| The March
1998 issue of GEARS magazine contained an article concerning
crankshaft thrust failure titled "Crankshaft Thrust Bearing
Failure: Causes and Remedies." This article was the result
of several technical experts from various organizations.
This is a reprint of the original copyrighted article.
Companies wishing to reproduce this article may do so
as long as credit is given to ATRA, GEARS and the contributing
authors and they receive written permission. To receive
permission to reproduce additional copies of "Crankshaft
Thrust Bearing Failure: Causes and Remedies" please contact
me personally at: ATRA, Attn: Dennis Madden, 2400 Latigo
Ave, Oxnard, CA, 93030.
For years, both transmission and engine rebuilders have
struggled with the problem of crankshaft thrust bearing
failure. In most cases it becomes a battleground, with
both parties throwing rocks at each other. To compound
this problem, many so-called "experts" have offered explanations
that have no basis whatsoever as to the actual cause.
Many of these explanations have simply fanned the flames,
causing most of these cases to end up in court, with the
truth still lingering in the background. In this reprint
from GEARS, ATRA, AERA (Automotive Engine Rebuilders Association),
ASA (Automotive Service Association), PERA (Production
Engine Remanufacturers Association) and AE Clevite have
joined forces to finally offer solutions that are not
only based on fact, but also cover many of the misconceptions
that have found their way into the industry. I would like
to offer a special thanks to Dave Hagen of AERA, ED Anderson
of ASA, Roy Berndt of PERA and John Havel of AE Clevite
for their contributions and efforts toward this cause.
   
Crankshaft
Thrust Bearing Failure:
Causes and Remedies
Although thrust bearings run on a thin film of oil, just
like radial journal (connecting rod and main) bearings,
thrust bearings can't support nearly as much load. While
radial bearings can carry loads measured in thousands
of pounds per square inch of projected bearing area, thrust
bearings can only support loads of a few hundred pounds
per square inch.
Radial journal bearings develop their higher load capacity
from the way the curved surfaces of the bearing and journal
meet to form a wedge. Shaft rotation pulls oil into this
wedge-shaped area of the clearance space to create an
oil film which actually supports the shaft.
Thrust bearings typically consist of two flat mating
surfaces, with no natural wedge shape in the clearance
space to allow an oil film to form, and support the load.
Conventional thrust bearings are made by adding flanges
at the ends of a radial journal bearing. This provides
ease in assembly and has been used successfully for many
years. Both teardrop or through grooves on the flange
face, and wedge shaped ramps at each parting line, allow
oil to enter between the shaft and bearing surfaces.
But the surface of the shaft and the vast majority of
bearing surfaces are flat. This flatness makes it more
difficult to create and maintain an oil film. For example,
suppose two gauge blocks had a thin film of oil on them.
If you were to press them together with a twisting action,
the blocks would stick together.
This is similar to what happens when a thrust load is
applied to the end of a crankshaft: Oil squeezes out from
between the shaft and bearing surfaces. If there's too
much load, the oil film collapses and the surfaces want
to stick together, which causes a wiping action, and ultimately,
bearing failure.
This is why many heavy-duty diesel engines use separate
thrust washers, each with a contoured face: to enable
them to support higher thrust loads. These thrust washers
either have multiple tapered ramps and relatively small
flat pads, or they have curved surfaces that follow a
sine-wave contour around the outer edge.
Recent Developments
In the past few years, some new automotive engine designs
have included contoured thrust bearings. This change enables
them to carry higher thrust loads imposed by some of the
newer automatic transmissions. Since it's impractical
to use contoured faces on one-piece flanged thrust bearings,
these new engine designs use either separate thrust washers,
or a flanged bearing, which is a three-piece assembly.
Cause of Failure
Aside from the obvious causes, such as dirt contamination
and misassembly, there are only three common factors which
generally cause thrust bearing failures:
- Poor crankshaft surface finish
- Misalignment
- Overloading
Surface Finish
Crankshaft thrust faces are difficult to grind because
they are done using the side of the grinding wheel. Grinding
marks left on the crankshaft face produce a visual swirl,
or sunburst pattern. The scratches sometimes crisscross
one another in a cross-hatch pattern similar to hone marks
on a cylinder wall.
If these grinding marks are not completely removed by
polishing, they will remove the oil film from the surface
of the thrust bearing, much like multiple windshield wiper
blades. A properly-finished crankshaft thrust face should
have only very fine polishing marks that go around the
thrust surface in a circular pattern.
Alignment
Under normal circumstances, a remanufactured crankshaft
does not require grinding of the thrust face surfaces.
There are, however, situations where grinding is necessary.
One is the automatic oversize of a thrust flange main
bearing, required by using undersized crankshaft main
journals.
A second occurs when thrust surface wear (front and rear)
is beyond allowable specifications. This situation often
requires an oversize thrust flange bearing or washer,
if one is available for that application. Under these
conditions, the thrust face of the crankshaft will require
oversize grinding. In this case, crankshaft end float
should be calculated and determined prior to grinding
additional material from the thrust face.
Grinding the thrust face of the crankshaft presents a
challenge, because the crankshaft remanufacturer has to
use the side of the grinding wheel, which is not specifically
designed for metal surface removal.
In addition, keeping enough coolant between the thrust
surface and the wheel (just as keeping oil for lubrication
within the engine) is difficult, and that combination
creates a danger of wheel loading and burn spots. The
result: an inconsistent thrust surface. To avoid this
situation, the grinding wheel must be dressed periodically,
to maintain a 90° angle, perpendicular to the
centerline of the grinding wheel. This transfers to the
same 90° angle between the thrust surface and
the centerline of the crankshaft.
During the grinding process, the grinding wheel must
feed into the thrust face very slowly and be allowed to
spark out completely. If the grinding wheel does not cut
cleanly, it may create hot spots on the crankshaft, leading
to a wavy, out-of-flat surface. It is important to avoid
excessive grinding of the thrust surface; this procedure
is intended primarily for surface clean up.
When Assembling Thrust Bearings:
• Tighten the main cap bolts to about 10 to 15 ft-lbs
in order to seat the bearings; then loosen the cap bolts.
• Tap the main cap toward the rear of the engine with
a soft faced hammer.
• Thread the main cap bolts in finger tight.
• Use a bar to force the crankshaft as far forward in
the block as possible, to align the bearing rear thrust
faces.
• While holding the crankshaft forward, tighten the main
cap bolts to 10 to 15 ft-lbs.
• Complete tightening the main cap bolts to specifications
in two or three equal steps.
This procedure should align the bearing thrust faces
with the crankshaft, to provide the maximum bearing contact
for load carrying.
Loading
A number of factors may contribute to wear and overloading
of a thrust bearing, such as:
1. Poor crankshaft surface finish
2. Poor crankshaft surface geometry
3. External overloading due to:
a) Too much torque converter pressure.
b) Improper clutch release bearing adjustment.
c) Riding the clutch pedal.
d) Excessive crankshaft load pressure due to a malfunctioning
front-mounted accessory drive.
Note:
There are other, commonly-thought issues such as torque
converter ballooning, the wrong flexplate bolts, the wrong
torque converter, the pump gears being installed backward
or the torque converter not installed completely. Although
all of these problems will cause undue force on the crankshaft
thrust surface, it will also cause the same force on the
pump gears, since all of these problems will put equal
force in both directions from the torque converter. So
any of these conditions should also cause serious pump
damage very quickly (within minutes or hours).
Diagnosing the Problem
By the time a thrust bearing failure becomes evident,
the parts have usually been so severely damaged there's
little if any evidence of the cause. The bearing is generally
worn into the steel backing, which has severely worn the
crankshaft thrust face as well. The following is a list
of factors to consider while diagnosing the cause.
Engine-Related Problems
Is there evidence of distress anywhere else in the engine
that would indicate a lubrication problem or foreign particle
contamination?
Were the correct bearing shells installed, and were they
installed correctly?
If the thrust bearing is in an end position, was the adjacent
oil seal installed correctly? An incorrectly installed
rope seal can cause enough heat to affect bearing lubrication.
Examine the front thrust face on the crankshaft for surface
finish and geometry. This may give an indication of the
original quality of the failed face.
Once you're satisfied that all potential internal sources
have been eliminated, ask about potential external sources,
such as overloading or misalignment.
Transmission Related Problems
- Did the engine have a prior thrust bearing failure?
- What external parts were replaced?
- Were any performance modifications made to the transmission?
- Was an additional cooler installed for the transmission?
- Was the correct flexplate used? At installation, there
should be at least 1/16" (1/8" preferred, 3/16" maximum)
clearance between the flexplate and converter, to allow
for converter expansion.
- Was the transmission aligned to the engine properly?
- Were all dowel pins in place?
- Was the transmission-to-cooler pressure too high?
If the return line has very low pressure compared to
the transmission-to-cooler line, check for a restricted
cooler or cooler lines.
- If a manual transmission was installed, was the clutch
release bearing adjusted properly?
- What condition was the clutch release bearing in?
A worn or overheated clutch release bearing that's adjusted
properly may indicate the operator was "riding the clutch."
How does the Torque Converter Exert Force on
the Crankshaft?
There are many theories on this subject, ranging from
converter ballooning to spline lock. Most of these theories
have little real basis, and rely little on fact.
The force on the crankshaft from the torque converter
is simple: It's based on the same principle as a servo
piston or any other hydraulic component: Pressure, multiplied
by area, equals force.
The pressure part is easy: It's simply the internal torque
converter pressure. The area is a little more tricky.
The area that's part of this equation is the difference
between the area of the front half of the converter and
the rear half. The oil pressure does exert a force that
tries to expand the converter like a balloon (which is
why converter ballooning is often blamed); however, the
forward force on the crankshaft occurs because the front
of the converter has more surface area than the rear (the
converter neck is open). This difference in area is equal
to the area of the inside of the converter neck.
The most common scenario is the THM 400 used behind a
big-block Chevy. General Motors claims this engine is
designed to sustain a force of 210 pounds on the crankshaft.
The inside diameter of the converter hub can vary from
1.50" to 1.64". Therefore, the area of the inside of the
hub can vary from 1.77 square inches to 2.11 square inches.
210 pound of force, divided by these two figures offers
an internal torque converter pressure of 119 PSI to 100
PSI, respectively.
So, depending on the inside diameter of the hub, it takes
between 100 to 119 PSI of internal converter pressure
to achieve a forward thrust of 210 pounds. The best place
to measure this pressure is the outgoing cooler line at
the transmission, because it's the closest point to the
internal converter pressure. The pressure gauge must be
teed in, to allow the cooler circuit to flow. Normal cooler
line pressure will range from 50 PSI to 80 PSI, under
a load, in drive: Far too low to create a forward thrust
of 210 pounds.
Causes for Excessive Torque Converter Pressure
There are two main causes for excess torque converter
pressure: restrictions in the cooler circuit, and modifications
or failures that cause high line pressure.
One step for combating restrictions in the cooler circuit
is to run larger cooler lines. Another is to install an
additional cooler in parallel with the original, rather
than in series. This will increase cooler flow considerably.
An additional benefit to running the cooler in parallel
is it reduces the risk of overcooling the oil in the winter.
The in-parallel cooler may freeze up under very cold conditions;
however, the cooler tank in the radiator will still flow
freely.
Modifications that can result in higher-than-normal converter
pressure include using an overly heavy pressure regulator
spring, or excessive cross-drilling into the cooler charge
circuit. Control problems such as a missing vacuum line
or stuck modulator valve can also create high pressure.
What Will Help Thrust Bearings Survive?
A simple modification to the upper thrust bearing may
be beneficial in some engines. Install the upper thrust
bearing in the block to determine which thrust face is
toward the rear of the engine. Use a small, fine tooth,
flat file to increase the chamfer on the inside edge of
the bearing parting line to about 0.040" (1 mm). |
