Authors :
V. Priyadharshan; R.Surendran; Dr. T.Sekar; D.Ajithkumar
Volume/Issue :
Volume 8 - 2023, Issue 7 - July
Google Scholar :
https://bit.ly/3TmGbDi
Scribd :
https://tinyurl.com/yc3r249r
DOI :
https://doi.org/10.5281/zenodo.8289193
Abstract :
A rotating dynamometer that can detect static
and dynamic cutting forces utilizing a strain gauge and a
piezo-electric accelerometer was invented and developed
in this work. The alignment of octagonal rings and strain
gauge sites has been chosen to enhance sensitivity while
minimizing cross-sensitivity. A data collecting system is
linked to the designed dynamometer. Cutting force
signals were recorded, converted to numerical form, and
processed utilizing a data collection system comprised
of required hardware and software operatingon an MS-
Windows-based personal computer. The results of
machining experiments performed at various cutting
settings demonstrated that the dynamometer could be
used to reliably measure cutting forces. The
dynamometer was designed primarily for turning
activities, although it may also be used to measure
cutting forces.
A rotating dynamometer that can detect static
and dynamic cutting forces utilizing a strain gauge and a
piezo-electric accelerometer was invented and developed
in this work. The alignment of octagonal rings and strain
gauge sites has been chosen to enhance sensitivity while
minimizing cross-sensitivity. A data collecting system is
linked to the designed dynamometer. Cutting force
signals were recorded, converted to numerical form, and
processed utilizing a data collection system comprised
of required hardware and software operatingon an MS-
Windows-based personal computer. The results of
machining experiments performed at various cutting
settings demonstrated that the dynamometer could be
used to reliably measure cutting forces. The
dynamometer was designed primarily for turning
activities, although it may also be used to measure
cutting forces.
