Electromechanical Design
Welcome! On this page, you can explore my diverse collection of electromechanical design projects. Spanning personal endeavors, research activities, and academic pursuits, these projects showcase my creative thinking, technical expertise, and problem-solving skills. Delve into the concepts, decision-making process, and manufacturing details behind each project, revealing my passion for exploring the fascinating intersection of electrical and mechanical engineering.
CNC Mill Project
This project involves the fabrication of a Cartesian plotter designed to attach to a drill press, effectively converting it into a CNC mill. The primary focus encompasses various essential components, such as fabrication, machining, G code coding, 3D printing, collaborative work, manufacturing design, circuitry, and mechanical optimization. The aim is to construct a robust plotter that securely integrates with the drill press, enabling precise milling operations. G code programming will be utilized to control the plotter's movements, while circuitry may be incorporated for enhanced control and automation. Throughout the project, meticulous attention will be given to manufacturing design considerations, ensuring compliance with safety standards. Additionally, mechanical optimization will be a key aspect, striving to enhance the plotter's accuracy and reliability. The ultimate objective is to successfully transform the drill press into a functional CNC mill through the creation of the Cartesian plotter.
Cartesian Plotter
The goal of this project is to fabricate a Cartesian plotter capable of precise drawing and movement. The plotter utilizes a motor screw and bearings to control the Cartesian motion of the drawing tool. The project involves multiple stages, including assembly, calibration, and debugging of the mechanical components required for the plotter's operation. Additionally, G code programming will be utilized to enable accurate and controlled movements. Fabrication techniques will be employed to create custom parts and optimize the plotter's performance. The project focuses on refining skills in mechanical fabrication, motor control, G code programming, and debugging to achieve a functional Cartesian plotter.
Linear Plotter
The goal of this project is to fabricate a linear plotter capable of drawing precise linear lines. The plotter utilizes a motor screw and bearings to control the movement of the drawing tool. The project involves various stages, including the assembly and calibration of the mechanical components required for the plotter's operation. Additionally, coding using Arduino is implemented to program the motor control, enabling precise movements and line drawing. The project also entails an exploration of different types of motors and their functionality within the plotter system. By adjusting motor delays, the aim is to optimize speed and control for efficient performance. This project allows for the development of skills in mechanical fabrication, motor control, coding, and precision adjustment, resulting in the creation of a functional linear plotter.
Solidworks Simulation
The goal of this project is to design and simulate a car suspension system using SolidWorks software, focusing on motion analysis and simulation. The project aims to create an accurate 3D model of the suspension system and evaluate its performance under various driving conditions and terrains. By leveraging SolidWorks' capabilities, the project enables a detailed exploration of the mechanical design and dynamic behavior of the car suspension. Through motion analysis and simulation, the project offers insights into the system's responsiveness, stability, and overall effectiveness. This project provides an opportunity to develop expertise in engineering design and simulation, specifically in the context of car suspension systems.
Pen Lifter Project
This project aims to integrate multiple disciplines, including 3D printing, mechanical design, SolidWorks CAD, manufacturing processes, and simple circuitry. The primary goal is to provide a comprehensive learning experience by combining these diverse elements. Participants will gain hands-on knowledge of 3D printing technology and its applications, apply mechanical design principles using SolidWorks CAD software, explore different manufacturing processes for prototyping, and incorporate basic circuitry to enhance the functionality of their projects. By engaging in this project, participants will develop a holistic understanding of the design and manufacturing process, fostering their skills in various engineering fields while creating innovative and functional prototypes.
Four-Bar Linkage
This introductory project aims to deepen understanding of mechanical linkages, specifically focusing on the creation of quick-return four-bar linkages. Math Illustrations and SolidWorks software will be utilized to design and model these linkages, allowing exploration of their kinematics and performance analysis. The project provides hands-on experience in designing and simulating mechanical systems, enabling the application of theoretical concepts to practical applications.
Gasket Project
This introductory project focuses on developing essential skills in accurate measurements of mechanical features as the foundation for creating CAD models. It also introduces the use of GibbsCAM software, a vital tool for manufacturing machine components in a CNC mill. Emphasis was also placed on dimensional analysis and computer-aided manufacturing. The project is applicable because various engineering applications require precision and attention to detail.
