| dc.description.abstract | This project focuses on the design and development of a double-acting power
hacksaw machine intended to improve cutting performance and reduce operation
time. Unlike conventional single-acting hacksaws, this double-acting design
enables cutting during both the forward and return strokes, effectively doubling
efficiency without notably increasing power usage. The machine employs a robust
crank and slider mechanism to convert rotary motion into linear reciprocating
action, delivering stable and consistent cutting operations. Key components include
the hacksaw blade unit, a driving motor, and a dual-action drive mechanism. This
setup significantly minimizes non-cutting strokes, enhancing material removal and
overall efficiency. The project also addresses essential mechanical considerations
such as material choice, motion analysis, and stress evaluation to ensure long term
durability and operational reliability. Designed with affordability and industrial
adaptability in mind, the machine supports large-scale usage. Test results confirm
the system’s efficiency, demonstrating a notable reduction in cutting time
compared to traditional designs. This innovation shows strong potential for
widespread use in industrial and workshop environments, promoting greater
productivity and energy savings. | en_US |
