Ementorhub

Specialization - 3 course series

The projects proposed in the courses under the specialization, “Collaborative Robotics in Industry” are having a sequence of tasks in each and every project. They need to design a robotic manipulator, design an appropriate end effector, should make the interface with the electronic control system. For heavy load handling purpose utilize the electro-hydraulic systems. Prepare a blue print to carry out this project comprising all the essentials like appropriate sensors, drive systems, electronic circuitry and fluid circuitry. Interface the developed robot with a control system. Find out an appropriate ICs and essential electronic circuit elements. Choose prototyping platforms either Arduino or Raspberry Pi. Apply the IIoT concepts. Choose a relevant gate way and connectivity to monitor its functioning and enhance the productivity.

As the backbone of modern industrial automation, robotics engineering holds immense significance in optimizing processes, enhancing productivity, and improving efficiency. Throughout the course, participants will delve into the nuances of robotic engineering, gripper designs, PLC (Programmable Logic Controller), and mechatronics system design. The interdisciplinary nature of the curriculum ensures that students develop a holistic understanding of the subject, enabling them to tackle real-world challenges with confidence and expertise. A strong foundation is laid through the prerequisites of the course, encompassing basics on industrial manufacturing, fundamentals of introductory mechatronics, introductory electronics, and applied physics. These prerequisites ensure that participants enter the course with the necessary background knowledge to fully engage with the advanced concepts presented throughout the modules. Upon completion of this course, participants will acquire a diverse set of skill sets essential for success in the field of collaborative robotics. From robotic manipulator design to robotic gripper design, participants will gain proficiency in designing and implementing key components of robotic systems. Furthermore, the course emphasizes the importance of interfacing mechanical components with digital control circuitry, equipping participants with the ability to seamlessly integrate hardware and software components in automation environments. A deep dive into sensor & transducer technology empowers participants to leverage cutting-edge sensing technologies for precise measurement, feedback, and control in robotic applications. Additionally, participants will develop troubleshooting skills essential for identifying and resolving issues in mechatronic systems, ensuring smooth operation in industrial settings. Mechatronics system design principles are thoroughly explored, enabling participants to conceptualize, design, and optimize complex systems tailored to specific industrial requirements. The course culminates in simulation using MATLAB-Simulink, providing participants with hands-on experience in designing, modeling, and simulating robotic systems. This practical aspect of the course not only reinforces theoretical concepts but also prepares participants for real-world implementation and problem-solving. In conclusion, the "Fundamentals of Robotics & Industrial Automation" course offers a transformative learning experience for individuals aspiring to excel in the dynamic field of collaborative robotics. Through a blend of theoretical knowledge, practical skills, and hands-on experience, participants emerge with the expertise and confidence to make meaningful contributions to the future of industrial automation.

At its core, the course emphasizes a hands-on approach to learning, ensuring participants are equipped with practical skills and theoretical knowledge essential for success in the field of collaborative robotics. The prerequisites of the course lay a solid foundation, covering basics on industrial manufacturing, fundamentals of introductory mechatronics, introductory electronics, and applied physics. Armed with this knowledge, participants are prepared to dive into the intricacies of robotic engineering and applications. The first module, "Robotic Engineering Essentials," serves as the cornerstone of the course, providing participants with a comprehensive understanding of robotic manipulator design, gripper designs, and the fundamentals of robot programming. Participants will explore the intricacies of designing and configuring robotic systems tailored to specific industrial requirements, laying the groundwork for subsequent modules. The second module, "Robot Programming and Vision Systems," delves into advanced programming techniques and the integration of vision systems in robotic applications. Participants will learn to harness the power of cameras, image processing, and object recognition techniques to enhance robot perception and decision-making capabilities. The module also explores the application of machine vision in industrial processes, equipping participants with the skills to analyze and interpret visual data for a wide range of applications. In the final module, "Design & Robot Building and Applications," participants will put their newfound knowledge into practice, undertaking the challenge of designing and building their own robots for real-world applications. From conceptualization to implementation, participants will learn to navigate the intricacies of robot design, integrating components seamlessly to achieve optimal performance. Furthermore, the module explores the implementation of Industrial Internet of Things (IIoT) in robotics, empowering participants to leverage interconnected devices and sensors to enhance automation and efficiency in industrial settings. Upon completion of this course, participants will emerge with a diverse set of skill sets essential for success in the field of collaborative robotics. From robotic manipulator design to robot programming, participants will gain proficiency in designing, programming, and implementing robotic systems tailored to specific industrial requirements. Furthermore, participants will be equipped with the knowledge and expertise to integrate vision systems and IIoT technologies, revolutionizing automation and efficiency in industrial processes. In conclusion, the "Robotics Engineering & Applications" course offers a transformative learning experience for individuals aspiring to excel in the dynamic field of collaborative robotics. Through a blend of theoretical knowledge, practical skills, and hands-on experience, participants emerge as innovators poised to make meaningful contributions to the future of industrial automation.

A solid foundation is laid through the prerequisites of the course, covering basics on industrial manufacturing, fundamentals of introductory mechatronics, introductory electronics, applied physics, and fundamentals of fluid mechanics & machinery. Armed with this multidisciplinary knowledge, participants are primed to delve into the complexities of industrial fluid systems and smart factory automation. The first module, "Fluid and Electrical Drive Systems," serves as the cornerstone of the course, offering participants a comprehensive understanding of electrical drives and control systems for machine tools and robots. Participants will explore the selection and implementation of electrical drives, along with troubleshooting techniques to ensure optimal performance. Additionally, the module delves into industrial hydraulics and pneumatics for automation, equipping participants with the skills to design electro-hydro-pneumatic systems tailored to specific industrial requirements. In the second module, "Fluid Circuit Systems," participants dive deeper into the design and implementation of fluid circuit systems essential for efficient operation in industrial environments. Through a combination of theoretical concepts and practical exercises, participants gain proficiency in designing and optimizing fluid systems to meet the demands of diverse applications. The final module, "Smart Factory Automation," explores the integration of advanced automation technologies to create intelligent, interconnected manufacturing environments. Participants will delve into topics such as industrial remote monitoring, smart material flow, IIoT (Industrial Internet of Things) in smart factories, digital twins, and industrial data analytics. Through hands-on projects and case studies, participants will learn to design and implement smart factory automation solutions, revolutionizing efficiency and productivity in industrial settings. Upon completion of this course, participants will emerge with a diverse set of skill sets essential for success in the field of industrial fluid systems and smart factory automation. From choosing the right electrical and hydraulic-pneumatic drives to designing and troubleshooting fluid systems, participants will possess the expertise to tackle real-world challenges with confidence. Furthermore, participants will be equipped to apply IIoT technologies for remote monitoring and predictive maintenance, ensuring the health and efficiency of machinery in industrial environments. In conclusion, the "Industrial Fluid System & Smart Factory Automation" course offers a transformative learning experience for individuals aspiring to excel in the dynamic field of smart manufacturing. Through a blend of theoretical knowledge, practical skills, and hands-on experience, participants emerge as innovators poised to make meaningful contributions to the future of industrial automation and efficiency.

Robotics Engineering & Applications

Industrial Fluid systems & Smart Factory Automation