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We "Force Match Tires" for a better balance; and it uses less lead
weights which is better for the environment
From our home page:
We force match your new tires to Original Equipment rims for maximum balance.
The tire manufacturer marks the location of the greatest radial force variation
(RFV) with a round sticker, yellow dot or similar method on the sidewall of the
tire. When we mount the tires on the rims we align the low spot on the
rim, usually at the valve stem, with the RFV mark on the tire. The
now O.E.M./Force matched tire will greatly increase the ride quality of the
vehicle. Just another way we go the "extra mile" to look out for you.
For the interested customer regarding the details:
From an article
from Bridgestone Tires.
Can we review which dot goes where?
First, if the tire has a red dot, ignore the yellow dot. Then, if you have a
steel wheel, look for the low point dimple on the wheel, and mount the tire with
the red dot next to the low point dimple. If the wheel is aluminum, or if it’s
steel, but has no low point dimple, mount the tire with the red dot next to the
valve stem.
And if the tire has only a yellow dot?
Regardless of the type of wheel, if there is no red dot, mount the tire with the
yellow dot next to the valve stem.
Why do it that way?
We’ll start with the yellow dot, because it’s easier to explain. The yellow dot
indicates the overall light static balance point of the tire. In other words,
it’s as though the tire is a bit lighter in the area where the yellow dot is
located.
How does that relate to the wheel?
On an aluminum wheel, the valve stem marks the heavy point of the wheel. So,
you’re matching the light point of the tire with the heavy point of the wheel,
because that’s likely to give the best initial balance.
Why is an aluminum wheel heavier at the valve stem location?
While steel wheels are forged, aluminum wheels are machined. For that reason,
aluminum wheels are very uniform in their overall balance. And, if you
look at an aluminum wheel, you notice that where a hole has been cut into the
wheel, an identical size and shape hole is cut at a location 180 degrees
opposite it.
The result is that even with all their cutouts and holes,
aluminum wheels are still very uniform in balance. Except for one place.
Where’s that?
Where the valve stem is located. At that spot, the manufacturer has to bore a
hole through the wheel for the stem, removing metal from the wheel. That hole is
about 9.7 mm in diameter and the
aluminum at that point is usually about 7.6 mm thick. If we do the math, knowing
that aluminum weighs about 2.64 grams per cubic centimeter, we find that the
aluminum removed to make the hole weighs about 0.52 ounces.
So wouldn’t that make the wheel lighter at that point?
If you didn’t replace the aluminum you drilled out. But you do. Into that hole,
you mount a valve stem. And one of the most popular valve stems, including its
securing nut and rubber grommet, weighs about 1.7 ounces.
So, when the valve stem is mounted, the wheel is about 1.2 ounces heavier at the
valve stem location, making it the heavy point of the aluminum wheel. When you
mount the tire with the yellow dot (the light point) next to the valve stem (the
heavy point), you are at least partially balancing out the assembly.
The same is true on steel wheels, so match the yellow dot to the valve stem on
those.
OK, that makes sense for the yellow dot, but what about the red dot?
The red dot is much more complicated than the yellow dot. It indicates the
“radial force variation first harmonic maximum.” That’s a mouthful, of course,
but it’s a way of indicating where the centrifugal force tending to pull the
rotating tire away from the wheel is greatest.
Another way of looking at it is that in a sense, if the tire were out of round,
the red dot would more or less correspond to the “high point” or place where
radial runout forces are greatest.
Why not just measure the runout of the tire?
The radial force variation measurement is much more accurate in predicting tire
behavior. In fact, the red dot often isn’t located exactly at the “high point.”
Instead, it accurately marks where the runout-like force is greatest.
But, if you think of it as marking the tire’s “effective” high point, it becomes
pretty obvious why you’d match the red dot with the steel wheel “low point”
dimple. It’s as though the tire is a bit “thicker” (from wheel to tread) in the
red dot area.
And, since the dimple marks the low point on the steel wheel, you might say the
wheel is a bit “thinner” (from axle to flange edge) where
the dimple is.
So, it makes sense to match the red dot to the wheel dimple.
And on aluminum wheels?
At the red dot location, the tire is trying to pull away from the center of the
axle a little bit, as a result of higher centrifugal force.
As in our last example, it’s as though the tire is a bit “thicker” near the red
dot, which has the effect of pushing the wheel and axle upward as the red dot
gets to 6 o’clock.
Meanwhile, the fact that the wheel is a bit heavier at the valve stem location
generates a centrifugal force effect trying to pull the axle downward as the
valve stem gets to 6 o’clock.
Those forces tend to counteract each other.
And the final result?
Matching the dots is no substitute for balancing tire and wheel assemblies. What
it does, however, is give you the best start, so you are more likely to use less
total weight to bring an assembly into balance.
If the Bridgestone pdf page link at the top ever disappears,
here is a pdf of it that also includes pictures.
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Located
off of Cedar Road in Great Bridge.