Culmination Of Years Of Development Work For The Harsh
Environment Of Space
NASA engineers have created a unique engineering marvel called
the ISIM structure that recently survived exposure to extreme
cryogenic temperatures, proving that the structure will remain
stable when exposed to the harsh environment of space. The ISIM, or
the Integrated Science Instrument Module Flight Structure, will
serve as the structural "heart" of the James Webb Space Telescope.
The ISIM is a large bonded composite assembly made of a light
weight material that has never been used before to support high
precision optics at the extreme cold temperatures of the Webb
observatory. The material that comprises the structure, as well as
the bonding techniques used to join its roughly 900 structural
components, were all created from scratch.
Imagine a place colder than Pluto where rubber behaves like
glass and where most gasses are liquid. The place is called a
Lagrange point and is nearly one million miles from Earth, where
the Webb telescope will orbit. At this point in space, the Webb
telescope can observe the whole sky while always remaining in the
shadow of its tennis-court-sized sunshield. Webb's components need
to survive temperatures that plunge as low as 27 Kelvin (-411
degrees Fahrenheit), and it is in this environment that the ISIM
structure met its design requirements during recent testing. "It is
the first large, bonded composite space flight structure to be
exposed to such a severe environment," said Jim Pontius, ISIM lead
mechanical engineer at NASA's Goddard Space Flight Center in
Greenbelt, Md.
The passage of those tests represent many years of development,
design, analysis, fabrication, and testing for managing
structural-thermal distortion.
Webb Telescope NASA Image
The ISIM structure is unique. When fully integrated, the roughly
seven-foot ISIM will weigh more than 900 kg (nearly 2000 lbs) and
must survive more than six and a half times the force of gravity.
The ISIM structure holds all of the instruments needed to perform
science with the telescope in very tight alignment. Engineers at
NASA Goddard had to create the structure without any previous
guidelines. They designed this one-of-a-kind structure made of new
composite materials and adhesive bonding technique that they
developed after years of research.
The Goddard team of engineers discovered that by combining two
composite fiber materials, they could create a carbon
fiber/cyanate-ester resin system that would be ideal for
fabricating the structure's 75-mm (3-inch) diameter square tubes.
This was confirmed through mathematical computer modeling and
rigorous testing. The system combines two currently existing
composite materials -- T300 and M55J -- to create the unique
composite laminate.
To assemble the ISIM structure, the team found it could bond the
pieces together using a combination of nickel-iron alloy fittings,
clips, and specially shaped composite plates joined with a novel
adhesive process, smoothly distributing launch loads while holding
all instruments in precise locations -- a difficult engineering
challenge because different materials react differently to changes
in temperature. The metal fittings also are unique. They are as
heavy as steel and weak as aluminum, but offer very low expansion
characteristics, which allowed the team to bond together the entire
structure with a special adhesive system.
"We engineered from small pieces to the big pieces testing all
along the way to see if the failure theories were correct. We were
looking to see where the design could go wrong," Pontius explained.
"By incorporating all of our lessons learned into the final flight
structure, we met the requirements, and test validated our
building-block approach."
Webb Telescope NASA Image
The Mechanical Systems Division at NASA Goddard performed the
26-day test to specifically test whether the car-sized structure
behaved as predicted as it cooled from room temperature to frigid
-- very important since the science instruments must maintain a
specific location on the structure to receive light gathered by the
telescope's 6.5-meter (21.3-feet) primary mirror. If the
contraction and distortion of the structure due to the cold could
not be accurately predicted, then the instruments would no longer
be in position to gather data about everything from the first
luminous glows following the big bang to the formation of star
systems capable of supporting life.
The test itself also was a first for NASA Goddard because the
technology needed to conduct it exceeded the capabilities then
offered at the center. "The multi-disciplinary (test) effort
combined large ground-support equipment specifically designed to
support and cool the structure, with a photogrammetry measuring
system that can operate in the cryogenic environment," said Eric
Johnson, ISIM Structure Manager at NASA Goddard. Photogrammetry is
the science of making precise measurements by means of photography,
but doing it in the extreme temperatures specific to the Webb
telescope was another obstacle the NASA engineers had to
overcome.
Despite repeated cycles of testing, the truss-like assembly
designed by Goddard engineers, did not crack. Its thermal
contraction and distortion were precisely measured to be 170
microns -- the width of a needle -- when it reached 27 Kelvin (-411
degrees Fahrenheit), well within the design requirement of 500
microns. "We certainly wouldn't have been able to realign the
instruments on orbit if the structure moved too much," Johnson
said. "That's why we needed to make sure we had designed the right
structure."
The same testing facility will be used to test other Webb
telescope systems, including the telescope backplane, the structure
to which the Webb telescope's 18 primary mirror segments will be
bolted when the observatory is assembled.