Name Owen Schelenz
- Education M.S. in Electrical Engineering, B.S. in Electrical Engineering
- Target Audience High School
Owen Schelenz, Electrical Engineer with GE Global Research Center
Electricity. It's not a new concept, and it is something most all of us take for granted. Now, electrical engineers like Owen Schelenz are striving to incorporate renewable energy into our power system so the lights never go out. Read on to discover why being an electrical engineer is such a cool job!
What is your job?
I work as an electrical engineer in a group called the Power Systems Group at the General Electric (GE) Global Research Center. At GE I focus on the many facets of the technology used to better US and Global Power systems as a whole. I work on the control and stability of the wider area power system and try to integrate more renewable energy into the power system in a responsible manner. We are constantly trying to figure out how to get more wind and solar power on the grid in a manner which won't disrupt the power system - we don't want the power to come and go as the wind blows or as the sun shines.
The work we do is really on an international scale, meaning we look at power systems outside of the US. As a research engineer many of my projects require travel to places such as the Netherlands, Germany and Spain, as well as domestic places like California.
Why did you choose this career?
When I started my undergraduate education I saw a lot of people going into "hot" new fields like biomedical engineering and I thought those fields were too new at the time with not enough of a proven track record yet. I always had a passion for power systems that required big machinery and handled a lot of electricity, so I thought to myself "people are always going to need to keep the lights on somehow - people are always going to expect to flip a light switch and have power come on." I always enjoyed learning the fundamentals of how power is generated and consumed and my career evolved from there.
Explain what an average day at work is like for you.
It ranges. Some days I meet with customers to explain the technical aspects of the things we are working on and show them what they can look forward to in the future. Other days I work in the lab solving problems, strategizing about which projects we should pursue next and discussing the work that we think will be pertinent to the future. We also do a lot of community outreach here at GE by participating in such events as Bring a Child to Work Day or job shadowing. I have a couple of neat trinkets that I have built that kids find interesting, and I use these devices to help encourage kids to be interested in what I do.
What kind of trinkets?
I've been known for building my own fully functional Segway. I wanted to do it as a capstone project in college but my team wouldn't go for it, so after college I started working on it during nights and weekends and it slowly came together. I brought it to Science Day to show the elementary school kids that came to our office and these kids were very excited by it.
What do you like best about your job?
One of the great aspects of the Global Research Center is that I get to work with people from all over the world. There are many different nationalities and people with various types of interests. As a center for research we are always in learning mode and I find that very stimulating. I end up learning something new with practically every conversation that I have with my co-workers. I also like the idea that the work I am doing helps push a product further. Since I am passionate about renewable energy globally, working in this industry really makes me feel like I'm making a difference in the world.
When you were a kid, did you like science, engineering and/or math?
I was always interested in engineering. I really liked taking things apart, though I wasn't so great at putting them back together. I would go to yard sales or second-hand stores to buy discounted toys that didn't work, then I would take them apart to find out what was wrong. Sometimes the batteries were corroded or the buttons weren't making good contact - then I would be able to fix them and have working toys for really cheap. I still do this to this day.
What was the biggest challenge you faced in your journey to becoming an electrical engineer?
My challenges were primarily financially-based and had to do with paying for school. I am originally of German nationality and I moved to the states when I was young. My family was never that financially well-endowed and I knew that my parents wouldn't be able to help me out a lot by paying for college. I also had a hard time getting loans due to my German nationality. Throughout college I ended up working on the weekends - I would work 4 shifts from Friday night to Sunday, spending my nights working as a busser and my days working at a deli counter. I also helped tutor math in the university math lab during the week. Toward the end of my college years I was finally able to work into some paid internships with GE and drop some of my part-time jobs. This was a good thing for me because through the end of my sophomore year I was never able to have any Friday night college nights because I was always working. I think the challenge of how to pay for college is a struggle that many people face.
Was there a person who inspired or convinced you to get involved in your field?
I certainly always had a knack for engineering and I always showed an interest in how things work. I think it is important, though, to have a support system that nurtures your natural interests and talents. It is important to have a good teacher, advisor or professor in college that you click with. I was lucky enough to be outgoing, so I always managed to find mentors that encouraged me to pursue my interests. My first mentor was my dad, because he knew I liked to take things apart and would bring me things from his job that were about to be thrown out, like an old printer or answering machine. For Christmas I would also get science kits to play with. I remember a solar powered radio that I got for Christmas, and this was really interesting for me as a kid. I got to see how sunlight could be used to power the songs I wanted to listen to- no batteries needed!
In high school I had a few good science teachers and in college I joined an affinity group called the Institute for Electrical and Electronics Engineers (IEEE) and I had a good mentor in this group. I think it is important not to have just one mentor, but a few different people that encourage your interests.
Do you have any suggestions for how students in high school can get practical experience in your field?
One great activity for kids is the First Lego League, which is a big national competition that allows kids to compete to accomplish certain objectives with Legos. They now have Legos that come with a programmable computer so you can now build a Lego robot and tell it what to do with a computer. The objective of the competition is always given ahead of time and you get a few months to work on it. I've been a referee for this competition for a few years now, and it is always impressive to see the creative solutions students come up with to accomplish their tasks. This competition is a really great way to get into mechanical engineering, electrical engineering and computer science. And it's fun too!
Also choose some interesting electives in high school. Instead of signing up for study hall choose a programming class or a physics class. Any experience in the different scientific subjects will teach you a lot.
What majors in college would you recommend for a student who is interested in a similar career?
I think it is important to be well rounded, so take as many different classes as you can. I took an image processing class in college that I thought would be interesting, though I thought I would never use it. Now we are using a lot of the technology that I learned in this class at GE with our renewable energy initiatives. Imagine being able to look at the sky with a camera and then teach a computer what is a cloud and what isn't a cloud. This can help us predict how the cloud cover will affect solar energy. This is just an example of a class I never thought I would use and now it is showing up on a professional level.
Are there exciting things happening in your field that could involve students who will enter the field within the next 5 years?
Power systems and power electronics are things that are definitely evolving in my field. People are always trying to figure out how they all come together to make our energy supply stable but also more renewable. The idea of electrification and how we can take unconventional sources of energy like wind and solar and make them readily available on the grid will be very well received in the future.
Getting Wind of Renewable Energy
- Sail boats and sailing ships are some of the earliest examples of humans using wind power.
- The first use of solar technology can be traced back as early as 7th century B.C.E. when humans used magnifying glasses to concentrate the sun's rays to create fire. (http://www1.eere.energy.gov/solar/pdfs/solar_timeline.pdf)
- Germany is the worlds' largest user of wind energy followed by the Northern European states (Denmark gets 20% percent of its energy production from wind energy). (http://lowcostenergy.com/renewable-energy-facts/)
Biomedical: The application of the natural sciences, especially the biological and physiological sciences, to clinical medicine.
Renewable Energy: Any naturally occurring, theoretically limitless source of energy.
Segway (Segway Personal Transporter): A two wheeled self-balancing personal transport.
Solar Power: Heat radiation from the sun converted into electrical power.