[DeTomaso] help searching (powder coat campys)

[MikeLDrew at aol.com]

In a message dated 5/26/16 7:58:20 PM, detomaso at server.detomasolist.com 
writes:


> Larry,
> 
> I've still got the story on my computer. I can post it when I land 
> tonight.
> 

>>>Found it, and text is posted below.

It's worth mentioning that I have a set of Larry's wheels on the front of 
my car now.   However, he goofed up and selected a way wrong color (DOH) so I 
had to have them painted atop the powdercoating.   They are bulletproof now 
I think!   Going forward, I would hope anybody who is contemplating doing 
this sort of thing will take the extra time to research the color and ensure 
tha it is what you want it to be....

BTW one of the really nice things about this list format is that I can whip 
out my phone while dashing through the airport between flights and quickly 
get caught up, whereas with a web-based forum I would realistically have to 
stop and break out my computer, get onto a WiFi network, and then wait for 
ages for huge pages to load.   So thank goodness that the REAL forum is alive 
and well!

Article text below.   Note that this was written almost 20 years ago, and 
at this point should serve as the starting point for a conversation rather 
than being treated as though the words were taken from a burning bush....

Cheers!

Mike

====


Restoring Magnesium Campagnolo Wheels the Right Way

The Pantera was delivered wearing Campagnolo wheels cast in exotic 
magnesium alloy.   Campagnolo is a very old company in Italy, and the methods they 
used were the tried-and-true types right out of the dawn of the Industrial 
Revolution.   Thus, our magnesium wheels were cast in molds hand-carved from 
mahogany!   

Naturally, wooden molds, however hard, could only withstand a limited 
number of times that molten metal could be poured into them before sharp details 
were blurred.   Eventually, these details were lost, and casting quality 
began to drop off as well so the mold would be scrapped.   This short life of 
the wheel molds may in fact be the reason there are at least four separate 
models of Pantera wheels that are known to have been shipped at various times 
during the life of the DeTomaso/Ford joint project in the '70's.

In the meantime, Campagnolo as a company was going through changes.   The 
light-alloy bicycle accessory business was spun off in the '70's, the wheel 
company was sold (but kept its name the first two times), and new management 
were brought in after being taken over by Technomagnesio (one of 
Campagnolo's chief rivals in the alloy-wheel business).   

Finally, the magnesium wheels made late in the Pantera project were 
pressure-die-cast.   This method is where the molten metal is literally pumped into 
steel dies under relatively high pressure.   The metallic dies are much 
more expensive than the old mahogany ones, but they also last much longer, 
quality is higher and the higher pressure during the metal solidification 
results in a denser casting with fewer, smaller pore areas.   Intuitively one 
would expect that the very late Campy wheels are stronger for these reasons.

Magnesium, the lightest structural metal known, has one desirable and 
several not-so-desirable attributes.   On the plus side, it is only 65% as heavy 
as aluminum while having as much strength as the better aluminum casting 
alloys, meaning it can be heat-treated and welded like aluminum.   

On the debit side, magnesium is a 'reactive' metal: when magnesium contacts 
plain water or even moisture in the air, a chemical reaction occurs that 
results in the outgassing of hydrogen gas from the water molecule; the l
eftover oxygen combines with magnesium to produce the familiar white mag-oxide 
powder.   If left exposed, Campy wheels will literally dissolve into powder!

At 650 degrees Centigrade, magnesium burns in air at such high temperatures 
that most substances in contact with it melt or burn as well.   Large 
chunks are difficult to catch on fire but grindings or shavings should be treated 
like gunpowder-and definitely kept dry!   Fine mag metal powder will react 
hydrogen gas off so quickly, the gas spontaneously lights off, catching the 
rest of the metal on fire.   Naturally, pouring water on a mag fire will 
result in a hydrogen explosion (remember the Hindenburg?) and even more fire!   
Sand or dry-chemical extinguishers are the only hope for stopping a 
magnesium fire.   In fact, it may be best to simply stand back and let it burn 
itself out....

Magnesium alloys have the property of age-hardening-that is, a mag   
casting will get harder and progressively more brittle as it gets older, 
regardless of its use or storage.   Magnesium expands some 2-1/2 times as much as 
aluminum when heated.   This means that for best results, the casting must be 
physically restrained-bolted down-before heating or it will literally 'crawl 
away' from the welding torch!   

And due to its very light density, magnesium castings, especially open-mold 
castings, tend to be porous, or at least have very large crystalline areas. 
  All wheels flex and bend slightly in use.   Magnesium flexes too, but the 
flex-energy is not dissipated 100%.   Instead, stresses build up inside the 
castings, eventually concentrating at an imperfection such as a casting 
pore or a crystal grain.   Such an area will eventually separate and connect 
with another pore or weak spot.   A few more cycles of this and you have a 
crack growing in the casting, with the accumulated stresses concentrating at 
the point-ends of the crack.   This process works exactly like a micro 
pry-bar!

Detecting cracks in mag castings cannot be done by conventional magneflux: 
magnesium is totally non-magnetic.   So a fluorescent dye called Zyglow is 
dissolved in a very thin solvent like petroleum ether.   The casting is 
dipped in the solvent, left for a few moments, then wiped off.   A spray cleaner 
is used to further clean the casting.   Any cracks or deep pores will retain 
some of the dye, however.   Illuminating the casting with near-ultraviolet 
light will show up any retained dye.   

Porous, rough castings like our wheels require someone talented in the art 
of interpreting florescent patterns that show up.   The layman could look at 
a perfectly good cast-mag wheel glowing in numerous areas and be afraid to 
mount a tire on it!   X-ray casting checks can also be done but are even 
more expensive, require more highly trained operators to evaluate the film 
records and are sometimes inconclusive, requiring a dye-check to be sure!

Cracked magnesium castings should only be welded after stop-drilling both 
ends of a detected crack.   This is a technique whereby the crack is outlined 
and a small hole drilled through the casting just in front of each end of 
the crack, not in the crack itself.  This is so when welding or grinding heat 
is applied, any growth of the crack will expand into the drill-hole rather 
than continuing to tear the base metal apart at the front of the crack.   
Then, the entire cracked area is V-ground away to prevent the crack from 
progressing sideways, and to provide clean metal to weld on.   The V-groove is 
also necessary since vertical cracks in thicker sections don't weld very well. 
  

Remember the cautions regarding the dangers of accumulations of grinding or 
drilling chips from magnesium repairs!   Magnesium welding is best done 
only by an expert, with lots of experience and understanding of the nuances of 
magnesium welding.   The incautious can very easily start a fire that will 
literally consume everything in its reach-including your house, garage and 
Pantera!

And surprisingly enough, the act of welding or grinding a casting induces 
even more stresses, so the repaired casting must be stress-annealed.   This 
literally bakes out the accumulated stresses or any additional ones from the 
repairs and results in a like-new wheel that has many more years of safe 
driving left.   

Fortunately, the annealing temperature (recommended by aerospace users of 
magnesium) is only 350-375 degrees Fahrenheit.   The piece is put into an 
oven, heated to 350-375 degrees, held for an hour or so, then very slowly 
cooled to room temperature-the slower the better!   Ideally, the heavily 
insulated oven is simply turned off and left closed until the next morning.   If the 
oven cannot be turned off, wrap the hot casting in thick blankets and leave 
it undisturbed for at least several hours.   Note-this will discolor any 
silver finishes painted onto the wheels.   Do the decorative painting last!

After the wheel is cast or weld-repaired, if it is to be painted it must 
first be protected from moisture in the air by painting it with a zinc 
chromate solution.   The zinc chromate reacts with the magnesium to produce a 
barrier layer that tends to be self-healing to small scratches-the zinc chromate 
literally spreads across the scratch, again protecting the underlying metal; 
not as well as a full-thickness coating, but at least there is some 
protection!   Zinc chromate is widely used in the aviation industry, and should be 
available at better paint stores, as well as at any municipal airport repair 
facility.

Bare wheels that are simply painted with conventional primers and paint may 
trap moisture between the wheel and paint, resulting in corrosion under the 
paint, which eventually shows up in the form of bubbles in the paint.   

In recent years, it has become very fashionable to powdercoat (or 
powderpaint) wheels rather than painting them.   The resultant finish can be superior 
to paint, but only if the wheel is correctly prepared.   Some people simply 
strip the old paint and then apply a coating of powderpaint, without 
actually repairing any damage to the surface, or checking the structural integrity 
of the wheel.   When powderpainted in this fashion, often the wheel will 
out-gas during the painting process, leading to bubbles in the finish.

Larry Stock of the Pantera Parts Connection found himself with a collection 
of Campy wheels from various sources, some of dubious ancestry (including 
Mike Drew's old wheels!)   Even though modern 17” wheels and tires are all 
the rage right now, he has found there are a select group of individuals who 
are looking for the best possible original factory wheels, and he set about 
taking these cast-offs and bringing them up to better-than-new specification. 
  

The wheels were first carefully bead-blasted to remove all the old paint 
and underlying zinc chromate.   The blasting process also removed any 
oxidation which might have accumulated.   Afterwards, the wheels were annealed at 
375 degrees in a large oven, which was allowed to slowly cool overnight.

>From there, the wheels were hauled to a sophisticated testing facility used 
by NASA and Lockheed Aerospace.   The wheels were dipped in a liquid 
penetrant (Zyglow), then rinsed off and evaluated for possible cracks and 
imperfections.   Any such imperfections were clearly marked, and one wheel was 
condemned and ultimately discarded.

Once the faults were identified, the wheels were then transported to a NASA 
welder who carefully welded up damaged areas of the wheels.   While none of 
the wheels exhibited any significant cracks, several had large hunks 
missing from the lip of the rim.   These were caused by the fitment of 
conventional wheel weights.   The metal in the wheel weights reacts with the magnesium, 
turning it to powder.   Tire-shop monkeys who traditionally remove old 
weights by hitting them with a hammer as often as not remove the lip of the 
wheel as well!   For these reasons, whenever possible stick-on wheel weights 
should be used instead of clamp-on weights.

The welder went out of his way to put excess material back into the wheels, 
so now they needed to be brought back into spec.   But before any machining 
would take place, they were returned to the oven and annealed again, to 
restore whatever strength might have been compromised by the application of 
high heat in only one area of the wheel.

Larry then took them to his fully-equipped machine shop.   A rear 
axle/brake disc/stud assembly was inserted into a large lathe, and the wheels were 
bolted to the axle.   Then sophisticated cutting tools were used to carefully 
remove the excess material and restore the original contours of the wheel.   
The average wheel required two full hours of machining in this fashion.

Of course, machining introduces its own heat factors, so back into the oven 
they went!   After annealing, the powderpainters sprayed on silver 
powderpaint, which had been carefully color- and texture-matched with an original, 
mint-condition factory painted wheel.   Back into the oven to bake the silver 
paint on, and anneal the wheels again!   Finally, a protective clear-coat 
was powderpainted atop the silver, then the wheels went back into the oven 
for the final time.

The resulting wheels are absolutely flawless, exquisitely beautiful, and 
literally much better and stronger than new.   The entire process was 
extremely labor-intensive and took almost six weeks to accomplish.  Larry now has 
several full sets of early-style (Pre-L) wheels and a few L-model wheels in 
stock, which he'll sell for $325 each with the exchange of your old wheels.   
Alternately, he can have your existing wheels repaired for $325 each.

Thanks to Larry Stock for providing the step-by-step photographs of the 
Pantera wheel restoration process.


-------------- next part --------------
   In a message dated 5/26/16 7:58:20 PM, detomaso at server.detomasolist.com
   writes:

     Larry,
     I've still got the story on my computer. I can post it when I land
     tonight.

   >>>Found it, and text is posted below.
   It's worth mentioning that I have a set of Larry's wheels on the front
   of my car now.  However, he goofed up and selected a way wrong color
   (DOH) so I had to have them painted atop the powdercoating.  They are
   bulletproof now I think!  Going forward, I would hope anybody who is
   contemplating doing this sort of thing will take the extra time to
   research the color and ensure tha it is what you want it to be....
   BTW one of the really nice things about this list format is that I can
   whip out my phone while dashing through the airport between flights and
   quickly get caught up, whereas with a web-based forum I would
   realistically have to stop and break out my computer, get onto a WiFi
   network, and then wait for ages for huge pages to load.  So thank
   goodness that the REAL forum is alive and well!
   Article text below.  Note that this was written almost 20 years ago,
   and at this point should serve as the starting point for a conversation
   rather than being treated as though the words were taken from a burning
   bush....
   Cheers!
   Mike
   ====
   Restoring Magnesium Campagnolo Wheels the Right Way
   The Pantera was delivered wearing Campagnolo wheels cast in exotic
   magnesium alloy.  Campagnolo is a very old company in Italy, and the
   methods they used were the tried-and-true types right out of the dawn
   of the Industrial Revolution.  Thus, our magnesium wheels were cast in
   molds hand-carved from mahogany!
   Naturally, wooden molds, however hard, could only withstand a limited
   number of times that molten metal could be poured into them before
   sharp details were blurred.  Eventually, these details were lost, and
   casting quality began to drop off as well so the mold would be
   scrapped.  This short life of the wheel molds may in fact be the reason
   there are at least four separate models of Pantera wheels that are
   known to have been shipped at various times during the life of the
   DeTomaso/Ford joint project in the '70's.
   In the meantime, Campagnolo as a company was going through changes.
   The light-alloy bicycle accessory business was spun off in the '70's,
   the wheel company was sold (but kept its name the first two times), and
   new management were brought in after being taken over by Technomagnesio
   (one of Campagnolo's chief rivals in the alloy-wheel business).
   Finally, the magnesium wheels made late in the Pantera project were
   pressure-die-cast.  This method is where the molten metal is literally
   pumped into steel dies under relatively high pressure.  The metallic
   dies are much more expensive than the old mahogany ones, but they also
   last much longer, quality is higher and the higher pressure during the
   metal solidification results in a denser casting with fewer, smaller
   pore areas.  Intuitively one would expect that the very late Campy
   wheels are stronger for these reasons.
   Magnesium, the lightest structural metal known, has one desirable and
   several not-so-desirable attributes.  On the plus side, it is only 65%
   as heavy as aluminum while having as much strength as the better
   aluminum casting alloys, meaning it can be heat-treated and welded like
   aluminum.
   On the debit side, magnesium is a 'reactive' metal: when magnesium
   contacts plain water or even moisture in the air, a chemical reaction
   occurs that results in the outgassing of hydrogen gas from the water
   molecule; the leftover oxygen combines with magnesium to produce the
   familiar white mag-oxide powder.  If left exposed, Campy wheels will
   literally dissolve into powder!
   At 650 degrees Centigrade, magnesium burns in air at such high
   temperatures that most substances in contact with it melt or burn as
   well.  Large chunks are difficult to catch on fire but grindings or
   shavings should be treated like gunpowder-and definitely kept dry!
   Fine mag metal powder will react hydrogen gas off so quickly, the gas
   spontaneously lights off, catching the rest of the metal on fire.
   Naturally, pouring water on a mag fire will result in a hydrogen
   explosion (remember the Hindenburg?) and even more fire!  Sand or
   dry-chemical extinguishers are the only hope for stopping a magnesium
   fire.  In fact, it may be best to simply stand back and let it burn
   itself out....
   Magnesium alloys have the property of age-hardening-that is, a mag
   casting will get harder and progressively more brittle as it gets
   older, regardless of its use or storage.  Magnesium expands some 2-1/2
   times as much as aluminum when heated.  This means that for best
   results, the casting must be physically restrained-bolted down-before
   heating or it will literally 'crawl away' from the welding torch!
   And due to its very light density, magnesium castings, especially
   open-mold castings, tend to be porous, or at least have very large
   crystalline areas.  All wheels flex and bend slightly in use.
   Magnesium flexes too, but the flex-energy is not dissipated 100%.
   Instead, stresses build up inside the castings, eventually
   concentrating at an imperfection such as a casting pore or a crystal
   grain.  Such an area will eventually separate and connect with another
   pore or weak spot.  A few more cycles of this and you have a crack
   growing in the casting, with the accumulated stresses concentrating at
   the point-ends of the crack.  This process works exactly like a micro
   pry-bar!
   Detecting cracks in mag castings cannot be done by conventional
   magneflux: magnesium is totally non-magnetic.  So a fluorescent dye
   called Zyglow is dissolved in a very thin solvent like petroleum
   ether.  The casting is dipped in the solvent, left for a few moments,
   then wiped off.  A spray cleaner is used to further clean the casting.
   Any cracks or deep pores will retain some of the dye, however.
   Illuminating the casting with near-ultraviolet light will show up any
   retained dye.
   Porous, rough castings like our wheels require someone talented in the
   art of interpreting florescent patterns that show up.  The layman could
   look at a perfectly good cast-mag wheel glowing in numerous areas and
   be afraid to mount a tire on it!  X-ray casting checks can also be done
   but are even more expensive, require more highly trained operators to
   evaluate the film records and are sometimes inconclusive, requiring a
   dye-check to be sure!
   Cracked magnesium castings should only be welded after stop-drilling
   both ends of a detected crack.  This is a technique whereby the crack
   is outlined and a small hole drilled through the casting just in front
   of each end of the crack, not in the crack itself. This is so when
   welding or grinding heat is applied, any growth of the crack will
   expand into the drill-hole rather than continuing to tear the base
   metal apart at the front of the crack.  Then, the entire cracked area
   is V-ground away to prevent the crack from progressing sideways, and to
   provide clean metal to weld on.  The V-groove is also necessary since
   vertical cracks in thicker sections don't weld very well.
   Remember the cautions regarding the dangers of accumulations of
   grinding or drilling chips from magnesium repairs!  Magnesium welding
   is best done only by an expert, with lots of experience and
   understanding of the nuances of magnesium welding.  The incautious can
   very easily start a fire that will literally consume everything in its
   reach-including your house, garage and Pantera!
   And surprisingly enough, the act of welding or grinding a casting
   induces even more stresses, so the repaired casting must be
   stress-annealed.  This literally bakes out the accumulated stresses or
   any additional ones from the repairs and results in a like-new wheel
   that has many more years of safe driving left.
   Fortunately, the annealing temperature (recommended by aerospace users
   of magnesium) is only 350-375 degrees Fahrenheit.  The piece is put
   into an oven, heated to 350-375 degrees, held for an hour or so, then
   very slowly cooled to room temperature-the slower the better!  Ideally,
   the heavily insulated oven is simply turned off and left closed until
   the next morning.  If the oven cannot be turned off, wrap the hot
   casting in thick blankets and leave it undisturbed for at least several
   hours.  Note-this will discolor any silver finishes painted onto the
   wheels.  Do the decorative painting last!
   After the wheel is cast or weld-repaired, if it is to be painted it
   must first be protected from moisture in the air by painting it with a
   zinc chromate solution.  The zinc chromate reacts with the magnesium to
   produce a barrier layer that tends to be self-healing to small
   scratches-the zinc chromate literally spreads across the scratch, again
   protecting the underlying metal; not as well as a full-thickness
   coating, but at least there is some protection!  Zinc chromate is
   widely used in the aviation industry, and should be available at better
   paint stores, as well as at any municipal airport repair facility.
   Bare wheels that are simply painted with conventional primers and paint
   may trap moisture between the wheel and paint, resulting in corrosion
   under the paint, which eventually shows up in the form of bubbles in
   the paint.
   In recent years, it has become very fashionable to powdercoat (or
   powderpaint) wheels rather than painting them.  The resultant finish
   can be superior to paint, but only if the wheel is correctly prepared.
   Some people simply strip the old paint and then apply a coating of
   powderpaint, without actually repairing any damage to the surface, or
   checking the structural integrity of the wheel.  When powderpainted in
   this fashion, often the wheel will out-gas during the painting process,
   leading to bubbles in the finish.
   Larry Stock of the Pantera Parts Connection found himself with a
   collection of Campy wheels from various sources, some of dubious
   ancestry (including Mike Drew's old wheels!)  Even though modern 17a
   wheels and tires are all the rage right now, he has found there are a
   select group of individuals who are looking for the best possible
   original factory wheels, and he set about taking these cast-offs and
   bringing them up to better-than-new specification.
   The wheels were first carefully bead-blasted to remove all the old
   paint and underlying zinc chromate.  The blasting process also removed
   any oxidation which might have accumulated.  Afterwards, the wheels
   were annealed at 375 degrees in a large oven, which was allowed to
   slowly cool overnight.
   From there, the wheels were hauled to a sophisticated testing facility
   used by NASA and Lockheed Aerospace.  The wheels were dipped in a
   liquid penetrant (Zyglow), then rinsed off and evaluated for possible
   cracks and imperfections.  Any such imperfections were clearly marked,
   and one wheel was condemned and ultimately discarded.
   Once the faults were identified, the wheels were then transported to a
   NASA welder who carefully welded up damaged areas of the wheels.  While
   none of the wheels exhibited any significant cracks, several had large
   hunks missing from the lip of the rim.  These were caused by the
   fitment of conventional wheel weights.  The metal in the wheel weights
   reacts with the magnesium, turning it to powder.  Tire-shop monkeys who
   traditionally remove old weights by hitting them with a hammer as often
   as not remove the lip of the wheel as well!  For these reasons,
   whenever possible stick-on wheel weights should be used instead of
   clamp-on weights.
   The welder went out of his way to put excess material back into the
   wheels, so now they needed to be brought back into spec.  But before
   any machining would take place, they were returned to the oven and
   annealed again, to restore whatever strength might have been
   compromised by the application of high heat in only one area of the
   wheel.
   Larry then took them to his fully-equipped machine shop.  A rear
   axle/brake disc/stud assembly was inserted into a large lathe, and the
   wheels were bolted to the axle.  Then sophisticated cutting tools were
   used to carefully remove the excess material and restore the original
   contours of the wheel.  The average wheel required two full hours of
   machining in this fashion.
   Of course, machining introduces its own heat factors, so back into the
   oven they went!  After annealing, the powderpainters sprayed on silver
   powderpaint, which had been carefully color- and texture-matched with
   an original, mint-condition factory painted wheel.  Back into the oven
   to bake the silver paint on, and anneal the wheels again!  Finally, a
   protective clear-coat was powderpainted atop the silver, then the
   wheels went back into the oven for the final time.
   The resulting wheels are absolutely flawless, exquisitely beautiful,
   and literally much better and stronger than new.  The entire process
   was extremely labor-intensive and took almost six weeks to accomplish.
   Larry now has several full sets of early-style (Pre-L) wheels and a few
   L-model wheels in stock, which he'll sell for $325 each with the
   exchange of your old wheels.  Alternately, he can have your existing
   wheels repaired for $325 each.
   Thanks to Larry Stock for providing the step-by-step photographs of the
   Pantera wheel restoration process.