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Electronic
Products & Technology - May 2008
Products
on Review
Negative-Stiffness vibration isolators provide
a significant improvement over air tables in vibration-sensitive
environments
Although
air tables have been around for the better part of a half-century,
their usefulness as an efficient method for vibration isolation
is now being seriously challenged by the more compact and
effective negative-stiffness vibration isolators.
By Jim McMahon, technical writer on controls
and instrumentation technology
For almost 40 years pneumatic vibration isolators have
been the mainstay for stabilizing industrial and academia's
most critical micro-engineering instrumentation. But just
as technology has been steadily migrating from micro to nano,
so has the need for more precise vibration isolation in microelectronics
fabrication, industrial laser/optical systems and biological
research.
These so called 'passive system' air tables are now being
seriously challenged by the newer Negative-Stiffness vibration
isolators. Negative-Stiffness isolation is rapidly gaining
popularity in industrial and laboratory environments, and
to no small degree because of its ability to effectively isolate
vibration in diverse and challenging environments.
An isolator is used to solve a problem, and how bad the problem
is determines the solution you need. Since the 1960's, air
tables have been used for isolation. Basically cans of air,
they are still the most popular isolators used. But, air tables
with resonant frequencies at 2 to 2.5 Hz can typically only
handle vibrations down to about 8 to l0 Hz, not quite Low
enough for optimum performance with modern nano-equipment.
Also, greater isolation efficiencies are needed in the frequency
ranges air isolators can handle.
For purposes of clarity in scanning probe microscopes and
interferometers, air tables are an inefficient isolation solution.
The air systems have been adequate up until a few years ago
when better isolation was required.
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Because of its very high isolation efficiencies,
Negative-Stiffness vibration isolation systems enable
vibration-sensitive instruments such as scanning probe
microscopes, micro-hardness testers, profilers and scanning
electron microscopes to operate in harsh conditions
and severe vibration environments that would not be
practical with top-performance air tables and other
pneumatic isolation systems.
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Negative stiffness vibration
isolation platform
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How negative-stiffness vibration isolation works
Negative-Stiffness isolators employ a unique - and completely
mechanical -concept in low-frequency vibration isolation.
Vertical-motion isolation is provided by a stiff spring that
supports a weight load, combined with a Negative-Stiffness
mechanism. The net vertical stiffness is made very low without
affecting the static load-supporting capability of the spring.
Beam-columns connected in series with the vertical-motion
isolator provide horizontal-motion isolation. The horizontal
stiffness of the beam-columns is reduced by the 'beam-column'
effect. (A beam-column behaves as a spring combined with a
Negative-Stiffness mechanism.) The result is a compact passive
isolator capable of very low vertical and horizontal natural
frequencies and very high internal structural frequencies.
Negative-Stiffness versus air isolation
Following are ten key points which demonstrate the benefits
of Negative-Stiffness isolators compared to air isolation
systems:
#1: Low Hertz perturbations
An air table will amplify vibrations in a typical range of
2 to 7 Hz, this is because of the natural frequencies where
air tables resonate. All isolators will amplify at their resonant
frequency and then they will start isolating. So, with an
air table, any vibration in that range could not only fail
to be mitigated, it could be amplified. The low cycle perturbations
would just come straight through to the instrument.
#2: Image clarity
Negative-Stiffness vibration isolation can reduce vibration
noise levels in Atomic Force Microscopes, for example, by
a factor of 2 to 3 when compared with top-performance air
tables. This is particularly significant for noise levels
in the sub-Angstrom range.
#3: Severe vibration environments
As nano-equipment use becomes more prevalent, Lab sites are
being set up in much more severe vibration-prone environments,
such as upper floors of buildings and clean rooms. Such severe
vibration locations are too extreme for pneumatic isolators
to effectively do their job.
#4: Harsh environments - vacuums, high/low temperature
extremes, radiation
Air tables are not particularly compatible when it comes to
operating in vacuums, extreme high and low temperatures and
radiation. Yet, these harsh operating environments are often
necessary when conducting research and testing, such as with
cryogenic chambers in semiconductor research.
All metal Negative-Stiffness systems can be configured which
are compatible with high vacuums and other adverse environments,
such as extreme high and Low temperatures and radiation. With
vacuums, for example, Negative-Stiffness isolators can be
used right inside the vacuum chambers.
#5: Compressed air
Air tables require a constant supply of compressed air. This
requires either a dedicated compressed air Line to be plumbed
in to your lab, a tank of pressurized gas or a small compressor.
Even if you are lucky enough to have a dedicated compressed
air Line, your table's location is still limited by the length
of air line you have. Large tanks of compressed gas have to
be mounted very securely to minimize their danger. Changing
the tanks can be quite difficult and inconvenient as well.
Compressors are sources of both mechanical and acoustic noise
and are very poor choices from a vibration standpoint.
If you can get your nano-environment mechanically isolated
without having to deal with compressed air to run your vibration
isolator, then you will be better off. The nice thing about
Negative-Stiffness isolators is they do not require compressed
air.
#6: Location selection for vibration-sensitive equipment
Let's face it, air tables are big, bulky structures, they
take up a lot of lab space. The high-performance air tables
are even bigger. This can become a limiting factor when laying
out the equipment in your Lab.
Negative-Stiffness isolators are available in high-performance
bench top configurations, considerably more compact than air
tables and easy to move around.
#7: Load adjustment
Low-frequency passive vibration isolators are somewhat sensitive
to small changes in weight loads, as well as to Large displacements.
Pneumatic systems utilize leveling valves to mitigate the
problem.
Negative-Stiffness isolators provide a very simple manual
adjustment to accommodate variations in weight loads.
#8: Scanning probe microscopes
Scanning Probe Microscopes (SPMs) have vibration isolation
requirements that are unparalleled in the metrology world.
The vertical axis is the most sensitive for most SPMs. They
can also be quite sensitive to vibrations in the horizontal
axes. In order to achieve the lowest possible noise floor,
on the order of an Angstrom, isolation is always used.
Bench top air systems provide Limited isolation vertically
and very little isolation horizontally. Negative-Stiffness
isolators provide increased isolation performance for SPMs
over air tables, while offering better ease-of-use and no
facility requirements.
#9: Laser/optical equipment
Laser and optical systems, whether used in an academic lab
or in an industrial environment, are very susceptible to vibrations
from the environment. These instruments almost always need
vibration isolation. Traditionally, large air tables have
been the isolators preferred for optical systems, but Negative-Stiffness
isolators are becoming a popular choice. Negative-Stiffness
isolators provide 10 to 100 times the performance of air tables,
depending on the vibration frequency.
Laser based interferometers are extremely sensitive devices
that are capable of resolving nanometer scale motions and
features. They often have very Long mechanical paths which
makes them even more sensitive to vibrations. The sophisticated
modern ellipsometry techniques that allow this high performance
rely on low noise to be able to detect fringe movement. Properly
isolating an interferometer will allow it to provide the highest
possible resolution.
Optical profilers have similar sensitivity to vibrations.
Optical component systems are often quite complex. The long
optical paths can lead to angular magnification of vibrations.
Optical air tables can make the problems worse since they
have a resonant frequency that often matches that of floor
vibrations.
#10: Maintenance and expense
Because Negative-Stiffness isolators utilize simple elastic
structures and viscoelastic materials that deform, their isolation
performance does not degrade with micromotions typical of
laboratory floors and fabrication rooms, as do conventional
pneumatic isolators.
Need for a better solution
The need for vibration isolation will continue to increase
in importance as the precision of research and test applications
embraces smaller and smaller magnitudes of scale.
As industrial researchers and universities continue to broaden
their nano-tech work, necessitating more sensitive equipment
and expanded lab facilities, vibration-handicapped environments
will become more prevalent, and a better vibration isolation
solution will be required than what has been available for
the past almost half-century with air tables. It appears Negative-Stiffness
vibration isolation will fill that void.
For more information on Negative-Stiffness vibration isolators
from Minus K Technology Inc., www.minusk.com
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