Impact of Covid and increased use of technology
Much of the industry is focused on innovation to return to the “new normal.” The pandemic is driving the need to completely overhaul an organization’s technology systems, including hardware, software, network architecture and data management. Machinery and plant engineering were already in the process of adopting Industry 4.0, but the arrival of this global pandemic has certainly pushed the schedule for technological change forward.
Crisis-bred high-tech mechanization brings better product realization, flexibility and reliability to the industry. The lessons of the global crisis lead to a rational focus on the company’s product portfolio and risk profile. According to the United Nations Industrial Development Organization (UNIDO), manufacturing has emerged as a mainstay of post-COVID-19 economic recovery strategies.
The demand for anti-COVID-19 products has opened up new horizons for the engineering industry focused on ramping up production of medical devices and equipment. Planned investments in future technologies such as collaborative automation could quickly lead to Industry 5.0-ready industry-leading collaborative robots (cobots). These are attractive offers for mechanical engineers.
Intelligent Human Robot Collaboration
Human-Robot Collaboration (HRC) applications are already in industrial practice. Robots coexist in the same space. HRC applications have many advantages over non-collaborative applications because they can combine the advantages of both human and robotic actors. Robots offer high precision and repeatability, can lift heavy weights and reduce cycle times compared to purely manual production. Humans, on the other hand, exhibit advanced cognitive abilities and dexterity. However, HRC applications raise safety concerns as they require robots to share space or tasks with humans, potentially compromising human safety without proper application.
Increase of Micro Devices
Microelectromechanical structures, or MEMS, is a method used to create tiny gadgets or structures which have both mechanical and digital elements. The practical factors of MEMS are for example: minitiaturized structures, sensors, actuators and microelectronics.
Leveraging with IOT
- Ease of governing the machines: The motors, valves, pumps and different conventional additives are working via software. These software-pushed controls via IoT can be managed even from a long distance and making sure of the right operation of the machine.
- Increased communication: IoT complements the potential of the producer to communicate with the product and manufacturing line. The usage of IoT in product improvement includes a big capacity to strengthen product reliability.
- Strengthening ethics: The IoT-enabled business PLM (Product Lifecycle Management) machine will assist in keeping the moral feel of mechanical engineers and apprehend the significance of bodily information within the field.
- Field testing: For the field testing of the mechanical layout, IoT-enabled sensors can assist mechanical design engineers take care of troubleshooting and enhance the functions.
Careers After Mechanical Engineering
Mechanical engineering provides a foundation for students pursuing careers in design, materials, manufacturing, CAD/CAM/CAE, automation, mechatronics, FEM and industry management. Mechanical engineering graduates are sought after by employers in most areas of the engineering industry, including aerospace, automotive, chemical, construction, defense, industrial electronics, IT, materials, pharmaceuticals, railroads and consumer goods.
There are several mechanical engineering design courses in Bangalore/Bengaluru which can cater to the interests of aspiring candidates. There are many top B Tech colleges in Bangalore/Bengaluru which have a mechanical engineering course.
CMRIT Mechanical Course Details
CMRIT is one of the best mechanical engineering colleges in Bangalore/Bengaluru.
Mechanical engineering applies the principles of engineering, physics, mathematics and material science to design, manufacture, test and maintain mechanical systems. This stream is for those who are curious and have a strong interest in the design and development of physical systems.
If one has the ability to invent and design new systems that can solve real-world problems, mechanical engineering could be one’s mission. One can learn the fundamentals of mechanical engineering and learn about rapidly evolving and disruptive technologies such as automation and robotics, intelligent aeronautics, mechatronics, microelectromechanical systems, Industry 4.0, additive manufacturing and more.
Accreditation, Recognition and Accreditation:
The faculty of Mechanical Engineering of CMRIT is accredited by the National Accreditation Board (NBA), New Delhi, endorsed by the All India Council for Technical Education (AICTE), New Delhi and permanently affiliated to Visvesvaraya Technical University (VTU), Belgaum in Karnataka.