Victoria Burt
Contributing Editor
Julie Kalista
Online Editor
What does it take to be a great engineer?
One way to find out is by
talking to engineers who’ve made
significant contributions to their
industries. Machine Design has
done exactly that.
The engineers profiled in the next few pages share several
traits. All faced challenges that forced them to think outside
their comfort zone and beyond their personal technical bias.
And they share an intense drive to solve problems, and create
new designs that make the world a better place.
Refuel on your way to Mars
Dan Delong, of XCOR Aerospace, Mojave, Calif. (xcor.com), is the lead engineer on a rocket engine, developed for
NASA that uses liquid methane as fuel. Delong and his team
had to come up with a way for astronauts to get fuel at their
destination, for example, Mars or the moon. As Delong puts
it, “If you are traveling across country and cannot stop for
fuel, the vehicle will be much bigger and heavier. However, if
you can stop for gas along the way, you can use a smaller and
lighter mode of travel.”
Delong says the team’s most-difficult challenge was in
cooling the combustion chamber. The solution was to direct
the fuel through carefully designed galleries. “The cooling
properties of boiling liquid methane are relatively unknown,
so this was a challenging design with lots of risks,” says Delong.
“We overcame that by using the best analysis we could,
with the most conservative cooling design.”
Inspired by his father, a lab technician who did house
wiring on the side, Delong got his Bachelor’s degree in Materials
Science and Engineering from Cornell. Interestingly,
he didn’t start out in aerospace. His first job out of school
was working with submarines and he says they fascinated
him. However, in 1984, a friend encouraged Delong to work on the Space Shuttle. He says the technical aspects of the career
change came easy, but he was challenged by the culture
of working for the government.
Changing a company and family’s culture
With four brothers who are engineers, engineering might
have seemed an obvious career choice for Susan Benysh.
But she says her parents advised her and her sisters to enter
traditionally female vocations such as medicine. Fortunately
for Benysh, a high-school teacher encouraged her to
consider engineering. She minored in
electrical engineering and then discovered
a school with a human-factors
engineering program that combined
her interest in engineering and
psychology.
Benysh got her Ph.D. from Purdue
and now works at IBM Corp., Rochester,
Minn. (ibm.com). She recently
moved to the Learning department
where her title is Learning Partner.
She is developing a program to teach
other IBM software engineers how
to design leaner and better products.
She says the hardest part of the project
is convincing her colleagues to adapt
to a new process. “Some people resist
change even when it will make their
work easier. The culture is an obapplicastacle
we are overcoming
as people go through the
classes and bring the techniques
back to their departments,”
Benysh says.
A package
like a puzzle
Mauro Morandi was
working on a different
project when some colleagues
asked him to help with a new
carton package design. He agreed to
help the team at Tetra Pak, Italy (tetrapak.com), and together they created the
eye-catching, octagonal Tetra Prisma
Aseptic package. An aseptic package
gets sterilized before it is filled with
food, resulting in products that can
stay on the shelf for over six months
without refrigeration or preservatives.
Morandi faced a major challenge
in the final folding of the top and bottom
parts of the package. “Because of
the octagonal shape, we had to fold
the edges twice, increasing complexity,
manufacturing, and slowing output.
My idea was simply to use the octagonal
shape in the middle of the package
and the traditional rectangular
or square shape of Tetra
Prisma’s predecessor, Tetra Brik
packages, for the top and bottom,”
says Morandi.
Growing up, Morandi always
loved trying to understand
and illustrate how things
work. He received his diploma
from the Istituto Tecnico Industriale
Statale Remo Corni,
in Modena, Italy, where he
studied mechanics.
Let the robot do it
The well-known Roomba is the
first home appliance to excite
the imagination of nontechies.
Made by iRobot, Burlington,
Mass. (irobot.com), the autonomous
vacuum cleaner is
the brainchild of a design team
headed up by Chris Casey, lead electrical engineer. According
to Casey, Roomba’s magic is the combination of two
tasks: navigating around an unstructured environment
while cleaning a wide variety of floor surfaces.
Equipped with navigation sensors, Roomba senses obstacles
like furniture, steps, and walls. It uses only 30 W to
clean as much as vacuums using more power.
Casey credits the development
team for making the
Roomba a reality. Scientists Joe
Jones and Paul Sandin were the
first to realize that a low-cost
floor vacuum robot was possible.
“Three engineers, Eliot
Mack on mechanics, Phil Mass,
and I, worked for Joe and Paul
for over two years turning the
concept into a product,” says
Casey.
“Our biggest challenge was
getting the robot to operate in a
human world, while balancing
conflicting needs like cost, size,
cleaning ability, and navigation.
We figured it out as we went —
at one point we spent nearly a
month testing the length of the
rear shroud of the main brush.”
Fascinated by programming
and the “magic” by which programs
were executed, Casey knew
from an early age he wanted to be
an electrical engineer. He picked
a good place to get Electrical Engineering
credentials: He graduated
from MIT and worked for a small company designing
electronics before coming to iRobot in 1997.
How to make racing engines last longer
Jobey Marlowe loved mechanics from an early age. He
started racing peddle cycles when he was eight-years old,
but couldn’t afford more than one bike. So he found parts
in dumpsters, put them together, and sold bikes for profit.
That early experience sparked his interest in both racing and
engineering.
Marlowe got a chance to make both areas his vocation
with the Magnom separator. The separator protects engines
in high-stress endurance races by filtering out iron and steel
contaminants. The technology uses magnetic flux, magnifying
it and focusing it into a complex matrix directed into
the oil stream. It came out of Marlowe’s discovery that the
metallic particles in engine oil were so small, they passed
straight through conventional filters.
The biggest obstacle in developing the separator was
optimizing the relationship between the contact zone of the
plates involved and the magnets. Engineers made several
prototypes and compared how they worked in live applications. The best features from
the most-efficient prototypes
went into the product
on the market today.
Harold Hall, or “H” as
Marlowe refers to him, is
an ex-Royal Air Force engineer.
He is also Marlowe’s
role model. “H is a bit like
the professor on ‘Back to the
Future,’ same looks and mannerisms,
a real sweet old guy,
and a heck of an engineer. He
got me seriously interested in
racing and building engines.
Today he still builds the most
reliable race engines on the
track,” says Marlowe.
I feel your psi arising
Pressures in aircraft hydraulic systems now reach 5,000 psi.
Tung Le and his team had to create fasteners that could
handle the pressure. As a project engineer for Alcoa Fastening
Systems, Fullerton Aerospace Operations, Fullerton,
Calif. (alcoa.com/global/en/home.asp), Le developed
the firm’s Ring Locked Fluid Boss Adapters. They have
captive lockrings that secure the adapters to the boss thus
keeping connection tight under severe vibrations, temperature
cycling, or B-nut installation and removal.
Le says the most challenging part of the design was
convincing the industry to accept it. However, Alcoa got a
break when, after passing extensive tests, Boeing agreed to
use the fittings on its new 787 Dreamliner.
As a child growing up in war-torn Vietnam, Le memorized
the look of aircraft, warships, tanks, trucks, and
weapons he saw daily, and drew them when he got home.
“This was the starting point for my entry into engineering,”
he says.
Le has a degree in mechanical engineering from Vietnam’s Saigon Institute of Technology. When he
came to the United States, he took engineering
classes at various schools. Le credits a colleague,
Owe Carlsson, director of engineering and quality
assurance, as being his mentor.
A plastic that protects
against x-rays
For Jay Amarasekera and his team at Sabic Innovative
Plastics, (formerly GE Plastics), Pittsfield,
Mass. (sabic-ip.com), the goal was clear: Find a
replacement material for lead in X-ray shielding.
Solving the problem, however, took experience
and lots of testing. The result was LNP Thermocomp
HSG compound. It is a compound based on
tungsten — a nonhazardous high specific gravity
material — in nylon.
The idea for the project came from the industry
push to get away from lead. Amarasekera
says, “the toxicity of lead has been heavily reported
in the news including stories about lead
paint on toys, and standards such as RoHS call
for a reduction in lead use. But for X-ray shielding
plastics, there were limited lead-free alternatives
that had good manufacturing capabilities.”
Amarasekera and
team members
Jennifer Doerfler,
Julie Tinklenberg,
and Dave Sweeley
developed a plast
ics composite
with X-ray shielding
properties
resembling those
of lead and optimized
flow properties for
easy injection molding. The
team worked with customers
to test the compound
and develop easily manufactured
grades for thin-wall
applications and designs
with complex geometries.
Amarasekera is the Technology
Manager at Sabic’s
LNP Business Unit. He has a
PhD in inorganic chemistry
from the University of Illinois
at Urbana-Champaign
and over 20 years experience
working with materials.
He says his career naturally
progressed to engineering
because he enjoys solving
problems and creating new
products.
Making tiny
instruments
for microscopic
procedures
Adam Cohen’s background in
rapid prototyping combined
with his interest in MEMS led
him to help develop electrochemical
fabrication, or Efab
for short. Cohen thought it
should be possible to design
a complex structure using 3D
CAD and then make it, one layer at
a time, from metal, on a wafer scale.
The idea could potentially be used
to fabricate hundreds or thousands
of devices simultaneously.
Efab technology from Microfabrica,
Van Nuys, Calif. (microfabrica.com), works by precisely depositing
and polishing the surface of two
metals. One of these is structural
— forming the final structure —
while the other is temporary and
sacrificial, serving as a support or
scaffolding during fabrication. Each
layer involves three key steps: deposition
of one metal in a precise pattern
that defines a cross section of
the desired structure, blanket deposition
of a second material, and planarization
(polishing the surface),
which yields a two-material layer
of well-controlled thickness, flatness,
parallelism, and surface finish.
After all layers are formed, the
sacrificial metal is dissolved away,
leaving behind the desired structure
with all individual components
now free to move with respect to
one another.
Cohen holds 34 patents and is
Microfabrica’s chief technology officer.
He has a BS in physics from
MIT and studied theoretical physics.
But 22 years ago he made a critical
decision to move out of pure
science into technology. He works
in engineering to “help repair the
world, and because I enjoy inventing
new things. I believe civilization
owes a massive debt to the world’s
inventors and engineers: without
their ingenuity, dedication, and
hard work we would all have short,
miserable lives filled with hardship,
poverty, pain, and illness.”
Experience and
experimentation
come together
Luke Volpe says he was drawn to engineering
almost 50 years ago when
a distant uncle gave him some career
advice. “Back in the days of Sputnik,
engineering was a popular and well
respected profession, especially in the
semiconductor industry, where I was
fortunate to work,” he says. Volpe has a BS in Industrial
Engineering from Boston University.
His career started at Transitron, a semiconductor
company, where he designed crystal-pulling systems
and developed photomask processes for semiconductor
devices. Almost 30 years ago he went to Dynamics
Research Corp., where he is now director of
engineering for the Metrigraphics Div., Wilmington,
Mass. (drc.com/metrigraphics/metrigraphics.htm).
They make extreme resolution microflex (ERMF)
circuits, which are used in imaging, monitoring, and
coupling devices. The circuits are so small and flexible
they can serve in angioplasty devices where they
are rolled into a cylinder and placed in veins.
According to Volpe, the ability to produce circuits
with traces as small as 5 microns is the result
of expertise in three technologies: semiconductor
photolithography, thin-film processing, and electrochemical
deposition. Volpe says the
learning curve was steep. The process
consists of spin casting and curing a
polyimide base layer. A conductive
metal layer is then deposited and delineated
into traces. Multiple conductive
trace layers are created by depositing
a second polyimide dielectric interlayer
and forming interconnecting via
holes prior to depositing the second
layer traces. During the early development
stages via holes were formed
using a photoimagable polyimide.
This process was adequate for circuits
with small numbers of via holes but
was not reliable for the more complex
circuits with three or more trace layers.
The problem was solved by using a
laser-drilling technique to form the via
holes. Reliable six-layer ERMF circuits have been built with this technology.
Volpe credits his team with the success
of the ERMF circuits.
Ultraclean 3D printing
Z-Corp. figured it would be a great
idea to devise a 3D printer that set
new standards for ease of use and easy
cleanup. Engineering program manager
Josh Kinsley and his team including
Dmitriy Katalichenko, Diego Torres,
Andrew Berlin, Ben Sweet-Block,
and Leo Kiefer set out to create one.
The result is the ZPrinter 450 color
3D printer which prints parts such as
concept mock ups, anatomical models
from MRI or CT scans, and automotive
prototypes.
On other machines, users had to
add powder at the beginning of the
process, then brush out the excess
powder to get to the finished object.
The team worked to automate the
powder-handling process but says the
task was not easy. “It’s difficult to make
powder do what you want it to because
it can behave like a solid, liquid, or gas,”
says Kinsley. “When you want to move
powder around you’d like it to flow like
water. But unfortunately it can set up
like a solid, and it doesn’t want to go
anywhere. Effectively handling powder
was one of the major design challenges
we faced with the 450, but our
automatic powder-handling system
worked flawlessly,” he adds.
Kinsley has a degree in mechanical
engineering and has worked for seven
years at the company in Burlington,
Mass. (zcorp.com).