Project-based course on the design of mechatronic devices to address needs identified by hospital-based clinicians and industry. Students work in teams to develop a mechatronic prototype. The lectures will cover the design of medical devices and robotics including sensors, actuators, and robots. The students will communicate with customers to understand design needs, then conduct study on prior art, intellectual property, due diligence, and idea conceptualization. Students will present ideas in class and to a broad audience from local industry. Students will also write a publication-quality final report, which they will be encouraged for publication submission.

As teachers it is important to interject real-world applications with science and math whenever possible.  Students often do not connect the principles to the career opportunities.  In our society, advanced manufacturing is creating many exciting careers that incorporate these scientific principles and provide excellent salaries.  This project will require students to determine and design methods that will move a selected product in a designed assembly process.

Lean thinking, as well as associated processes and tools, have involved into a ubiquitous perspective for improving systems particularly in the manufacturing arena. With application experience has come an understanding of the boundaries of lean capabilities and the benefits of getting beyond these boundaries to further improve performance. Discrete event simulation is recognized as one beyond-the-boundaries of lean technique. Thus, the fundamental goal of this text is to show how discrete event simulation can be used in addition to lean thinking to achieve greater benefits in system improvement than with lean alone. Realizing this goal requires learning the problems that simulation solves as well as the methods required to solve them. The problems that simulation solves are captured in a collection of case studies. These studies serve as metaphors for industrial problems that are commonly addressed using lean and simulation.

This resource is a video abstract of a research paper created by Research Square on behalf of its authors. It provides a synopsis that's easy to understand, and can be used to introduce the topics it covers to students, researchers, and the general public. The video's transcript is also provided in full, with a portion provided below for preview:

"Biopharmaceuticals, protein-based drugs manufactured by living cells, are some of the most powerful and effective drugs leading the fight against numerous diseases. But producing them is a notoriously difficult business. Growth conditions, purification procedures, and formulation requirements can unintentionally change the protein structure of these drugs, altering their efficacy and toxicity. Testing for these modifications is therefore crucial. But current methods are cumbersome and don’t provide the throughput and real-time analytics that today’s rapidly growing biopharma industry desperately needs to control their development and manufacturing efforts. Now, there’s a solution. Introducing Intabio’s Blaze system. The Blaze platform performs a comprehensive analysis of biopharmaceutical product quality with 100 times higher throughput than traditional approaches..."

The rest of the transcript, along with a link to the research itself, is available on the resource itself.

The City X Project is an international educational workshop for 8-12 year-old students that teaches creative problem solving using 3D printing technologies and the design process. This 6-10 hour workshop is designed for 3rd-6th grade classrooms but can be adapted to fit a variety of environments. Read a full overview of the experience here: http://www.cityxproject.com/workshop/

Have you ever wondered why it takes such a long period of time for NASA to build space exploration equipment? What is involved in manufacturing and building a rover for the Red Planet? During this lesson, students will discover the journey that a Mars rover embarks upon after being designed by engineers and before being prepared for launch. Students will investigate the fabrication techniques, tolerance concepts, assembly and field-testing associated with a Mars exploratory rover.

The subject of this course is the historical process by which the meaning of “technology” has been constructed. Although the word itself is traceable to the ancient Greek root teckhne (meaning art), it did not enter the English language until the 17th century, and did not acquire its current meaning until after World War I. The aim of the course, then, is to explore various sectors of industrializing 19th and 20th century Western society and culture with a view to explaining and assessing the emergence of technology as a pivotal word (and concept) in contemporary (especially Anglo-American) thought and expression.
Note: In the interests of freshness and topicality we regard the STS.464 syllabus as sufficiently flexible to permit some — mostly minor — variations from year to year. One example of a different STS.464 syllabus can be found in STS.464 Technology and the Literary Imagination, Spring 2008.

Students learn about the manufacturing phase of the engineering design process. They start by building prototypes, which is a special type of model used to test new design ideas. Students gain experience using a variety of simple building materials, such as foam core board, balsa wood, cardstock and hot glue. They present their prototypes to the class for user testing and create prototype iterations based on feedback. (Note: Conduct this activity in the context of a design project that students are working on; this activity is Step 5 in a series of six that guide students through the engineering design loop.)

As students learn more about the manufacturing process, they use the final prototypes created in the previous activity to evaluate, design and manufacture final products. Teams work with more advanced materials and tools, such as plywood, Plexiglas, metals, epoxies, welding materials and machining tools. (Note: Conduct this activity in the context of a design project that students are working on; this activity is Step 6 in a series of six that guide students through the engineering design loop.)

This project, which started in May 2021, has a duration of two years ending last April 2023.
DITMEP project aims to improve manufacturing learning, in particular Risk Prevention courses, generating digital capabilities on the methodology (through e-learning, gamification and augmented reality experiences) for educators and trainees. This supports and helps the transformation of manufacturing training aftermath of COVID-19.
DITMEP has developed these blended courses for risk prevention with digital capabilities, in a transnational format solution for an innovative and reinforced education on composites manufacturing, which can be easily replicated at other sectors.
The DITMEP project consortium is composed of 5 partners, from 3 different EU countries (Germany, Spain, Portugal). Partners come from the training center, university and certifier sectors to cover all aspects of training course development.
The main objectives of the project are:
• Training course deployment in an e-learning platform with a core syllabus on Risk Prevention and Health, prepared for its adaptation to the specific countries regulation.
• Deployment of a common gamification methodology for Risk Prevention training modules
• AR mobile application development to support 2 series of learning experiences proposed as part of the core training (virtual spaces signalisation and emergency drills).
• To reinforce learners and teachers with digital capabilities: guides on how to use the materials, how to complement in-presence teaching and to develop on-line trainings.
• Tools and methodology evaluation through pilot training implementations (in all 3 countries) with included tests for evaluation the procedures from the teachers/learners.
Despite the corona pandemic, work in all work packages was able to start in May 2021. The fact that the topic of "digitization" has become extremely central nowadays motivates all project partners and shows that our research project has gained relevance again. The digital tools developed in this project will help to continue to provide high-quality training in the future.
Our training course "Prevention of occupational hazards in composite manufacturing” consists of the two blocks "General Risks" and "Specific Risks in Composite manufacturing". The first block is divided into 3 units, the second block is divided into 5 units. Each unit will have its own theoretical part in which the trainee has to build up his knowledge. What you have learned can be applied in the practical part. For our “Personal Safety Equipment” and “Signalization” units, the practical part consists of AR tools, which we developed as part of the project.
The theoretical part has been completed and translated into the respective languages of the consortium members (English, Spanish, German and Portuguese). All learning material are available on a Moodle platform and downloadable. The Moodle platform, the AR tools and the entire training course have been validated in pilot tests

Students act as Mars exploratory rover engineers. They evaluate rover equipment options and determine what parts fit in a provided NASA budget. With a given parts list, teams use these constraints to design for their rover. The students build and display their edible rover at a concluding design review.

Students act as Mars exploratory rover engineers, designing, building and displaying their edible rovers to a design review. To begin, they evaluate rover equipment and material options to determine which parts might fit in their given NASA budget. With provided parts and material lists, teams analyze their design options and use their findings to design their rovers.

The “Einstein Project” is a framework that is designed to help you find a solution to an everyday problem that makes you passionate in your thinking and designing. This project is designed to make you think outside of the box as active learners and create solutions in uncommon ways, forget about failing or succeeding and take chances.

This resource is a video abstract of a research paper created by Research Square on behalf of its authors. It provides a synopsis that's easy to understand, and can be used to introduce the topics it covers to students, researchers, and the general public. The video's transcript is also provided in full, with a portion provided below for preview:

"On-the-job training is critical to any enterprise But how and why employers train employees remains something of a mystery especially in Australia, where research on the subject appears outdated To provide a fresh look, researchers surveyed employers across several industries including government and community services retail and manufacturing Reasons for training seemed to agree with findings reported in older studies But some new trends emerged such as an accelerated need to master new technologies and an increased focus on business strategy— indications of a continuously changing workplace across the board And while financial constraints present a major barrier to training, companies report doing more training than they did five years ago with the amount of training not necessarily linked to the size of an organization Although comparative studies with other countries are needed to tease out further trends these findings could help organizations make more cost-effective decis.."

The rest of the transcript, along with a link to the research itself, is available on the resource itself.

This course provides students with an opportunity to conceive, design and implement a product, using rapid prototyping methods and computer-aid tools. The first of two phases challenges each student team to meet a set of design requirements and constraints for a structural component. A course of iteration, fabrication, and validation completes this manual design cycle. During the second phase, each team conducts design optimization using structural analysis software, with their phase one prototype as a baseline.
Acknowledgements
This course is made possible thanks to a grant by the alumni sponsored Teaching and Education Enhancement Program (Class of ‘51 Fund for Excellence in Education, Class of ‘55 Fund for Excellence in Teaching, Class of ‘72 Fund for Educational Innovation). The instructors gratefully acknowledge the financial support.
The course was approved by the Undergraduate Committee of the MIT Department of Aeronautics and Astronautics in 2003. The instructors thank Prof. Manuel Martinez-Sanchez and the committee members for their support and suggestions.

This course provides students with an opportunity to conceive, design and implement a product, using rapid prototyping methods and computer-aid tools. The first of two phases challenges each student team to meet a set of design requirements and constraints for a structural component. A course of iteration, fabrication, and validation completes this manual design cycle. During the second phase, each team conducts design optimization using structural analysis software, with their phase one prototype as a baseline.
Acknowledgements
This course is made possible thanks to a grant by the alumni sponsored Teaching and Education Enhancement Program (Class of ‘51 Fund for Excellence in Education, Class of ‘55 Fund for Excellence in Teaching, Class of ‘72 Fund for Educational Innovation). The instructors gratefully acknowledge the financial support. The course was approved by the Undergraduate Committee of the MIT Department of Aeronautics and Astronautics in 2003. The instructors thank Prof. Manuel Martinez-Sanchez and the committee members for their support and suggestions.

Fundamentals of photoelectric conversion: charge excitation, conduction, separation, and collection. Lectures cover commercial and emerging photovoltaic technologies and cross-cutting themes, including conversion efficiencies, loss mechanisms, characterization, manufacturing, systems, reliability, life-cycle analysis, risk analysis, and technology evolution in the context of markets, policies, society, and environment.
This course is one of many OCW Energy Courses, and it is an elective subject in MIT’s undergraduate Energy Studies Minor. This Institute–wide program complements the deep expertise obtained in any major with a broad understanding of the interlinked realms of science, technology, and social sciences as they relate to energy and associated environmental challenges.

The Girls Who Build: Make Your Own Wearables workshop for high school girls is an introduction to computer science, electrical and mechanical engineering through wearable technology. The workshop, developed by MIT Lincoln Laboratory, consists of two major hands-on projects in manufacturing and wearable electronics. These include 3D printing jewelry and laser cutting a purse, as well as programming LEDs to light up when walking. Participants learn the design process, 3D computer modeling, and machine shop tools, in addition to writing code and building a circuit.

The Girls Who Build: Make Your Own Wearables workshop for high school girls is an introduction to computer science, electrical and mechanical engineering through wearable technology. The workshop, developed by MIT Lincoln Laboratory, consists of two major hands-on projects in manufacturing and wearable electronics. These include 3D printing jewelry and laser cutting a purse, as well as programming LEDs to light up when walking. Participants learn the design process, 3D computer modeling, and machine shop tools, in addition to writing code and building a circuit.