Category Archives: Engineering

Student Design and Engineering Web Community

Autodesk has launched the Student Design and Engineering Community for architecture, design, civil and mechanical engineering university students. Students will be able to learn, collaborate and communicate with their peers on campuses around the world.

Students and educators from accredited colleges and universities can download free student editions of professional Autodesk software, discuss projects, ask and answer questions about projects, share work, find jobs, network with personal profiles, learn from experts and use tutorials.

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Young Innovators Under 35

2006 – 35 Young Innovators Under 35 from MIT’s Technology Review:

Includes: Apostolos Argyris, disguising data as noise; Jeffrey Bode, Peptide “Legos” to make new drugs; Christopher Voigt, A vision in bacteria; Michael Wong, Cleaning up with nanoparticles

With some 300,000 hazardous-waste sites scattered across the United States, cleaning up contaminated soil and groundwater is a daunting challenge. Chemical engineer Michael Wong is taking on toxic waste with tiny particles that can break down organic pollutants more quickly, and perhaps less expensively, than existing technologies.

Wind-Powered Water Heater

University Students Build Wind-Powered Water Heater by Gregg Kleiner:

A team of engineering students from Oregon State University, inspired by a late professor’s rudimentary sketches, has designed a working prototype of a hot water heating system powered solely by the wind.

The students believe the technology, which uses magnets, a copper plate and plenty of ingenuity, has the potential to birth a new company and ultimately make an impact on the way the world heats water, especially in developing countries.
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The prototype was the team’s senior design project, a year-long, hands-on engineering course at OSU that all senior engineering students must participate in, choosing an idea or basic design and developing it to the prototype stage. Despite having no funding, the students say the concept has now been proven to work, and several team members considered spinning off a nonprofit company that would bring the technology to developing countries.

Nanoscientists Create Biological Switch

Nanoscientists Create Biological Switch From Spinach Molecule:

The scientists used a scanning tunneling microscope to image chlorophyll-a and then injected it with a single electron to manipulate the molecule into four positions, ranging from straight to curved, at varying speeds. Though the Ohio University team and others have created two-step molecule switches using scanning tunneling microscope manipulation in the past, the new experiment yields a more complex multi-step switch on the largest organic molecule to date.

The work has immediate implications for basic science research, as the configuration of molecules and proteins impacts biological functions. The study also suggests a novel route for creating nanoscale logic circuits or mechanical switches for future medical, computer technology or green energy applications, said Hla, an associate professor of physics.

Great Nanotechnology Overview

Reporting Risk Assessment of Nanotechnology: A reporter’s guide to sources and research issues (pdf) by Trudy E. Bell:

The article discusses how reporters should investigate the risks with nanotechnology, and in doing so provides a good introduction to concepts in nanotechnology:

If engineered nanomaterials have physical properties different from their bulk counterparts, might they also pose new risks to human health in their manufacture, use, and disposal?

As yet, no one knows. Current data basically suggest “it depends.” But researchers both in government and private
industry are keen to find out.

The potential for nanotechnology is amazing but as we have said before the risks presented by nanotechnology also need careful study.

At the nanoscale, fundamental mechanical, electronic, optical, chemical, biological, and other properties may differ significantly from properties of micrometer-sized particles or bulk materials.

One reason is surface area. Surface area counts because most chemical reactions involving solids happen at the surfaces, where chemical bonds are incomplete. The surface area of a cubic centimeter of a solid material is 6 square centimeters—about the same as one side of half a stick of gum. But the surface area of a cubic centimeter of 1-nm particles in an ultrafine powder is 6,000 square meters—literally a third larger than a football field.

Engineering Student Contest Winners Design Artificial Limb

St. Joseph's College of Engineering students

St. Joseph’s engineering college students win design contest, India:

Three students of St. Joseph’s College of Engineering received a cash award of Rs.50,000 for their prototype of an artificial limb, presented in the `National Level Engineering Students Design Contest’.

The contest, organised by the Product Development and Management Association (PDMA), was aimed at encouraging engineering students to design innovative products.

Organising secretary K. Chandrasekaran said the event was held to address the gap between education and industry, promoting design education and take students to the logical end of working prototypes.

Electrical Engineering Future

The future of electrical engineering

The article discusses many of the explanations for the lack of growth in engineering graduates in the USA and reasons for studying engineering. Some related posts from our blog: Top degree for S&P 500 CEOs? Engineering – Lucrative college degrees – USA Engineering Jobs – Global Share of Engineering Work – Engineers in the Workplace

Indeed, a degree in electrical engineering can open many doors, in part because electrical engineering is so broad. Electrical engineers have taken on many tasks that you might expect people with other technical degrees to do. Semiconductor processing, for example, is highly populated by electrical engineers, but its basis is in physics and chemistry. Other areas include optics (as applied to communications), aerospace engineering, and even life sciences. “A lot of people don’t realize that a lot of biomedical devices are actually electrical devices,” noted Georgia Tech’s May.

Engineered Immune Cells Shrink Tumors

Tumors Shrunk by Engineered Immune Cells, Scientists Say by Stefan Lovgren, on an extermintal treatment with 17 patients so far:

“This is the first example of an effective gene therapy that works in cancer patients,” said Steven Rosenberg, chief of surgery at the National Cancer Institute in Bethesda, Maryland, and leader of the research team.

The therapy has so far been applied only to melanoma patients. But the researchers are optimistic that their treatment can be used for many other types of cancer.

The team has already engineered similar immune cells for more common tumors, such as breast, lung, and liver cancers.
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His team focused on T (thymus) cells, a type of specialized immune cell that can learn to recognize and attack specific “foreign” objects, such as the cancer cells that make up tumors.

In the new study, researchers created tumor-fighting cells by harvesting normal T cells from melanoma patients and genetically engineering these cells to carry receptor proteins on their surfaces that recognize cancer markers.

Ocean Power Plant

Interest in ocean power resurges by Dennis Camire via A new wave of interest in ocean power:

Ocean thermal power plants, which generate electricity from the temperature difference between the tropics’ warm surface water and deep cold water, could be built on land in several hundred areas around the globe’s equatorial zones and also could be constructed as floating plants.
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A recent Electric Power Research Institute study found sites in Maine, Alaska, California and Washington that had good potential for tidal power generation with production costs ranging from 4.2 cents per kilowatt hour to 10.8 cents. By comparison, the average retail cost of electricity to U.S. consumers in May was 8.64 cents per kilowatt hour.

Research Career in Industry or Academia

In, Working in Industry vs Working in Academia, a computer scientist (software engineering) shares their experience and opinion on research career options. He discusses 4 areas: freedom (to pursue your research), funding, time and scale, products (papers, patents, products).

In academia, you’re under a huge amount of pressure to publish publish publish!
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In industry, the common saying is that research can produce three things: products, patents, and papers (in that order). To be successful you need to produce at least two of those three; and the first two are preferred to the last one. Publishing papers is nice, and you definitely get credit for it, but it just doesn’t compare to the value of products and patents.