heat input and high heat intensity. In this study, a Nd:YAG pulsed micro laser machine with maximum 6J pulse energy was used for joining 49Ni–Fe soft magnetic alloy. Welding of samples was carried out autogenously by changing the pulse duration, focused beam diameter, voltage, frequency and welding speed. All samples were bead on plate welded. Scanning electron microscopy (SEM), optical microscopy and microhardness measurements were used for survey of results. Results show that weld bead size and grain size increase with voltage and heat input increase with pulse frequency. However, weld penetration depth and weld craters reduce with pulse frequency. The study shows that the average peak power density and pulse frequency are two important parameters that results in the formation of weld crater and porosity in the weld zone. Formation of hot cracks in the weld metal depends on the weld pool shape. Cylindrical weld pools are sensitive to hot cracks. Therefore, in order to reduce hot cracks in the weld bead, it is necessary to decrease voltage and increase pulse duration time, focused beam diameter and pulse frequency.
Investigation on pulsed Nd:YAG laser welding of 49Ni–Fe soft magnetic alloy
Ebrahimzadeh, Hossain (author) / Mousavi, Seyed Ali Asghar Akbari (author)
2012-01-19
9 pages
Article (Journal)
Electronic Resource
English
Investigation on pulsed Nd:YAG laser welding of 49Ni-Fe soft magnetic alloy
| British Library Online Contents | 2012
| British Library Online Contents | 2014
Pulsed Nd:YAG laser welding of Cu54Ni6Zr22Ti18 bulk metallic glass
| British Library Online Contents | 2007