A novel cooling and lubrication approach: Device development and machining performance evaluation of ultrasonic vibration–assisted MQL

Minimum quantity lubrication (MQL) as a sustainable technology has gained popularity in addressing the conflict between environmental protection and the machining requirements during cutting processes. However, conventional MQL systems employ pneumatic atomization, resulting in the generation of oil...

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Bibliographic Details
Published inInternational journal of advanced manufacturing technology Vol. 133; no. 3-4; pp. 1667 - 1684
Main Authors Zhang, Minxiu, Wu, Bangfu, Zhao, Biao, Ding, Wenfeng, Cui, Hailong
Format Journal Article
LanguageEnglish
Published London Springer London 01.07.2024
Springer Nature B.V
Subjects
Air cooling
Atomizing
CAE) and Design
Computer-Aided Engineering (CAD
Cooling
Cutting equipment
Cutting force
Cutting parameters
Design parameters
Droplets
Engineering
Environmental protection
High strength steels
Industrial and Production Engineering
Lubrication
Machining
Mechanical Engineering
Media Management
Original Article
Particle size distribution
Performance evaluation
Surface roughness
Topography
Ultrasonic testing
Ultrasonic vibration
Workpieces
Surface topography
Chip morphology
Cutting temperature
Ultrasonic vibration–assisted MQL device
Cutting force
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Summary:Minimum quantity lubrication (MQL) as a sustainable technology has gained popularity in addressing the conflict between environmental protection and the machining requirements during cutting processes. However, conventional MQL systems employ pneumatic atomization, resulting in the generation of oil droplets with large particle sizes and uneven distribution, eventually leading to the inadequate lubrication performance of the MQL jet. In this case, the present study employed a combination of ultrasonic atomization and MQL technique to propose a novel cooling and lubrication approach and fabricate the ultrasonic vibration–assisted MQL (UVMQL) device. Geometric parameters of the ultrasonic vibrator of this device were designed and optimized using the theoretical design and finite element simulation techniques. Additionally, the impedance and amplitude detected to evaluate the performance of the UVMQL device. Subsequently, the comparative experiments were carried out under five cooling and lubrication conditions in machining of ultra-high strength steels: dry cutting, wet cutting, high-pressure air cooling, MQL, and UVMQL. Then, the machining performance of the UVMQL was discussed, in terms of cutting forces, cutting temperature, surface roughness, surface topography, and chips. Results demonstrate that in comparison to MQL, UVMQL has a lower cutting force by 5.3 N, leading to the formation of a more effective oil film lubrication layer. Due to the excellent penetration of fine oil droplets, UVMQL possesses a slightly higher cutting temperature than that of wet cutting by 43 °C, whereas results in optimal surface roughness value ( R a = 0.3 µm) and surface topography of the workpiece. Additionally, under UVMQL condition, the length of chip bonding zone is reduced by 39.8%, and the sawtooth height of chip is decreased by 35.9% compared to dry cutting.
ISSN:0268-3768
1433-3015
DOI:10.1007/s00170-024-13832-0