 | Basics The aged flatulent one wanted me to do this months
column on suspension. Well, Mike, it is a little more involved than
that. We will split it up into two months. This month, shocks and next
month, forks. There is just too much info to try to squeeze it all into
one article.
The shock. Its purpose is to dampen the up and down movements of the
rear wheel. It also comes in handy for holding the rear spring. The
differences in the shock for a single shock rear suspension and a dual
shock set up are very similar. Their mounting and/or linkage systems are
basically the only difference. Dual shock set ups are pretty self
explanatory so I won't go into them too much. The shock itself is
similar or the same as a single shock set up.
Some of the older shocks had some unique damping systems. One that comes
to mind is one that had the rebound damping controlled by six orifices
shut by spring loaded steel balls. During rebound, the movement of the
shaft/piston would force the oil against the steel balls and raise them
off their seats. I'm not going to cover much of anything except what is
in most all shocks for the last decade. This would be a series of spring
steel shims controlling oil flow through a series of holes in the shock
piston. Since a visual will help immensely, I'll stick a few shots in
and describe them. These I took while installing a Gold Valve in the
shock of a '99 YZ 125. I'll show the differences between the stock
piston and the Gold Valve.
One word to cover my ass. This is NOT an advertisement for Race Tech
products. I am a Race Tech distributor and this was a shock I had apart
for one of my customers. It just so happens 70% of the shock work I do
is Gold Valve installation, so that's what I had it handy to take
pictures of. Some other suspension shops revalve by simply changing the
diameter, thickness, and/or quantity of the shims. Some will drill the
stock piston to enlarge the holes the oil passes through. There are
other companies who have different pistons beside Race Tech also. The
theory is the more oil that can flow through the piston, the more
damping relies on shim selection. This means we can control it more
thoroughly.
|
 | | Gold
Valve and the Stock Shock Piston |
| This is a picture of a
Gold Valve and the stock shock piston.
Notice the 3 large oblong holes in the Gold Valve. The shims are held
tight against the face of the valve and oil is forced through the
holes bending the shims off the face. This is where the damping
occurs. This shows the compression side of the piston. The rebound
side has much smaller holes on both the stock and aftermarket pistons.
|
 | | Shims -
Ready to Install |
| Here is a shot of the
shims in their respective position ready to install on the shock
shaft. The shims on the left are the compression shim
stack and the shims on the right are the rebound shim stack. Okay, we
know the shims bend off the face of the valve. The amount they bend
controls the damping. This is controlled by a few variables, one of
which is known as the clamping shim. This is the smallest shim at the
ends of the shim stacks. This is what tightens everything together.
This means only the edges of the shims bend. The outer diameter of the
clamping shim determines how much of the other shims cannot bend. If
more of each of the shims are allowed to bend, the valving feels
softer. If we stack more of the same diameter shims together, this
makes it harder to bend and makes it stiffer. Same thing if we use
thicker shims. This will make it harder to bend and make it stiffer.
Depending on which shims we use, we can alter the damping
characteristics virtually any way we want. |
 | | Stock
Piston with Shims |
| Here is the stock piston
with its shims displayed.
From upper left is the plate that the assembly tightens against, the
compression stack beginning with its clamping shim, increasing in size
, the piston itself and then the rebound stack ending with the end
plate that the nut tightens against.
|
 | | Gold
Valve Installed on the Shock Shaft |
| Here is the Gold Valve
installed on the shock shaft. The reservoir holds the bladder (or floating
piston in some shocks- Ohlins, for instance). This allows us to
pressurize one side of the bladder/piston to help keep the shock oil
from cavitating (foaming). You can see how well it works when you pull
the shock apart and the oil foams up like a Coke after being dropped.
Altering the nitrogen pressure can affect compression damping also.
Normal pressures run from 140 psi up to 300+ psi. I usually use
175psi, except for XR shocks that use 225 psi, when doing a revalve.
Remote reservoirs function the same as an attached reservoir except
they obviously have a hose between them to allow a different mounting
position.
|
 | | Rebound
Adjuster |
| The rebound adjuster is
nothing more than a needle that is screwed into a fixed seat that
controls a bleed passage around the piston.
The adjuster is a tapered screw that pushes the needle further into
the shaft the farther the screw is screwed into the clevis. It is a
little difficult to see, but here is a picture of the adjuster screw.
This is looking down into the clevis with the shaft removed.
|
 | | Shock
Shaft with Rebound Needle. |
| You can see the visible
part of the adjuster on the right side of the clevis. The adjuster is
the brass screw in the very center of the hole. |
| The compression adjuster
works a little differently. As the shock moves through its travel, oil
is displaced by the volume of the shaft assembly and is forced into
the reservoir. The compression adjuster controls the rate at which the
oil goes into the reservoir. This is also a needle and seat adjuster. Some shocks have ball type joints (a spherical
joint) at the ends, some have needle bearings. Some of the spherical
joints have a bushing surrounding the ball that do not require grease.
Check your shop manual to see if they recommend lubrication. Needle
bearings obviously need a good quality waterproof lube. I use the Bel-Ray
grease. It's nice and thick. Good stuff.. Maintenance
We'll assume you can get the shock off the bike without any help. If
you can't, you probably shouldn't be trying to attempt any repairs to
the shock itself.
|
| | Shock
with Spring |
| Measure the spring
installed length and the adjuster settings and write them down. Loosen
the spring preload adjuster until the spring is loose. There are a
couple different methods for holding the lower spring seat to the
shock. One is a circlip that is virtually hidden until the outer
collar is pushed towards the spring a little. It is common to have to
tap it lightly to get it to move. This should expose the circlip.
Remove the circlip and the spring seat will slide over the lower end
of the shock. This KYB shock has a split collar that can be slid out
sideways once the preload adjuster is loosened far enough.
|
 | | Shock
without Spring |
| Okay, we have a shock
without a spring on it. Remove the schraeder valve cap and release the
gas pressure. On most shocks, the valve points straight down out of
the reservoir. Using a socket to protect the valve stem, tap the
reservoir cap down far enough to expose the circlip. Use two small
flat blade screwdrivers to remove the circlip. It ca be a little
difficult to explain, but push the circlip down until it is out of its
groove and use the other screwdriver to pull the circlip over the tip
of the first screwdriver. In the next picture, this circlip is the one
in the shock body itself, but the circlip and removal are the same.
I've got the circlip pushed down and I am ready to pull it up with
another screwdriver. If you scratch the surface much more than 1 or 2
mm below the circlip groove, you can create a leak due to the seal not
sealing correctly. Be careful.
|
| Pull the reservoir
bladder out of the reservoir body. Normally I use a valve core removal
tool screwed over the end of the valve stem and pull up with that so
nothing gets damaged. The bladder may be a little stubborn. Wiggle it
back and forth to remove it.
Now to remove the guts of the shock. There is a cap on the end of the
shock body that protects the seal head. This metal cap is pressed into
the end of the body. Use a sharp chisel or punch and tap it up. Tap
evenly from opposite sides to prevent it from getting wedged too
tightly. We don't need to break any expensive parts.
I use a clothes pin to hold the cap up out of the way. Now the seal
head is exposed. Showa shocks have two circlips and another collar
between the circlips. First thing you'll need to do is remove the one
circlip that is visible. A pair of snap ring pliers can push the clip
out of place enough to get your screwdriver tip under it and pull it
off.
Push the seal head down. On Showa shocks this will leave a washer
resting on the lower circlip. Now you can remove this washer.
Otherwise it can be a royal bitch trying to get it out with the seal
head in position. With the washer removed, you'll be able to see the
lower circlip. KYB owners won't have to deal with this first circlip
and washer business. Just push the seal head down until the circlip is
exposed (just like the above picture shows). Remove the circlip.
Now you can pull the shaft assembly out. Normally wiggling it will be
enough to remove it. Sometimes I've had to tap on the clevis end to
get the shaft out. Be SURE you don't have it cocked off to one side.
Remember, you're dealing with some really expensive stuff. Screw
something up and you'll go from saving $50 to spending literally
hundreds.
|
 | | Shaft
Assembly |
| Here is the shaft
assembly once we get it out if the shock body.
From left to right, the clevis end, the bottoming bumper, the cap, the
seal head and the piston and shim assembly.
If we were doing an oil change we could rinse everything off with
brake cleaner and reassemble it. We'll get to that in just a minute.
We'll finish pulling this one all the way apart in case you're
replacing the seal or bushing or the bottoming bumper.
|
 | | Loosening
Locknut - Replacing Bottoming Bumper without Oil Loss
or Full Disassembly |
| Actually the bottoming
bumper can be replaced without losing any oil (shock still fully
assembled without the spring) by removing the clevis end. This is
relatively easy and painless. Once the nitrogen pressure is released
out of the reservoir, the clevis end can be taken off the shaft and
the bumper replaced. There is a locknut (normally a 22mm) that is
right at the clevis end of the shaft. You can use this to unscrew the
shaft from the clevis end. The next picture shows the locknut being
loosened but without the rest of the shock. As long as the rebound
needle isn't removed, you won't lose any oil (provided all the
pressure in the reservoir is released). A little red Loc-Tite on the
shaft threads and reassembling and you'll be ready to go. It would be
a good idea to mark the locknut position in relation to the clevis end
so you have a way of knowing when it is fully tightened
. |
| Okay, back to removing
the piston and seal head. The nut that holds the piston on the end of
the shaft is peened in place from the factory. This peening needs to
be ground/machined off so the nut can be removed without damaging the
end of the shaft. Some shocks have a check
|
 | | Here
is what the peening looks like. |
| valve assembly in the
center of the shaft. On these shocks, the peening also holds the check
valve in place. It is critical that this peening is removed very
carefully. If you're unsure of whether your shock has this check
valve, grind the peening as though it does have one. We would rather
be safe than sorry.
Here is what the peening looks like before it is ground away.
|
 | | Loosen
the Nut |
| What you want to
accomplish is to remove enough of the peened area to facilitate the
nut removal but leaving the center intact. This is what it looks like
after I've removed enough take the nut off. |
 | | Here's
what it looks like when done correctly. |
| Now you can loosen the
nut. If it begins to come off too hard, remove a little more along the
sides of the peening. Once the nut is removed, you can use a file to
remove any burrs and a thread file to restore the threads. If you try
to use a tap, it can cut new threads if it doesn't start in the same
place. Be careful.
Here's what it looks like when done correctly.
|
 | | After
Removal |
| Now you can pull the
piston off the end of the shaft. A coat hanger cut and bent in a
"U" shape can be useful in holding the shim and piston
assembly together.
Here is what we have when the piston assembly is removed.Now the seal head can be removed.
|
 | | Seal
Head |
| This is what the seal
head looks like once removed.
The seal and bushing can be changed but it isn't much cheaper than
replacing the seal head assembly. You can save maybe $20-25 by
changing the individual parts. |
 | | Bleed
Hole |
| The shock bumper can now
be replaced if it is needed. While we have the seal head off, it can
help the bleeding if we drill a hole in the side of the seal head.
Showa shocks come with a hole from the factory. A 1/8" hole
halfway between the sealing o-ring and the bottom edge will work
wonders. In the next picture you can see the hole. Drill just deep
enough to get through the wall of the seal head. A shot of brake
cleaner will rinse out any metal shavings.
|
| Now reinstall the seal
head. Make sure you don't fold the dust seal under when installing it
over the step of the shaft. If you're installing an aftermarket
piston, this is where it comes in. Be sure to have the larger shims
(compression stack) facing towards the clevis end. If you are changing
anything in the piston assembly (shims, piston, etc) you need to make
sure the piston is spaced up so the step (directly below the threads
at the end of the shaft) is not exposed. What happens is the nut will
tighten down against this step instead of tightening down against the
shims and piston.
|
 | | Without
Spacer Installed |
| This is what it would
look like if NOT spaced properly. The Gold Valve shim stack and piston
is thinner than the original and needs to be spaced out. You can see
the brass spacer installed in the above picture. The picture at left
shows the step before the spacer and nut are installed. If a nut was
installed without the spacer, it wouldn't tighten down properly. |
| Be sure to use a new nut
with red Loc-Tite. Torque is normally 24 lb/ft. I torque it to 30
lb/ft because if this nut comes loose, the results can be disastrous
not only to the shock but to the rider also. Normally the KYB thread
is a 10x1.5 and the Showa is a 10x1.25. Don't guess, you need to be
certain of this. There is a fiber bushing that goes around the
piston. If this is not in good condition (edge rolled or torn), now is
the time to replace it. The aftermarket bushings are split and need to
be held in position while the piston is inserted into the shock body.
We're not quite ready for this though. Okay, we have the shaft assembly ready. We have
the body thoroughly rinsed out with brake cleaner. The reservoir
bladder is rinsed clean and is installed on the reservoir cap.
Remember what Grandma said. "Cleanliness is next to
Godliness". She must've been talking about shock servicing. We're
ready to reassemble the shock. The method I use is different than some
manufacturers use. I've found bleeding is much easier with this method
and getting the proper amount of oil in the shock is more of a sure
thing. Here we go. |
 | | Inserting
the Bladder |
| Tighten the shock body
in a vise with the openings pointing straight up. Place a drain pan
directly under the vise on the floor. This will get messy. Pour new
oil in the reservoir until it is almost half full. Insert the bladder
into the reservoir. |
 | | It will be messy! |
| If the reservoir end cap
has to be pointing a certain direction (like this YZ 125), now is the
time to point it in that direction. Push the bladder into the
reservoir until oil gushes out all over. Like this?.. |
 | Pressurize
Bladder
Add Oil |
| Push the bladder into
the reservoir until the circlip groove is visible. Install the circlip
and pull the end cap up into position seated against the circlip. Now
you need to pressurize the bladder with 35-40 psi of air. This will
force any air trapped in the compression adjuster out, into the shock
body. Add oil into the body until it is about an inch from the top
edge. This is what you should have?. |
| Now put the business end
of the shaft assembly in the body. If you have a new piston bushing,
you'll have to hold it in place while you push it into the body. Push
the guts into the body slowly. You should see a lot of bubbles coming
up through the oil. Don't push too hard because oil will come shooting
out the hole in the side of the shaft. I told you this would be messy.
Now run the shaft through its stroke a few times. Don't pull the shaft
up so far it sucks air through the hole in the side of the shaft. This
will result in pulling more air in under the piston. Watch closely. If
it sucks air, you need to start all over with the bleeding.
|
 | | Fill
Body - Bleed Air Bubbles |
| Once you get it so no more air
bubbles are coming out, pull the shaft up as far as you can before
sucking air. Take a rubber or plastic hammer and tap the clevis end of
the shaft assembly. You want to tap it hard but don't pound it. What
this does is makes the oil force the compression shims off their seat
far enough to release any trapped air bubbles. Do this until no
bubbles come up. This step is important. Don't take it lightly. Give
the oil a few minutes for the very small bubbles to surface. Fill the
body with oil to near the top edge. It should look like this?
|
| Once you have the air bled out from
under the piston, we're ready to push the seal head in. Tilt the shock
body to one side just a little. Now pull the shaft assembly up as far
as you can with the body full of oil. You want to get as much oil in
the body as you can. Turn the seal head so the bleed hole is at the
higher side of the tilted shock body. You want any air trapped under
the seal head to go to the high spot (where the bleed hole is). Push
the seal head in place. You should see bubbles coming through the
bleed hole.
The seal head will stop moving down. While holding pressure on it,
release the pressure in the reservoir. The seal head will go further
into the shock body. Keep pushing down and continue to release the
pressure in the reservoir until the seal head is down far enough to
expose the circlip groove. Install the circlip.
Now pressurize the reservoir with air pressure. Normal shop air will
work fine (at least 90 psi or so). Here's where we test the shock to
see if it has enough oil in it. With the damping adjusters set at full
soft (counterclockwise) and air pressure in the reservoir, push the
shaft into the shock. It should go in smoothly and return fully by
itself. If it doesn't return 100%, then you may not have enough oil in
it.
Once you're satisfied the internals are in good order, rinse the
outside with brake cleaner and tap the cap into the to of the shock
body. Rinsing the shock off can be important in case you suspect a
leak after it is reassembled. A clean and dry shock will reveal any
leaks quickly.
Put a little grease on the preload adjuster threads, reinstall the
spring, set it to its correct length, reset the damping adjusters and
you're ready to put the shock back on the bike.
Adjustments
Adjusting the clickers can be a science in itself. There are a lot of
variables between individual bikes, so I'll only cover basic settings.
New bikes should be set as close as possible initially. It doesn't
cost a thing to set it up and can make the new bike experience much
better since some new bikes come pretty far from the best settings.
Some forks take a while to break in and adjusting the compression
clicker to a much softer setting initially can make life easier while
waiting for things to loosen up.
Race sag is the difference in the measurement between the bike on the
stand and the bike with a fully dressed rider aboard. Measure from the
rear axle to a reference point near the rear fender/seat. A lower edge
of the rear fender works well. The important thing is to measure from
the same two points. For the measurement with the rider aboard, the
rider should be standing up. One variable is where the rider sits
during the measurements. If he changes his seating position even a
little between measurements, it can have a significant effect on the
settings you end up with. Standing up eliminates this variable. This
means a 3rd person is needed to balance the rider/bike. Suck up to the
wife/girl friend and she may give you a hand if she isn't still bent
about you getting the new bike.
Drag in the suspension pivots can affect your measurements. On the
first measurement, push the rear fender down slowly and let it rebound
slowly. Check your ruler. Now pull up and let it relax slowly. Check
the ruler again. The difference in these two indicate how much drag
there is in the pivot points. If there is more than 10mm, something is
binding enough to need attention. For accuracy, this pulling,
measuring, pushing, measuring should be done at each measurement. But
since there is a relatively large range of adjustment anyway, this may
not make much difference. Just be aware of it.
Sag should generally be set at about 1/3 wheel travel. This means
about 100mm for most full size dirt bikes. Some bikes have an
adjustment range of around 90mm to 105mm. The less the spring is
compressed does not necessarily mean the softer the ride will be. Due
to the progressive ratio designed into the linkage, setting the spring
stiffer can make the ride softer?..
Say what?!?
The linkage is designed to move the shock less as the suspension moves
through its travel. This makes it soft at the beginning of the
movement and stiffer as it goes through towards the end. This makes it
more resistant to bottoming but still allows it to be plush over
smaller bumps at full extension. So if we set the spring stiffer, it
will move the ride height into the softer ratio part of the travel.
This is one reason a "too soft" spring rate can give a dead
feel to the rear of a bike (compared to how it should feel).
Once you get the sag set, you can check to see how close the spring
rate is for your weight. Check the sag again without a rider aboard.
This is known as static sag. You should get between 15mm and 25mm if
your spring rate is correct for your weight. If the static sag is less
than 15mm, your spring is too soft for your weight. If the static sag
is more than 25mm, your spring is too stiff for your weight. I know
this may sound backwards, but this is due to the preload applied to
the spring to get the rage sag correct for your weight.
Compression adjustment can give a variety of adverse symptoms. It can
be a good idea to have someone watch what is really happening to
verify your feelings. Is it "really" bottoming over that
jump? Is it harshness due to improper valving? The clicker is a low
speed adjuster. This means it affects the damping concerning
relatively slow hits (jump landings, G-outs, etc). The high speed hits
(braking bumps, roots, rocks, ruts) are controlled by the valving.
This holds true for pretty much all suspension clickers, front and
rear.
Rebound adjustment can create some problems if not set close. The rear
end can pack through whoop sections if it is set too stiff. It can
make the back end kick if set too light. If a bike jumps consistently
with the front end high, try setting the shock rebound setting a
couple clicks softer. This will kick the rear end up a little on the
lip of the jump making the front come down a little.
Go out to a track you're familiar with and experiment a little. Just
remember (write down) your beginning settings so you can always return
there if you get things acting "not good". There are no
"right" settings for any one model bike. Anyone who tells
you that is just plain lying. I now some of you wanted to hear
definite symptoms and how to cure them but it just isn't that simple.
Too many variables. First thing to do is make sure the shock is
freshly serviced and the pivots are working well and freshly greased.
This is the starting point to cure any problems.
Hope you got something useful out of this months column. If you have
any specific questions, please don't hesitate to contact me.
MX Tuner
|
Posted Aug 14 2007 09:37AM
