|
24 Oct 2000 |
Terminology
–
|
FD |
Final
Drive/diff ratio |
FD’s are
ultimately responsible for the way your Mini goes after engine, gearbox, and
under carriage tweaking has been applied. The aforementioned and the degree to
which it has been done will affect the decision as to what FD is required.
They’re also responsible for much discussion between many tuning freaks, and
confusion to the less informed. There’s nothing weird or scientific about it.
Maximum acceleration requires a low final drive, top speed a high one. And
these two terms confuse most. The confusion being the LOWER number denotes a
HIGHER gear. Likewise the higher number denotes a lower gear. Largely because
the lower the ratio, the slower you go and vice versa. That’s how I remember
it. So a 2.95 FD is a HIGH gear (high top speed, reduced acceleration), a 3.76
a LOW gear (low top speed, increased acceleration). That was too simple, so we need
to add just a little ‘spice’ to it by introducing everybody's favourite term
‘COMPROMISE’. To establish the FD ratio, just divide the tooth count on the
crown wheel (big gear in diff housing) divided by the pinion tooth count
(little gear on end of mainshaft that engages the
crown wheel).
Unless you
specifically want maximum top speed or maximum acceleration you are going to
have to make a compromise. The main influences are what you use your Mini for
most, and what you find acceptable. Mostly driven in town with the odd foray
onto a motorway, 3.44 gives a good general performance on smaller-bore engines,
3.105 being a better choice where higher output/torquier
big-bore engines are concerned. When Motorways are the largest chunks of your
habitat then a 2.76 is the way to go. Rover plumped for a 3.105 FD as it’s do
all in the A+ engined cars, with the odd change for ‘Specials’ - like a 2.95 in
the 998 E (Economy). It was Ok in the big-bore engined cars, but killed the
small-bore ones. Since 1996 Minis have been endowed with a 2.76 FD in a
last-ditch attempt at keeping noise levels way down, and better economy on long
motorway runs. It has killed engine performance on the road though as the
engines barely have sufficient mid-range power to pull it. Unfortunately there
aren’t any hard and fast rules for selection, but there are a number of
influencing factors. Below is a table depicting the standard, helical-cut
ratios that have been made for the A series.
Final drive ratios and part numbers
|
Tooth count |
Part nos - A+ |
Part nos - pre A+ |
A+ C/Wheel |
|||||
|
Ratio |
C/wheel |
Pinion |
C/wheel |
Pinion |
C/wheel Pinion |
Casting No. |
||
|
4.333 |
65 |
15 |
DAM3645 |
DAM3647 |
22G443 |
22G99 |
DAM3546 |
|
|
4.267 |
64 |
15 |
|
|
2G370
|
22G99 |
|
|
|
4.133 |
62 |
15 |
|
|
2G101
|
22G99 |
|
|
|
3.938 |
63 |
16 |
DAM3216 |
DAM3218 |
22G340 |
22G338 |
DAM3217 |
|
|
3.765 |
64 |
17 |
DAM4779 |
DAM4131 |
22A401
|
22A399 |
DAM4780 |
|
|
3.647 |
62 |
17 |
DAM4162 |
DAM4137 |
22G940
|
22A399 |
DAM4163 |
|
|
3.444 |
62 |
18 |
DAM2677 |
DAM2679 |
22A411
|
22A413 |
DAM2678 |
|
|
3.211 |
61 |
19 |
DAM2806 |
DAM2808 |
|
|
DAM2807 |
|
|
3.105 |
59 |
19 |
DAM6327 |
DAM2808 |
|
DAM6243 |
||
|
2.95 |
59 |
20 |
DAM5925 |
DAM5927 |
|
DAM5926 |
||
|
2.76 |
58 |
21 |
TCB10004 |
TCC10001 |
|
TCB10005 |
||
IMPORTANT NOTES:
-
Although
some gears have the same tooth count for different ratios, they are not
interchangeable - hence the need for distinguishing part numbers. Therefore use
in known pairs only.
-
A+
gears have a different tooth profile to pre A+, so they are not
interchangeable.
-
A+
pinions can be identified as they have flat machined surfaces on either side,
pre A+ ones have a shoulder on one side.
-
A+
crown wheels have casting numbers stamped into them that are different to their
actual part numbers, so refer to table.
-
Pre
A+ gearboxes, and A+ gearboxes having cast centre main bearing retainers will
have to be modified when fitting 3.1/2.9/2.76 FD. This is because the pinions
are much larger on outside diameter than the others. Some later sintered
retainers may also need modifying. Always carefully check for clearance before
finish-assembly of these parts. The modification is a simple filing out
procedure.
Selection.
There are,
of course, a number of influencing factors over which is the best FD to fit to
suit your particular application. We’ll ignore the obvious (like the one you’ve
got/can easily get/was given free by a mate). The three most important to
consider are engine performance envelope, wheel/tyre combination fitted, and -
as previously mentioned - main vehicle usage.
An engine
built with a specification akin to a circuit racer for blasting around twisty ‘B’
roads will not take kindly to a 2.95 FD. The fact that the camshaft doesn’t
produce any power worth mentioning until the rev counter sees 3,000rpm will
make it an absolute pig to get it moving from a standing start. Much
clutch-slip would be necessary, putting excessive strain on it and associated
components. Consequently they won’t last long at all. On the other hand, a
1380cc sports-tourer engine spec built for
demolishing motorways isn’t going to do so with a 4.33 FD. You most definitely
need to consider the useful working power-band your particular engine build is
going to give.
The
over-all size of the wheel and tyre combination used influences the FD
performance. Ten-inch wheels with 165/70/10 tyres will do more revolutions in a
mile than thirteen-inch wheels with 175/50/13 tyres. This increases
acceleration as it lowers the over-all gearing. An interesting side effect is
that it may also make the car faster at the top-end by allowing the engine to
pull more revs to over-come drag. Fitting a high FD doesn't automatically
guarantee maximum top speed - after-all, the latest 13-inch wheel-shod
Sports-pack Minis are about 6mph slower at top speed, and 0.6seconds slower
0-60mph than the 12-inch wheel-shod cars!
Usage. This
is where you really have to be either all or nothing, and damn the
consequences, or be sensible. Difficult I know, but can make or break your love
affair with your Mini. A low FD may make the car accelerate like a scolded cat
around town and those twisty lanes, but the din created by a high revving
engine/induction/exhaust will make your ears bleed at anything over 60 mph, and
crucify your hard earned pay packet too! A very high FD may do wonders for the
mpg when out on open roads, and make it lovely and quiet, but can be a real
pain in town when you’re rowing the car along on the gear lever - and seriously
adversely affect your fuel-economy.
Apart from
the usual advice of talking to specialists and other like-minded folk at shows
to try and assess which way to go - how can you do a self-assessment? The
simplest way is to consider what Leyland/Rover have used over the years on
their relevant models that appear to be what you’re trying to achieve. For
instance, Rover fitted the 2.76 FD to the latest cars as it achieved a number
of things - but mainly driver comfort. It provides reasonable economy and low
engine rpm on motorways and therefore a sensible noise level, and the engine
just about has sufficient torque/power to pull it. The Coopers and Ss were
equipped with 3.65 or 3.44 FDs (along with a set of
close-ratio gears) to allow spirited driving around twisty roads, where it
excels. Noise levels were therefore compromised, and economy depended on
frequency and depth of ‘pedal to the metal’ activity. Early 10-inch wheeled
small-bore engines were given 3.76 FDs for nippy-ness
about town and country. Get the picture? It's really only recent automotive
fashion and customer expectation that has pushed them into the 2.76FD
silly-ness.
For those
wanting a little more scientific approach see the 'Formulae for car speed,
etc.' for calculating mph per 1,000 engine rpm. And for those who really want
to stretch their grey cells, the formula for calculating gear ratios and
transmitted engine rpm are included too. Using this and a calculator you can
compute the most satisfactory FD for your engine type/usage - guaranteed hours
of fun!!