|
Cooling Controlling water
temperature |
23
July 2003 |
The introduction of the
Cooper S proved to be a testing time for the Mini’s systems, but conveniently provide
a guideline as to what the standard cooling system was capable of - that used on the ‘S’ was marginal to say
the least! It wasn’t uncommon for many S’s to spew water from their overflow
pipes when ever it was doing anything other than a steady 70 miles an hour,
over-heating eventually caused through water loss. Perhaps some deductions can
be made from the following…
There are a number of
elements involved in controlling water temperature. Some confusion over what to
sort first when over-heating occurs leads to wasted
time and money, and possibly terminal engine damage. Maximum power is usually
generated from A-series engines at 70 – 75 degrees C (160 to 170 degrees F).
The main problem with this on a road car is the oil’s unlikely to get hot
enough for maximum performance – the results outlined previously. Another being
that the heater (where needed) will be grossly inefficient. So, excluding race
cars, the optimum temperature to aim for is 85 to 90 degrees C (185 to 194
degrees F).
Radiators. No amount of
tweaking the rest of the cooling system will help if there simply isn’t enough
cooling capacity in the radiator. Water capacity used to be the answer, hence
the production of four-core radiators. It’s possible the improvement in cooling
was a product of more surface area created by the extra tubes, but the
inefficient airflow through the congested radiator area reduced its ultimate
effectiveness. In reality, effective surface area’s the answer, and why the
latest after-market, super-efficient two-core radiators are the best. The
standard radiator can just about cope with a standard engine in most cases. The
exception appearing to be the fuel injected cars. They’ll stand the limited
modifications that can be made without problems. Perhaps it’s the ‘brain’
compensating for it somehow in trimming ignition and fuel? If you’re
significantly increasing the power output, I strongly advise fitting one of the
aforementioned two-core radiators. And ALWAYS have water flowing out of the
heater tap take-off. If no heater or auxiliary matrix is used, plumb it into
the top hose. If it’s put back into the bottom hose it won’t work properly, if
at all. The water going into the bottom hose at that point MUST be below that
in the main hose coming out of the radiator.
I'd like a
pound-sterling for every time I've seen an oil cooler doing duty as an
auxiliary water radiator. They simply don't work. Well, they do a little. Their
design makes them grossly inefficient as the water flows through too quickly,
and material spec causes minimal heat transfer. If you need to run an auxiliary
radiator, use a heater matrix. See 'Cooling - How it works' for hook-up
details.
An expansion tank could
be the answer if your motor runs at the right temperature, but is prone to
spewing water out the over-flow at odd occasions. Usually when come to a
standstill after tramping-on a bit. Water passes into it when over-flow occurs
when hot then is drawn back in again when cooling down. Make sure the pressure
cap is fitted to the expansion tank and a flat, plain cap on the radiator.
Fans. They’re there to
cool the engine whilst at low speed. Fact. Once above
35 mph or so, it’s airflow through the radiator that does the cooling. Electric
fans only help up to about 30 mph, so fitting one won’t cure hot running at
speed. The fan creates a barrier to airflow at speed; trimming the blades down
in length (NOT removing blades) can often help. Generally the standard plastic
fans are the best all-round as they are aerofoil shaped, cutting power consumed,
increasing airflow, and quietest running. Two-blade fans are good but noisy,
four-blade fans made up of two two-blade fans more so of each. Six-blade
‘export/tropical’ fans better, but noisier! Both eat horsepower.
Water pumps. One good thing that came from ‘S’
development – an improved water pump! Unfortunately, the water pump has
fallen into the oil pump syndrome – biggest is best! True for
road cars spending most of their time at low-ish rpm
under load, but not for high revving engines. The A-series pump is
essentially centrifugal; it’s pumping capability squaring with engine rpm. The
design’s such that maximum efficiency’s around 2,000rpm, so at low speed it’s
hardly moving any water. At 2,000 rpm it’s pumping all the water needed to cool
the engine, so higher rpm just means it’s sapping
power. If your engine spends all it’s time north of 3,500 rpm or so, a deep
impeller pump is costing power, and may be causing cavitation, reducing cooling
efficiency. To mediate the A-plus motors got a bigger diameter pump pulley
(first seen on the Ss’), and should be used where possible on modified road
engines.
I would very strongly
advise against the use of the after-market water pumps that have the 'folded
tin' impellor as opposed to the cast iron one on the original equipment types.
They are grossly inefficient and have a tendency for the impellor to fall off
at the worst moments! There are some about with plastic impellors. They seem
OK, but I haven't put one to test on a race motor yet. All I can say is I haven't
seen a road car with one fitted that has failed yet.
Recent testing has seen
the growing popularity of electric water pumps. These have to be the ultimate
answer, as their pumping capacity remains constant, as they're completely
independent of engine speed. Consequently cooling efficiency is far greater.
The only two drawbacks being their initial cost, and installation, as adaptors
have to be made up to blank-off the water pump mounting hole. Both, however, are well worth it - the
results are outstanding. Not to mention the fact the water pump consumes power
to drive it and reduces accelerative power output - to the tune of 4 bhp on a
small-bore engine and 2 bhp on the large-bore ones! A further benefit is that
the pump can be left running with the engine off after a race/hot/long journey
to reduce the problems associated with the 'heat-sink' effects of
non-circulating coolant at stand-still. For further information on electric
pumps, see relevant article.
Coolant additives. Too many folk
seek solace in antifreeze. They keep adding more and more in the hope it'll
solve their problems. Whilst a small amount of antifreeze does help marginally
as it breaks down the water's surface tension (waters only real drawback as a
major coolant), in large amounts it actually makes matters worse (see 'Cooling
- How it works' for further information).
The only additive I've
ever tested that actually lives up to expectation/recommendation is Redline's Water-Wetter. This stuff basically breaks down water's
surface tension without affecting its cooling capability. This maximises
water's wetting capability, getting as much water against the metal surfaces of
the water jacket as possible. Consequently it prevents the hot-spot syndrome
outlined in 'Cooling - How it works'. I always use the liquid product (they do
it in crystallised form too, but I'm not so keen on that). Temperature
reductions in the order of 8-10 degrees have been experienced. Brilliant stuff. It also acts as a corrosion inhibitor -
effective enough to stop ALL corrosion on the block water jacket walls, and the
water pump impellor/housing. Lubricates the water pump seals
too. Most impressive. For the racers even more
good news is it doesn't make your slicks slippery if it gets out of the cooling
system.
For further cooling
information, see 'Lubrication - Temperature critical'.
Useful part numbers:
|
12G617 |
Cooper S top rad bracket - 1275 engine in
round-front Mini |
|
12G617S |
Stainless steel version of above |
|
11G227 |
Grommet for above - 2 needed |
|
11G228 |
Shouldered bolt for above - 2 needed |
|
12G2453 |
1275GT top rad bracket -
longer than S type, uses above grommets and bolts |
|
11G176 |
Thermostat blanking sleeve |
|
GTS102 |
74 deg-C/165 deg-F thermostat |
|
GTS104 |
82 deg-C/180 deg-F thermostat |
|
GTS106 |
88 deg-C/192 deg-F thermostat |
|
GTG101 |
Thermostat gasket |
|
GWP134 |
Large impellor water pump with by-pass hose take-off |
|
GWP4187 |
Large impellor water pump, blanked off by-pass hose take-off |
|
GUG705555GM |
Water pump gasket |
|
CAM6239 |
Standard water pump pulley - 3.875-in dia. |
|
CAM116 |
Water pump pulley - 4.265-in dia. |
|
CAM6408 |
Water pump pulley - 4.725-in dia. Latest A+ large diameter
version of S iron pulley (12A667) |
|
GCB10813 |
Fan belt for CAM6239, up to 1985 |
|
GCB10825 |
Fan belt for CAM6408 with latest A127 alternator |
|
GCB10838 |
Fan belt for CAM6408/12A667, dynamo or alternator |
|
2A997 |
Two-blade fan – use two for four-blade |
|
2A998 |
Six-blade export/tropical fan |
|
12G1305 |
Eleven-blade plastic fan. 1.100-in wide at tip, up
to 1968 and 1991 on |
|
12G2129 |
Eleven-blade plastic fan. 1.500-in wide at tip, 1969
to 1990 |
|
12A312 |
Fan blade spacer shim - as required |
|
ARP2000 |
Standard, modern 3-core radiator |
|
GRD974 |
Latest aluminium and plastic made front mounted
radiator from TPi Coopers. 3-in thick, 11-in tall, 178-in
wide. Side outlets and Mounting Lugs top and bottom. Light weight, small, but
very efficient |
|
C-ARA4444 |
4-core radiator |
|
C-ARA4442 |
Super-cool 2-core radiator |
|
C-ARA443 |
Super-cool 2-core radiator with temp sensor fitting |