The Jet Propulsion Laboratory (JPL) in Pasadena, California, is NASA’s
premier research and development facility. It is staffed and managed by the
California Institute of Technology (Caltech), a leading private university.
Satellites, space telescopes and planetary explorers are designed and built
here. JPL is home to some of the most advanced and capable machine shops in the
country. One of these, the Space Instrument Shop, is very small. It employs
three machinists, houses about a dozen machine tools and is equipped with
various pieces of inspection and measurement technology.
The shop’s mission is to produce components for scientific instruments that
allow space vehicles to gather, analyze and transmit information about the earth
and other parts of our solar system—or beyond. Typically, these are components
that other shops outside of JPL are unable or unwilling to produce. That’s
because machined features on these parts may have dimensions that are fractions
of the width of a human hair and have tolerances as low as ten millionths of an
inch (less than a micron in metric terms).
Prime examples are sub-millimeter microwave blocks that are used to mix or
boost the frequency of microwave signals ranging from 600 gigahertz to 2.5
terahertz. They are critical components in instruments and for applications such
as detecting and measuring the presence of CO2 and other gases in the upper
atmosphere. This information helps monitor climate change or predict weather
patterns.
Finished blocks are roughly the size of a rectangular sugar cube or a pair of
dice. These blocks are produced as a set of perfectly matched halves. When
assembled, the internal features of the mating surfaces include microscopically
small channels and pockets that must line up within 100 millionths of an inch.
The most important features are the wave-guide channels. These are
square-bottomed channels that form contoured paths through which the signals
pass. The walls of the channel must reflect the signals precisely in order to
modify the frequency as intended. The average width of such a channel is 0.002
inch.
For this kind of work, the shop often uses spade-type end mills as small as
0.001 inch wide, although even smaller tools have been used occasionally.
Cutting with end mills of this size is representative of this shop’s capability,
and it gives a glimpse into the world of machining on a microscopic scale. As
parts for medical applications, handheld computer devices and consumer products
become smaller and smaller, other job shops and machining labs will have to
learn many of the lessons that the Space Instrument Shop has already mastered.
 |
| This is how details of the wave-guide channel appear
through a high-powered microscope. The smallest channel is 0.0013 inch wide.
The smallest end mill used was 0.001 inch wide. The heavy black bar across
the top of the image is the profile of a human hair. Photo courtesy of JPL.
|
According to Hal Janzen, shop lead, producing parts with features visible
only with magnification is vastly unlike the world of ordinary machine shop
operations. Procedures for setup, tool-length setting, deburring and other
production steps are rather different. The habits, outlook and discipline of the
shop team are also distinctly characteristic. Formulas for machining parameters,
rules of thumb and expectations that apply in the average shop often do not
apply here. Skill, experience and insight are necessary to work in this shop,
but perhaps more important are a willingness to experiment, the ability to think
creatively and a generous capacity to be patient. “Patience, patience, patience”
is Mr. Janzen’s mantra.
The Pace Defines The Place
The Space Instrument Shop has its own self-contained area in Building 168 at
JPL’s extensive campus, where more than 5,000 are employed. The shop’s work team
consists of two others besides Mr. Janzen, who has 42 years of experience in
machining. Pete Bruneau is a senior machinist with more than 25 years of
machining experience, and David Evans is the “new kid,” having worked in the
shop for only two years following 15 years as a machinist.
 |
| Work at the Space Instrument Shop is highly
collaborative. The team consists of Pete Bruneau (left), Hal Janzen (right)
and David Evans (seated). |
The shop is set apart because the machining techniques and equipment are
unique among those utilized at JPL’s other machine shops. Its location is also
more accessible to the engineers and scientists whose projects involve the Space
Instrument Shop. Interestingly, none of the specialized equipment is so unusual
that other shops would be mystified by the appearance or configuration of the
shop’s vertical machining centers, milling machines and grinders. In many ways,
the Space Instrument Shop looks a lot like an everyday job shop.
What is markedly noticeable is the pace of the work conducted in this shop.
It’s intense but not rushed. “You have to take your time with everything you
do,” Mr. Janzen says. He and his team must go about their procedures
methodically, consistently and very attentively. Successful results are never
guaranteed, and predicting how cutting tools will perform is often impossible.
“This is not a place for the easily frustrated,” Mr. Janzen says.
Yet working here is very rewarding, he contends. One of the roles that this
shop fulfills is to advise some of JPL’s top scientists, researchers and
engineers. They are constantly working to develop systems that are more
powerful, more sensitive or more capable. They come to the Space Instrument Shop
to consult on the manufacturability of new designs. This means that the space
instrument team gets involved in projects in the earliest stages and often sees
them ultimately put into production in their own shop. “We take some of these
innovations from the cradle to the grave,” Mr. Janzen says, but it would be more
accurate if he had said from “sketch pad” to “launch pad.”
Because JPL scientists are interested in higher and higher frequencies for
microwave devices, the designs of the microwave blocks are becoming more
intricate and the necessary internal wave-guide channels must be smaller and
smaller. The Space Instrument Shop is currently getting ready for the next
generation of microwave blocks. As it is, production techniques are already
extreme. Here are some of the key steps in machining these workpieces.
The Same Yet Different
Machining the wave-guide channels and pockets in the blocks is a bit
paradoxical. As Mr. Janzen points out, all of the elements found in an ordinary
machining operation are here. You need the right cutting tool, the right machine
tool, the right setup, the right CNC program, and the right way to apply
coolant. Yet each of these elements is adapted specifically to machining on a
microscopic scale.
Barely Visible Machining
 |
| The shop’s larger VMCs have been modified so that
the machinist can position the column-mounted microscope without
obstruction. Vises and workholding fixtures have been customized for
precise clamping of workpieces, as seen in the photo below. |
 |
One of the first things a visitor notices about each of the Space
Instrument Shop’s two Bostomatic VMCs is the absence of the usual sheet
metal enclosure. These machines were acquired without the enclosures so that
operators would have unencumbered access to the machining zone. Having
“bare” machines allows the operator to use the microscope mounted on an arm
that is attached to the column of the machine. Cutting tools used on these
machines may be as large as a 3/4-inch diameter end mill (a shop-imposed
limit) or as small as a 0.0013 inch end mill (barely visible without
magnification). The microscope is needed to align workpieces, set tool
lengths and monitor cutting with extremely small tools. Because the
microscope is attached to the column, it travels in the X and Y axes with
the cutting tool so that the operator can follow the action during
machining. Using mist coolant makes splash guarding unnecessary.
These machines are the shop’s high speed workhorses. They are 40-taper
models with a 60,000-rpm auxiliary spindle mounted on the side of the
column. Preliminary prepping of the guide blocks is one of the tasks
performed on these machines.
The blocks are machined from bars long enough to accommodate two or three
pairs of half-blocks to assure positional accuracy. The pairs are not
separated from the bar until all other machining operations on the blank
blocks are completed. Wave-guide blocks feature a number of threaded holes
for assembly screws and precision-bored holes for press-fit dowel pins that
maintain the alignment of the blocks when put together. These features are
typically machined to a true position of 0.0004 inch. |
The blocks are produced in two major steps. First, matched sets of
half-blocks are machined on one of the shop’s two Bostomatic VMCs and
precision-ground on an older but well-maintained Thompson surface grinder. The
material is usually a high grade of naval brass alloy. Each side of a block must
be parallel and perpendicular to within 0.00005 inch and each block must be
square to within 0.0001 inch or better. As the box at right shows, preparation
of the blocks is extremely important. Mr. Janzen emphasizes that it sets the
foundation for successful machining in the next step.
In this second step, the wave-guide channels and pockets are machined on
either one of the Bostomatics or a modified three-axis milling machine from
DAC International (Carpinteria,
California). The smallest channels are machined on the DAC. This machine was
originally designed to mill lenses that are surgically implanted in the eye for
vision correction (intraocular lens haptics). The machine is based on a granite
surface plate that is mounted on vibration isolators on a welded steel frame.
The Space Instrument Shop replaced the X, Y and Z slides with high-precision
Schneeberger slides and installed larger servomotors to run at slower feed rates
without overheating. Heidenhain glass scales provide position feedback in
10-nanometer increments. Mr. Bruneau is the chief operator of this machine and
he is responsible for most of the retrofits and enhancements.
Two microscopes are some of the most important features of each milling
machine. One microscope is integrated into the column of the machine so that its
focal point is at a fixed, known distance from the spindle centerline. This
single-eyepiece microscope is used to align the block halves and find their
position relative to the tip of the cutting tool. In the machine jog mode, the
operator touches the tip of the tool to the workpiece surface to create a
witness mark. After jogging the workpiece over to the viewing area under the
microscope, the operator can place the crosshairs on this witness mark and
offset the point coordinates to check the relationship of the cutter tip
centerline and microscope centerline. A similar procedure is used to find the
edges of the blocks and align them so that the blocks are symmetrical to the
home position of the program. This step ensures that any variations in the
workpieces will create mirrored effects in the machined features and still
achieve perfect alignment of these features when the blocks are assembled.
The other microscope is mounted on an adjustable swing-away arm that rides on
a column mounted vertically to the table of the machine. This binocular-style
microscope swings into position to magnify a view of the cutting zone. It is
used to set the length of the cutting tool in the spindle, a process similar to
workpiece alignment. Each click of the jog button advances the Z axis ten
millionths of an inch at a time on the DAC (20 millionths of an inch on the
Bostomatics). Each advance can be observed through the microscope. When the
rotating tool tip makes contact with the workpiece surface, it leaves a circular
mark that is barely visible at 50x magnification. The height in Z at that point
is set as zero tool length and the appropriate offsets can be applied to the
programmed tool path. This microscope is also used to observe the machining
process in action and monitor it for tool breakage or negative cutting
conditions such as raising a heavy burr.
 |
| (top)Pete Bruneau uses the microscope integrated to
the column of the DAC milling machine for setup. (bottom) A second
microscope mounted to the table allows him to observe the machining
operation in progress. |
The shop produces its own end mills with diameters less than 0.002 inch
(larger sizes are acquired from vendors.) Starting with commercially available
blanks of super-fine-grain carbide, these end mills are ground on an Ewag WS11
tool grinder (United
Grinding, Miamisburg, Ohio). All are two-flute, spade-type end mills with
relief angles on the side cutting edges and at the center of the bottom edge to
avoid a dead spot. The photograph (below, right) shows a profile of this end
mill design. After grinding, the tools are inspected on a Nikon measuring
microscope to check for excessive runout (any total above 0.0001 inch is
unacceptable).
Tool paths to machine the wave-guide channels are generated with Esprit CAM
software from DP Technology
(Camarillo, California). The shop uses this software because cutter paths must
be postprocessed to six decimal places. Otherwise, inherent programming error
would exceed the resolution of the machine’s positioning system. According to
Mr. Janzen, cutter path geometry of the channels is usually programmed 0.00015
inch undersized to allow for runout in the end mill.
Although the DAC has an electric air-bearing spindle capable of 120,000 rpm,
the shop finds that 90,000 rpm is a practical upper limit. For a 0.001-inch end
mill, feed rates are as low as 0.1 ipm. An atomized mist of vegetable oil-based
coolant provides lubrication, cooling and chip removal. Proper application of
the mist is no trivial matter, Mr. Janzen says.
When machining is completed, the blocks are deburred by hand at a bench under
a microscope. Burrs are gently removed with the ground tip of a bamboo chopstick
or other type of wood. All edges must be dead sharp. No nicks or edge rollover
is allowed. The edges can’t be touched by human hands at this point, Mr. Janzen
says, because particles of skin left behind by contact can damage mating
surfaces when the blocks are assembled.
 |
| The tip of this end mill is 0.001 inch wide. The inset
shows the tip head on, revealing the relief angles on the sides and at the
center. Photo courtesy of JPL. |
After deburring, the blocks are cleaned ultrasonically and inspected on the
Nikon measuring microscope. “This is when we discover where the cutting tool may
have overshot an inside corner or violated and edge in the test cut,” Mr. Janzen
explains. Programmed feed rates can be adjusted to correct for errors. Even when
the team is confident about the process, several sets of blocks may have to be
machined to yield one that is acceptable for delivery to final assembly.
Seven Effective Habits
Although this simplified de scri ption of microwave block machining seems
straightforward, Mr. Janzen cautions against that assumption. There aren’t any
handbooks or tables to consult when unfamiliar cutting conditions are
encountered or when familiar conditions yield unexpected results.
Trial-and-error experimentation is sometimes the only option, he says.
Nevertheless, Mr. Janzen emphasizes that good habits need to be cultivated to
maximize the shop’s overall success rate. The shop has its own tips for
achieving good results and follows them rigorously. Some of the most important
items are:
1. Check, check, check. Mr. Janzen and his team purposefully
review every step of each procedure to be sure it has been conducted properly.
Following mental checklists becomes second nature. Members of the team review
activities together to get a fresh perspective. “Everything is important; no
detail can be neglected,” Mr. Janzen says.
 |
| Hal Janzen uses the Ewag cutter grinder to produce the
smallest end mills used in the shop. This work is done with the aid of a
microscope. Everyone in the shop has “trained their eyes” to recognize and
identify objects under magnification. |
2. Cleanliness counts. For example, every time a tool
assembly or setup is taken apart, each component gets an alcohol wipe before
being put back together.
3. Keep machines calibrated. Every machine tool in the shop
is laser-calibrated at least once every six months. Even the two Bridgeport knee
and column mills used for simple jobs and utility work are “lasered” on a
regular basis. The aim of adjustments and realignments is to maintain a like-new
or better performance. “You have to have a service provider that understands
this goal,” Mr. Janzen says. The shop has been working with Lasers Inc. of
nearby Glendora, California, for this service.
4. Spread the work around. To avoid concentrating wear in
one part of a machine’s work zone, jobs are set up at different spots on the
table. Don’t leave heavy vises or clamping fixtures where the machine has an
overhang.
5. Test, inspect, analyze and adjust. That’s how the shop
learns from every critical machining operation, and the shop never misses a
learning opportunity. Projects are planned and reviewed collaboratively so that
the whole team benefits. Logbooks and documentation can capture important
information, but experience is the best teacher, Mr. Janzen notes.
6. Keep the lights on. The Space Instrument Shop never goes
dark because heat from ceiling lights affects ambient shop temperature.
High-intensity task lighting is turned off quickly when not needed because small
tools and workpieces can absorb heat rapidly. Holding a constant temperature is
the main thing.
Don’t Worry. Be Humble.
7. There is a lot to be humble about. “We are always looking
for new tools, new techniques and new thinking,” Mr. Janzen says. He and his
team are aware that they are only a small step ahead of what the researchers and
scientists will want them to produce. Being constantly on the edge, however, is
never boring.
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