Category Archives: Engineering
Academy of Mechanical and Aerospace Engineers inducts new members – Missouri S&T News and Research
Seven professionals with ties to Missouri University of Science and Technology were inducted into the Missouri S&T Academy of Mechanical and Aerospace Engineers during an induction ceremony held Thursday, Oct. 7, at the Signature Event Center in Rolla.
The academy recognizes outstanding alumni for their professional achievement and success. It also provides support and experience to help the mechanical and aerospace engineering department at Missouri S&T reach its collective mission and values.
New members are:
Timothy Alfermann of Noblesville, Indiana, electric machine release engineering manager with BorgWarner, earned a bachelor of science degree in mechanical engineering from Missouri S&T in 2001 and a master of science degree in electrical and computer engineering from Indiana University in 2007. Since joining BorgWarner, Alfermann has held positions of increasing technical and managerial responsibility, received multiple patents and launched customers in North America, Asia and Europe.
Matthew Cordner of Dallas, associate vice president and principal aerospace and defense business architect with HCL Technologies, earned a bachelor of science degree in mechanical engineering from Missouri S&T in 1984. At HCL, Cordner provides consulting and program support for complex business transformation initiatives and large aerospace and defense A&D companies. Prior to joining HCL, Cordner spent 30 years at Bell, where he held functional and leadership positions in engineering, manufacturing, supply chain, flight operations, program management and IT. He also served as director of enterprise systems and analytics for Textron, Bells parent company.
Scott Glaeser of Milstadt, Illinois, pipelines project manager with Burns & McDonnell, earned a bachelor of science in mechanical engineering from Missouri S&T in 1986. Glaeser began his career at Granite City Steel, where he focused on energy infrastructure. He also held several roles at Union Electric Co., the predecessor of Ameren, where he held numerous positions before being named vice president of gas operations and business development. Glaeser then joined G2 Integrated Solutions as vice president of the Midwest division, supporting pipeline engineering and integrity projects throughout the region.
Anthony Lebert of Milstadt, Illinois, senior design lead for aircraft structures at Boeing, where he supports Boeing Phantom Works research and development projects, earned a bachelor of science degree in mechanical engineering from Missouri S&T in 1988 and a masters degree in business administration from Washington University in St. Louis. During his tenure at Boeing, Lebert has held various design engineering and project leadership positions. He has worked on production aircraft programs including the F/A-18 Hornet and Super Hornet, the F-15 Eagle and 777X commercial airliner. He has also worked on advanced design programs.
Bradley Nelson of Maryville, Illinois, senior test program manager for the T-7 Redhawk at Boeing, earned a bachelor of science degree in mechanical engineering from Missouri S&T in 1987. Since joining Boeing as a flight test engineer, Nelson has served in various engineering and management positions at test locations throughout the country. In his current role, he manages the development of the T-7 Redhawk advanced pilot training program in St. Louis.
Michael Sinnett of Woodway, Washington, vice president and general manager of product development for Boeing Commercial Airplanes, earned bachelor of science degree and master of science degrees in aerospace engineering from Missouri S&T in 1986 and 1990, respectively. Sinnett is a member of the National Academy of Engineering, a fellow of the Royal Aeronautical Society, and an associate fellow of the American Institute of Aeronautics and Astronautics.
Anne Spence of Waco, Texas, clinical associate professor and assistant chair of mechanical engineering at Baylor University, earned a bachelor of science degree in aerospace engineering from Missouri S&T in 1985. She also earned a master of science degree in aerospace engineering from the University of Texas-Arlington in 1988 and a Ph.D. in aerospace engineering with a focus on helicopter aeromechanical stability from the University of Maryland in 1994. Spence began her career with Bell Helicopters as a handling qualities engineer. After completing her Ph.D. she was a faculty member at the University of Maryland and the University of Maryland Baltimore County.
About Missouri University of Science and Technology
Missouri University of Science and Technology (S&T) is a STEM-focused research university of over 7,200 students and is part of the four-campus University of Missouri System. Located in Rolla, Missouri, Missouri S&T offers 101 different degree programs in 40 areas of study and is ranked by CollegeFactual as the best public university to study engineering. For more information about Missouri S&T, visitwww.mst.edu
Read more from the original source:
Academy of Mechanical and Aerospace Engineers inducts new members - Missouri S&T News and Research
These coding and engineering bundles are only $20 each — and pack loads of hireable knowledge – The Next Web
TLDR: These programming, mechanical, and electrical engineering bundles can all open new career opportunities for only $20 each.
Knowledge is power. If youve got the motivation to really dig in and learn something new, your opportunities skyrocket.
Case in point hiring managers say only about 15 percent of job applicants actually have the skills that firms want in their new hire. What that means for the opportunistic go-getter is that learning in areas like coding, mechanical engineering, and more can instantly vault you ahead of more than 8 in 10 other people chasing one of those jobs.
Weve not only compiled seven ultra-packed bundles full of digital learning skills, but as part of this weeks flash sale, each bundle is available now for just $20. These deals expire in just a few days, but if you get in now, that $20 investment in you could pay off big.
If youre going to learn to code, you might as well learn everything there is to know. While this 27-course, 270-plus hour behemoth training package might not include everything, it comes pretty darn close. From learning programming languages like Python, C#, and JavaScript to deep dives on app development, database management, and even machine learning, this mountain of knowledge can more than get you ready to get working as a web developer.
Of course, coding is such a massive field with so many routes to success that there are still going to be areas primed for further exploration. This collection of 13 courses covering over 119 hours can further solidify your growing programming skills. Along with courses delving into topics like Ruby on Rails, C++, jQuery, and more, this package also includes hands-on opportunity to build working apps, and even get some first-hand experience in some of the key tenets of data science.
With everyone migrating their systems to the cloud, this top-to-bottom primer on creating, managing, and protecting networks on the Microsoft Azure platform is not only interesting, its positively vital. Over six courses, students can not only fast-track a career as a cloud developer or administrator, but also prep for exams aimed at earning prime Azure certifications to prove your skills.
After nearly three decades, Java remains so versatile and popular that its still one of the top programming languages in the world. With this eight-course package, youll understand why. One of the easiest and most powerful coding languages to learn, this training goes from the foundations of Java to how to write clean code to crafting your own algorithms. And once all this deep Java learning is done, theres also a course packed with interview questions youll undoubtedly be asked by employers that can prove your Java mastery.
Smart IT admin is knowing how to automate loads of tedious programming functions that can eat up time and brainpower. Microsoft PowerShell was built with just that task in mind and this three-course, 11-hour collection can show you how to use PowerShell to automate processes and save hours on your builds. From the basics all the way through the advanced scripting tricks and tools that all the experts use, this training can take users from PowerShell novices to experts in record time.
Raspberry Pi and Arduino have become the building blocks of DIY electronics creation everywhere. This bundle of five intensive courses can help users understand the scope of what those open-source single board microcomputers and microcontrollers can really do. Each of these courses is packed with hands-on projects like using a Pi to build a surveillance and alarm system, how Arduino code can power your own traffic light, and how to create, build, run, and debug a robot powered by your own ROS program.
Nothing runs without power so this package of five courses gets into understanding power engineering from small household energy feeds to electrical substations powering whole neighborhoods. With more than 43 hours of instruction, learners get deep into electrical circuitry, electrical drawing, powering DC machines, as well as the role of solar energy in powering both on and off-grid systems.
Prices are subject to change
Here is the original post:
Engineering innovations to enhance the performance of wireless systems – ASU Now
October 12, 2021
In the early centuries of sailing the open seas, often the only navigation tool was the human eye. Ships crews found their way by coordinating their paths based on observing the positions of the constellations of stars and planets in the sky.
Communications back then were equally old school. If ships were too far apart for crews to shout at each other, they would wave flags in specific patterns to convey simple messages.
Today, navigation, communications, ranging and nearly all operations of both sea-going vessels and airborne transportation are performed with technologies that could scarcely be imagined only several generations ago.
Now some of the most advanced communication, sensing, detection, signaling, course-setting and safety and emergency backup systems all fully automated and computerized are standard equipment. Still, the demands of the modern world continue to generate new applications to provide even more enhanced capabilities for our high-tech modes of connectivity and security.
Thats why there is keen interest in the research being conducted in facilities such as the MTP Lab at Arizona State University directed by Saeed Zeinolabedinzadeh, an electrical and computer engineer and an assistant professor in ASUs Ira A. Fulton Schools of Engineering.
His labs name is an acronym for the Millimeter-Wave, Terahertz and Photonic Integrated Circuits Lab, where researchers focus on designing high-speed integrated circuits (semiconductor chips) and systems operating at various electromagnetic frequency bands ranging from millimeter-wave frequencies to optical frequencies.
Innovative technological endeavors have earned Assistant Professor Saeed Zeinolabedinzadeh the Office of Naval Research Young Investigator Award. It will fund the efforts by his laboratory team to pursue advances to enhance the capabilities of communications, sensing, ranging and navigation systems and networks (depicted in the illustration) that are critical for todays modern connected systems and national security. Illustration provided by Saeed Zeinolabedinzadeh/ASU
The world we live in, Zeinolabedinzadeh says, is equipped with advanced technologies from the Internet of Things to communications and autonomous vehicles, all utilizing wireless transceiver systems with semiconductor chips built at the heart of those systems.
Chips that are only a few millimeters in size and less than 1 gram in weight can perform high-speed communication and high-accuracy sensing and ranging with the precision required for todays high-tech applications such as 5G communications, vehicle-to-vehicle communications, autonomous vehicles, wireless imaging and space missions.
Other circuits and systems produced by the MTP Lab are designed for use in harsh environments such as space, where there can be high radiation intensity and wide temperature variation. The lab is currently developing advanced terahertz spectrometer technology for use by NASA.
Zeinolabedinzadehs range of expertise and progress in these critical areas of research has most recently earned him a prestigious Young Investigator Award from the Office of Naval Research, or ONR.
The award will provide $510,000 to support his labs research in areas with the potential to advance the goals of the ONRs Precision Navigation and Timekeeping program.
The programs primary objective is spurring innovation in fundamental science for navigation and communications technologies to produce the next generation of highly reliable systems with enhanced precision and reduced size.
Our goal in this project is to realize cooperative arrays of radio transceivers with electronic beamforming capability with enhanced operation range, improved spatial coverage, enhanced real-time awareness and resilience to interference, while significantly reducing the cost and weight by utilizing microelectronics technologies, says Zeinolabedinzadeh, who teaches in the School of Electrical, Computer and Energy Engineering, one of the seven Fulton Schools.
The proposed systems can mitigate the effects of interferers, jammers and blockers that can otherwise interrupt the operation of communication systems, he says.
His labs earlier projects have yielded notable breakthroughs in developing fully integrated millimeter wave and terahertz transceiver and transceiver array systems with robust transmission and electronic beamforming capability with extremely reduced size, weight and power consumption (SWaP) critical for portable applications.
The microelectronic integrated circuits involved in that process are small chips capable of speedily transmitting many gigabytes of data an advancement that enabled wireless technologies that have brought us todays powerful 5G and modern Wi-Fi telecommunications technologies, Zeinolabedinzadeh says.
Saeed Zeinolabedinzadehs research focuses on the development of advanced microchip radio frequency, millimeter-wave and terahertz high-speed integrated circuits. Photo by Erika Gronek/ASU
He and his lab team are delving into these same areas in their efforts for the ONR, as well as into ways to improve high-precision time transfer for communication and ranging devices in research that is supported by a Young Faculty Award Zeinolabedinzadeh received in 2020 from the U.S. Department of Defense Advanced Research Project Agency, or DARPA.
For the ONR project, the end product will be an array of chip-scale transceivers working together for improved communication, spatial coverage, real-time awareness and highly reliable, uninterruptible signal communication that overcomes limitations in existing technology while providing a cost-effective solution with reduced size, he says.
The project also will provide opportunities for Fulton Schools graduate students to work on the advanced topics from theorizing, analysis, modeling, design, simulation, implementation and characterization of the high-frequency chips similar to those found in 5G and Wi-Fi systems.
This award provides unique opportunities to advance our research goals at ASU to achieve breakthrough innovations that can significantly enhance the performance of next-generation wireless systems for improved precision, enhanced security, robustness and faster connectivity, Zeinolabedinzadeh says.
Top photo:Saeed Zeinolabedinzadehs lab team is focusing on making advances in microelectronic integrated circuits that are capable of speedily transmitting many gigabytes of data enabling the circuits to perform high-speed communications and high-accuracy sensing and ranging with extreme precision. Photo by Erika Gronek/ASU
Here is the original post:
Engineering innovations to enhance the performance of wireless systems - ASU Now
FAU | FAU Engineering in the Top Three Fastest Improving Colleges in US – Florida Atlantic University
Florida Atlantic Universitys College of Engineering and Computer Science (COECS) is rapidly rising in U.S. News & World Report rankings, and is now one of the top three fastest improving engineering colleges in the nation (2020 to 2022). The college also is ranked No. 111 by U.S. News & World Reports Best Colleges Rankings 2022, among public engineering colleges whose highest degree offered is a Ph.D.
This rise in rankings is due in large part to numerous achievements during the past four years, which include a 2.6-fold (164 percent) increase in external research funding, a 5.8-fold (480 percent) increase in student internships, and a 40 percent increase in M.S. and Ph.D. degrees awarded.
Our College of Engineering and Computer Science is soaring to new heights and our latest U.S. News & World Report rankings is evidence that we are getting noticed by peers for our research and development output and for our robust engineering programs, which are continuously progressing, evolving and ascending to align with national priorities for workforce development, said Stella Batalama, Ph.D., dean, the COECS. Our graduates are sought by leading engineering firms in industry and government, and our innovative programs are preparing both undergraduate and graduate students to be leaders in engineering disciplines.
Research efforts in the COECS are supported by the National Science Foundation (NSF), the National Institutes of Health (NIH), the United States Department of Defense, the U.S. Department of Transportation, the U.S. Department of Education, the state of Florida as well as industry. Eight faculty members have received the NSF Early CAREER award, and two have received NIH MIRA awards, all in support of early-career faculty.
The COECS is trailblazing a path in cutting-edge research and technologies focused on artificial intelligence (AI) and autonomy, data science and machine learning. This year, the college launched the Center for Connected Autonomy and Artificial Intelligence(ca-ai.fau.edu), a revolutionary effort on networked AI and connected robotics that combines expertise in AI, computing, sensing solutions, big data analytics and autonomous technologies. Supported by the Schmidt Family Foundation, this one-of-its-kind center already has garnered more than $9 million in basic research federal funding. Center projects cover underwater, surface, air and space applications that are supported by autonomous resilient machine-to-machine wireless networking.
The college also is home to several state-of-the-art institutes and centers including the Freight Mobility Research Institute, a Tier 1 University Transportation Center funded by the U.S. Department of Transportation, established in 2017. The institute has received more than $15 million in funding to date to help strengthen the nations economic competitiveness. The colleges Industry/University Research Collaboration Center for Advanced Knowledge Enablement (CAKE) supported by the NSF and industry and established in 2009, enables close and sustained engagement between industry innovators, academic research teams, and government agencies in the areas of information technology, multimedia and data mining, and cloud computing. CAKE members include companies such as JM Family Enterprises; Motorola Mobility (powered by Google); LexisNexis; Tecore Wireless Systems and Florida Solar Energy. FAU CAKE has received more than $9 million in federal, state and industry funding.
At the forefront of research in sensing technologies is the FAU Institute for Sensing and Embedded Network Systems Engineering (I-SENSE), established in 2016 and housed in the COECS. One of the universitys four research pillars, I-SENSE is focused on infrastructure systems and smart cities, marine and environment and smart health and behavior.
Located on FAUs Dania Beach campus in Broward County, FAU SeaTech The Institute for Ocean and Systems Engineering was established in 1997 as a state-funded Type II Research Center. Focused on acoustics, marine vehicles, marine materials, ocean energy technologies, among others, SeaTech has established a long-term partnership with the U.S. Naval Surface Warfare Center Carderock Division and its South Florida Testing Facility. SeaTech is consistently funded by the U.S. Office of Naval Research.
The COECS offers 24 graduate degree programs (M.S. and Ph.D.), 13 undergraduate degree programs and 12 undergraduate and graduate certificates. In just four years, the college has launched several future-focused programs including Floridas first Master of Science program in Artificial Intelligence (MSAI). The college is designated as a Hispanic-Serving Institution by the U.S. Department of Education, and has recently received $1 million from the NSF to provide scholarships to high-achieving low-income engineering undergraduate students to pursue an M.S. degree in AI.
The college also has established Floridas first Professional Master of Science and Ph.D. degree programs in computer science for working professionals with flexible schedules and offers a M.S. and B.S. degree program in data science and analytics. New programs in the college also include a Ph.D. degree program in transportation and environmental engineering and a co-op B.S. degree program in computer science.
The COECS recently secured $3.4 million in graduate student training grants in data science and AI, as well as $4.3 million in grants focusing on population genomics with advanced machine learning and AI tools. In addition, the college hosts a number of undergraduate research scholarship initiatives to enable students to participate in federally-funded research projects, which creates a pipeline for its graduate degree programs.
The most recent point of pride for the COECS is a state-of-the-art Fab Lab (rapid prototyping and small production facility) that officially opens its doors next month to the entire University and broader community.
-FAU-
Link:
Engineers 3D-Print Personalized, Wireless Wearables That Never Need a Charge – The University of Arizona Research
By Emily Dieckman, College of Engineering
Oct. 8, 2021
Wearable sensors to monitor everything from step count to heart rate are nearly ubiquitous. But for scenarios such as measuring the onset of frailty in older adults, promptly diagnosing deadly diseases, testing the efficacy of new drugs or tracking the performance of professional athletes, medical-grade devices are needed.
University of Arizona engineers have developed a type of wearable they call a "biosymbiotic device," which has several unprecedented benefits. Not only are the devices custom 3D-printed and based on body scans of wearers, but they can operate continuously using a combination of wireless power transfer and compact energy storage. The team, led by Philipp Gutruf, assistant professor of biomedical engineering and Craig M. Berge Faculty Fellow in the College of Engineering, published its findings today in the journal Science Advances.
"There's nothing like this out there," said Gutruf, a member of the university's BIO5 Institute. "We introduce a completely new concept of tailoring a device directly to a person and using wireless power casting to allow the device to operate 24/7 without ever needing to recharge."
Custom Fit Enables Precise Monitoring
Current wearable sensors face various limitations. Smartwatches, for example, need to be charged, and they can only gather limited amounts of data due to their placement on the wrist. By using 3D scans of a wearer's body, which can be gathered via methods including MRIs, CT scans and even carefully combined smartphone images, Gutruf and his team can 3D-print custom-fitted devices that wrap around various body parts. Think a virtually unnoticeable, lightweight, breathable, mesh cuff designed specifically for your bicep, calf or torso. The ability to specialize sensor placement allows researchers to measure physiological parameters they otherwise couldn't.
"If you want something close to core body temperature continuously, for example, you'd want to place the sensor in the armpit. Or, if you want to measure the way your bicep deforms during exercise, we can place a sensor in the devices that can accomplish that," said Tucker Stuart, a doctoral student in biomedical engineering and first author on the paper. "Because of the way we fabricate the device and attach it to the body, we're able to use it to gather data a traditional, wrist-mounted wearable device wouldn't be able to collect."
Because these biosymbiotic devices are custom fitted to the wearer, they're also highly sensitive. Gutruf's team tested the device's ability to monitor parameters including temperature and strain while a person jumped, walked on a treadmill and used a rowing machine. In the rowing machine test, subjects wore multiple devices, tracking exercise intensity and the way muscles deformed with fine detail. The devices were accurate enough to detect body temperature changes induced by walking up a single flight of stairs.
Continuous, Wireless and Effortless
Gutruf and his team aren't the first to adapt wearables to track health and body function. However, current wearables do not have the ability to track metrics continuously, or with enough precision to make medically meaningful conclusions.
Some wearables used by researchers are patches that stick to the skin, but they come off when skin goes through its normal shedding process, or sometimes when a subject sweats. Even highly sophisticated wearables used in clinical settings, such as ECG monitors, face these issues. Also, they aren't wireless, which severely limits mobility. Patients can't go about their normal daily routines if they're tethered to bulky external devices.
The biosymbiotic device that Gutruf's team has introduced uses no adhesive, and it receives its power from a wireless system with a range of several meters. The device also includes a small energy storage unit, so that it will function even if the wearer goes out of the system's range, including out of the house.
"These devices are designed to require no interaction with the wearer," Gutruf said. "It's as simple as putting the device on. Then you forget about it, and it does its job."
This research was funded by the Flinn Foundation Translational Bioscience Seed Grants Pilot Program. The team has also been working with Tech Launch Arizona, the commercialization arm of the university, to protect the intellectual property and launch a startup to bring the technology to market.
Continue reading here:
Eric Appel: Gels are changing the face of engineering … and medicine – Stanford University News
Readers of Eric Appels academic profile will note appointments in materials science, bioengineering and pediatrics, as well as fellowship appointments in the ChEM-H institute for human health research and the Woods Institute for the Environment. While the breadth of these appointments does not leap to mind as being particularly consistent, the connections quickly emerge for those who hear Appel talk about his research.
Appel is an expert in gels, those wiggly, jiggly materials that arent quite solid, but not quite liquid either. Gels in-betweenness is precisely what gets engineers like Appel excited about them. Appel has used gels for everything from new-age fire retardants that can proactively prevent forest fires to improved drug and vaccine delivery mechanisms for everything from diabetes to COVID-19. Hence the appointments across engineering and medicine.
Listen in with host and bioengineer Russ Altman as Appel explains to Stanford Engineerings The Future of Everything podcast why gels could be the future of science. Listen and subscribe here.
Russ Altman, the Kenneth Fong Professor of Bioengineering, of genetics, of medicine (general medical discipline), of biomedical data science and, by courtesy, of computer science.
Eric Appel, Assistant Professor of Material Science and Engineering, by courtesy, of Pediatrics (Endocrinology) and Center Fellow, by courtesy, at The Woods Institute For The Environment
See the rest here:
Eric Appel: Gels are changing the face of engineering ... and medicine - Stanford University News
UofL engineering student earned two achievement medals during his five-year Navy career – uoflnews.com
From serving as a Culinary Specialist aboard one of the worlds most advanced nuclear powered attack submarines, to acing Mechanical Engineering classes at the University of Louisville, Michael Salas has accomplished quite a bit in the last few years.
From 2015 to 2020, Salas served in the U.S. Navy as a Culinary Specialist onboard the Los Angeles Class Attack Submarine the USS Newport News. In spring of 2021 Salas enrolled in UofLs Mechanical Engineering program as a sophomore.
During his five-year Navy career, Salas earned two Navy and Marine Corps Achievement medals: the Global War on Terrorism Service Medal and the Global War on Terror Expeditionary Medal. Although he cited his proudest decoration as earning the coveted Submarine Dolphin, signifying his expert knowledge about every system on-board the submarine. While serving on the Newport News he deployed twice, including visits to Scotland, Gibraltar, and Diego Garcia.
Salas has been a UofL fan since he and his family moved to Louisville when he was seven. From that point on, he knew he wanted to attend UofL to study engineering.
He is a proud member of UofLs Formula SAE team, an engineering design competition to design and produce a prototype race car for prospective investors. While the goal of the season is producing a competitive race car, there are many more aspects of the project than simply design and production.
Salas envisions using his Mechanical Engineering degree to pursue a career with the motorsports divisions of BMW, Toyota or Porsche.
UofL celebrates Salas service in the U.S. Navy in recognition of the 246th birthday of the U.S. Navy on October 13.
Story written by Kyle Hurwitz, UofLs director of Military and Online Initiatives.
View post:
Mechanical engineering student wins international machining competition The Daily Evergreen – The Daily Evergreen
Gus Bronk designed, machined his own keyboard at WSU mechanical engineering lab, won post-secondary education competition
Gus Bronk,senior mechanical engineering major, won an international competition in September for designing and building his own computer keyboard.
The keyboard Bronk designed and built is made from several materials, including aluminum, carbon fiber and tantalum. The process of designing and building the keyboard was particularly difficult because of the mills available for cutting out the pieces, Bronk said.
The two mills in the Cougar Shop of the Engineering Teaching and Research Laboratory only move material on the X, Y and Z axes. Bigger mills can rotate material and move it in other ways. Bronk said he had to figure out how to work around the machines limits because of the keyboards slanted shape and size.
Bronk said he decided to make a keyboard because he is a nerd. He wanted a new keyboard and started the project with a simple design in mind, then later scrapped it.
I first started making it easy to machine, then I was like, you know, this is lame. Lets try and do something a little cooler, that ended up being more difficult to machine, he said.
Once all the pieces of the keyboard were milled, Bronk said he had to send it to Coeur dAlene, Idaho, to be anodized before engraving the keys. Anodization is a process that prevents aluminum and other materials from oxidizing, said Robert Kurt Hutchinson, WSU mechanical engineering laboratory manager.
Engraving the 109 keys with all the right letters, numbers and words was also time-consuming and difficult because of their shape, he said. Bronk wrote all the coding for the keyboard and engraving.
And its not something that a student with the experience our students have tackles something that complicated, so I was all over letting him try it, Hutchinson said.
Bronk said he finished engraving the keyboard shortly before the deadline to mail it in June. He received the notification that he won the competition in September. He said the first thing he did was tell Hutchinson and then his parents.
The Mastercam Wildest Parts competition is a machining competition for students and professional engineers to design and build something unique, according to the Mastercam website. Bronk competed in the post-secondary education division, which includes colleges, universities and trade schools.
Mastercam sponsors the Wildest Parts competition every year. The 2020 competition was canceled because of the pandemic. When the 2021 competition came up, Hutchinson said he encouraged Bronk to finish the keyboard, which he started before the pandemic.
Mastercam is a company that creates software used for manufacturing machinery, Hutchinson said. The mills in ETRL run on Mastercam software.
Bronk and Jack Spieker, WSU mechanical engineering major, worked as technical assistants for Hutchinson in past semesters, Hutchinson said. This semester, he does not have TAs, so Spieker and Bronk stepped in to help because they both have experience working with the machinery.
[Bronk is] one of these guys that pretty much everyone likes because he will bend over backwards to help people without them ever asking or saying anything, Hutchinson said.
Bronk engraved the Mastercam logo, as well as a thank-you message to his family, Hutchinson, Spieker and the fast-food workers on Stadium Way on the back of the keyboard. Bronk said he also included his own personal logo, which looks like a wizard hat.
Bronk won a cash prize, as well as a license to the Mastercam software, he said. Normally, a license for the software he used to make the keyboard costs about $40,000.
Bronk said he developed an interest in engineering through his father, who is also a mechanical engineer. His father gave him a model rocket for his first birthday.
Bronk said he originally considered an electrical engineering career path, then took the mechanical engineering route after working in a machine shop in high school.
Over the summer, Bronk interned for the Phillips 66 Ferndale Refinery as an equipment reliability engineer. He worked on a team that fixed things in the refinery when they broke down and came up with solutions to make things run more efficiently, he said.
Phillips 66 offered Bronk the position again for next summer, he said.
Bronk also works as the lead engineer for WSUs Formula Society of Automotive Engineers club, he said. The club builds a race car every year and submits it in a design competition. Bronks job as lead engineer puts him in charge of technical leadership and making sure all the teams on the project have a strong direction, he said.
The keyboard he designed will be on display with the International Manufacturing Technology Show in Chicago, Hutchinson said. The keyboard will also travel to different exhibitions. It will be about a year before it is returned to Bronk.
When he does get it back, Bronk said he plans to use it. The keyboard is fully wired and functional and will replace the one he currently has.
Hutchinson said Bronks recognition is a positive influence for younger mechanical engineering students.
It really inspires them to work hard to try things that maybe they havent thought they were capable of, he said.
Read this article:
Queen thanks engineering and technology industry for invaluable inventions – Yahoo Lifestyle UK
The Queen has praised those working in engineering and technology for their countless invaluable inventions and for making a difference to society every day.
The monarch, who is patron of the Institution of Engineering and Technology (IET), sent a message to mark the organisations 150th anniversary.
Her late husband, the Duke of Edinburgh, was a passionate champion of engineering and the Queens recognition of work in the field comes just six months after Philips death.
She hailed the rapid evolution of electrical technologies that underpin 21st century life.
In her message, which was signed Elizabeth R, the Queen said engineers continue to improve the lives of millions with their solutions to global problems.
Engineering and technology innovations have had an impact on many aspects of our lives, from the rapid evolution of electrical technologies that underpin 21st century life, to the countless other inventions which have become invaluable to us all, she said.
Engineers have created solutions to global challenges and continue to improve the lives of millions of people all over the world.
This anniversary provides an opportunity to thank and recognise the dedication and hard work of all those working in engineering and technology who, every day, make a difference to society, and whose professionalism is championed by the Institution of Engineering and Technology.
I send my good wishes to you all and hope the next 150 years will continue to bring you success in delivering your vision to Engineer A Better World.
The IET was established in 1871 and represented those working in newly established telegraph companies.
It now supports 158,000 professionals in 153 countries.
The IET said the Queen is a keen supporter of the industry and has described the role of engineer as a noble profession.
See the original post:
Queen thanks engineering and technology industry for invaluable inventions - Yahoo Lifestyle UK
AstraZeneca and the Royal Academy of Engineering announce new partnership to bolster support for African health tech entrepreneurs – Africanews…
Earlier today, AstraZeneca (www.AstraZeneca.com) and the Royal Academy of Engineering (the Academy) officially announced a new partnership to establish connections between African healthcare innovators and AstraZenecas A.Catalyst Network of more than 20 global health innovation hubs. The joint venture seeks to drive the development of engineering solutions that have the potential to address local challenges with a focus on health tech.
As part of its commitment to building international partnerships and solving global challenges, in 2014 the Academy founded The Africa Prize for Engineering Innovation (https://bit.ly/3Ah0FC8), an annual award that grants crucial commercialisation support to ambitious innovators across sub-Saharan Africa. To date, over 100 innovators are part of the Africa Prize alumni network. AstraZenecas A.Catalyst Network brings together digital, R&D and commercial resources to reimagine the future of healthcare, working with partners to co-create solutions and establish integrated and strong health systems that benefit the whole patient experience. By connecting Africa Prize entrepreneurs to A.Catalyst Network, as well as the AstraZeneca supply chain and wider ecosystem (including investors), the AstraZeneca-Academy partnership hopes to further strengthen the work of both organisations to nurture local talent and strengthen healthcare innovation and creativity on the African continent.
As part of the collaboration, AstraZeneca will join the Prizes network of expert mentors, offering training support for Africa Prize entrepreneurs, giving them access to tailored expertise and experience to help them develop their projects. AstraZeneca will also take part in a webinar series for the Africa Prize alumni network and current cohort, sharing knowledge and insights on health tech and other subjects.
Aleksandr Bedenkov, VP, Medical International at AstraZeneca said: We want to offer entrepreneurs in emerging markets like Africa the same kind of platform and opportunities that their counterparts in other countries would benefit from. A.Catalyst Network offers exciting opportunities for health tech entrepreneurs to connect and collaborate with a truly global network of expertise and experience, helping to accelerate innovation and ensure that more patients can get access to the latest health tech solutions.
Barbara Nel, Country President, African Cluster at AstraZeneca, said: This partnership with the Royal Academy of Engineering is integral to our unwavering commitment to improve health access and create sustainable impact in Africa. We recognise that breakthrough science and healthcare don't happen in isolation; they are the result of collaboration and partnerships to strengthen healthcare innovation and creativity. We are looking forward to supporting our Africa Prize entrepreneurs in developing their innovative projects and working together to seek answers to our health challenges for the benefit of all patients in Africa.
Ana Avaliani, Director of Enterprise and Sustainable Development at Royal Academy of Engineering said: Our partnerships are crucial to delivering the breadth and depth of support we can offer, which in turn allows the programme to accelerate African entrepreneurial capacity, producing scalable, local solutions to global challenges. We believe that while one innovator can change a community, a network can transform a continent, and the Africa Prize network truly represents the brightest minds tackling the greatest challenges. We are looking forward to working with AstraZeneca to amplify the impact of our innovators in harnessing the power of engineering and building a sustainable society and inclusive economy that works for everyone.
Going forward, AstraZeneca and the Academy will continue to collaboratively explore further partnership opportunities to support the healthcare system in the region and beyond.
For media enquiries please contact:AstraZenecaAna ZainaghiAna.Zainaghi@astrazeneca.com
The Royal Academy of EngineeringJane Suttonjane.sutton@raeng.org.uk
About AstraZeneca:AstraZeneca (LSE/STO/Nasdaq: AZN) is a global, science-led biopharmaceutical company that focuses on the discovery, development, and commercialisation of prescription medicines in Oncology, Rare Diseases, and BioPharmaceuticals, including Cardiovascular, Renal & Metabolism, and Respiratory & Immunology. Based in Cambridge, UK, AstraZeneca operates in over 100 countries and its innovative medicines are used by millions of patients worldwide. Please visit AstraZeneca.com and follow the Company on Twitter @AstraZeneca.
About A.Catalyst Network:A.Catalyst Network is an interconnected global network of more than 20 AstraZeneca health innovation hubs, made up of physical locations and virtual partnerships. The network embodies our commitment to Growth Through Innovation (https://bit.ly/3lgCQ9s) and is a key part of our Patient Centricity workstream, as a catalyst for the development of new solutions to support patients. It aims to address healthcare challenges, increase access to healthcare, and scale and showcase patientenabled innovation around the world.
About The Royal Academy of Engineering:The Royal Academy of Engineering is harnessing the power of engineering to build a sustainable society and an inclusive economy that works for everyone. In collaboration with our Fellows and partners, we are growing talent and developing skills for the future, driving innovation and building global partnerships, and influencing policy and engaging the public. Together were working to tackle the greatest challenges of our age.
About the Africa Prize for Engineering Innovation:The Africa Prize for Engineering Innovation, founded by the Royal Academy of Engineering, is Africas biggest prize dedicated to engineering innovation. It awards crucial support to ambitious African innovators developing scalable engineering solutions to local challenges, demonstrating the importance of engineering as an enabler of improved quality of life and economic development. The programme is designed to help engineers achieve commercial success from their innovations. Following an eight-month training and mentoring period, the Africa Prize for Engineering Innovation is awarded to a chosen winner, who receives 25,000, while three runners-up receive 10,000 each.
Africanews provides content from APO Group as a service to its readers, but does not edit the articles it publishes.
Go here to read the rest: