| dc.description.abstract | This thesis presents the design and development of a Multipurpose Sieving Machine
aimed at improving material separation processes in various industries such as
construction, agriculture, and food processing. The primary goal of the project is to
create a machine that can efficiently sieve different types of materials, ranging from
fine powders to coarse aggregates, with high accuracy and minimal human
intervention.The Multipurpose Sieving Machine utilizes a vibratory sieving
mechanism that facilitates the separation of materials based on particle size. The
machine is equipped with a set of sieving screens, an electric motor, and an
adjustable gearbox system to ensure adaptability and efficiency for a wide range of
materials. The machine’s design prioritizes energy efficiency, ease of operation, and
cost-effectiveness.The methodology includes a comprehensive study of material
selection, machine design, and the construction of a prototype. Key considerations
include the durability of materials, operational stability, and the effectiveness of the
sieving process. Experimental tests were conducted to evaluate the machine's
performance in terms of throughput, separation quality, and operational time.Results
demonstrate that the Multipurpose Sieving Machine significantly enhances the
sieving process, offering faster separation with minimal error. The machine
performs well across different materials, demonstrating versatility and applicability
in both small-scale and large-scale operations. The study also highlights potential
improvements for future research, focusing on automation, precision sieving, and
incorporating advanced technologies.In conclusion, the Multipurpose Sieving
Machine provides a viable and efficient solution to material separation challenges
across multiple industries. It offers a balance between functionality, cost
effectiveness, and adaptability, ensuring its usefulness in diverse applications. | en_US |
