|
 Reverse
Engineering
Case Studies
Plaster Disaster
to Digital Master
-- Aft Pylon Fairing --
|
I chose this job as a
case study because it has the full range of reasons, that are common
in the industry, for a part to need reverse engineering. Some of these
reasons are very universal to other industries as well. Some of the
reasons include: |
- The part was created by hand, by master tool-builders, as no CNC machines were
used to cut the profiles.
- Engineering data for the profile was hand drafted on Mylar at
1:1 scale for visual inspection of the rib templates.
- Rib templates are placed on flat tooling plate and set to
specific distances apart, as parallel as possible to each other,
with a grid of thin supports between them.
- Plaster is poured into cavities between rib templates with a thin
sheet of material stretched tightly over the assembly to help form
and retain the plaster.
- After curing, the plaster is hand blended in between the rib
templates to form the final contours.
- There is an incredible amount of man hours and talent invested
in this procedure, and this plaster master engineering tool has
made successful parts for many years. However, there is a fair
amount of hand fitting required to get the individual components
to fit to each other because of the tolerance build-up in each of
the master tools and additional tolerance build up error in the parts
themselves.
|
(Very damaged tool)
|
Well here it
is fresh out of the box, and oh isn't it lovely.;-)
Don't mind
the missing pieces, we'll digitally fill those in later. Notice all the
different colors of plaster, indicating repaired, replaced and or
modified sections in the tool. This tool was part of a joint effort program between the United States and
France, so it's probably seen more miles in transit back an forth than most
Sky miles platinum members, and I'm afraid it's beginning to show. |
The
individual aluminum "loft plates" that basically control or create
the shape, were first hand drafted onto Mylar sheets at a 1 to 1 scale. The aluminum pieces are
then cut and trimmed
to visually match these Mylar "loft curves". The Mylar now
becomes the actual inspection tool for the plates, and thereby
transfers the engineering authority to the "loft plate".
This, of course, cannot be done completely accurately, so in this case we
also want to inspect not only the plaster surfaces, but also the aluminum loft plates
themselves, against the Mylar, this will show the error in the
"loft" plates, which are the basis of the plaster model. To do this
we must first digitize the Mylar sheets. With the sheets being 4' x
16' in length, using a traditional scanner would result in a great
deal of error, so the Laser Tracker is a clean and accurate method
of capturing this legacy data. Once the 2-D data is captured, we then
model the data in 3-D CAD. This is now the most accurate
representation of the original design intent of the part.
We then digitize the aluminum sections of the master tool and compare
them with the nominal Mylar data. |
(Close up of "loft"
plates) |
(CAD model of digitized Mylar
loft data)
|
As you
can see in the picture below, the deviation error (shown in red
+, and blue -) between the nominal
Mylar data and the actual part is very inconsistent. This is as expected when you consider the method of
production, and that the shaping and inspection of the aluminum
"loft" plates
was done visually, by hand. These errors are now forever part of the
master inspection tool and those errors are inherited in the subsequent
parts that this tool inspects.. This is a case where it is not
desirable to simply just reproduce the actual surfaces of the plaster model, this would
also reproduce all the errors and damage that the plaster mould contains, and
make those errors a permanent part of every actual finished part that is made from here on
out. Rather, we should attempt to capture the original intent of the
designers, which in this case is represented on the hand drafted Mylar. |
If there are large errors between the plaster
and the Mylar, we must add a third artifact to help determine which
geometry is correct. This would need to be one of the following:
- An actual part (pylon fairing) that has been proven to fit well
on the aircraft.
- A CAD model of the mating part(s) geometry, or again we could
digitize the mating part(s) if no CAD data were available.
- Data from other hard tooling or jigs that actually were used to
make the most recent successful part.
As no actual parts or mating
part data was available for this project, we turn to the hard tooling
that holds the actual part, and drills all the 5 axis mounting holes
that secure this fairing to the mating pieces. This is called a drill
or jig fixture. Once again, the Laser Tracker shows
excellent capability as a portable co-ordinate measurement machine, or
"portable CMM" to capture the data. |
(Actual error between plates
and Mylar)
|
( Interface drilling fixture) |
After careful evaluation of
all the digitized data, we compile an accurate CAD model that
accurately represents the original engineering intent and also incorporates all
the updates and changes that have been made to the hard tooling and
plaster master since the original Mylar were drawn. This is a far
better solution than simply using any single one of the original
tools and calling that "right" or nominal,
and now all of the storage for all of the associated inspection tools can be
reduced to a simple CD, not to mention we can now modify, reproduce,
and create any of the required geometry at will. |
Finished CAD model
Top
of page
|