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Cooling System
The purpose of the engine's cooling system is to remove
excess heat from the engine, to keep the engine operating at its most efficient
temperature, and to get the engine up to the correct temperature as soon
as possible after starting. Ideally, the cooling system keeps the engine
running at its most efficient temperature no matter what the operating
conditions are.
As fuel is burned in the engine, about one-third of the
energy in the fuel is converted into power. Another third goes out the
exhaust pipe unused, and the remaining third becomes heat energy.
A cooling system of some kind is necessary in any internal
combustion engine. If no cooling system were provided, parts would melt
from the heat of the burning fuel, and the pistons would expand so much
they could not move in the cylinders (called "seize").
The cooling system of a water-cooled engine consists of:
the engine's water jacket, a thermostat, a water pump, a radiator and radiator
cap, a cooling fan (electric or belt-driven), hoses, the heater core, and
usually an expansion (overflow) tank.
Fuel burning engines produce enormous amounts of heat;
temperatures can reach up to 4,000 degrees F when the air-fuel mixture
burns. However, normal operating temperature is about 2,000 degrees F.
The cooling system removes about one-third of the heat produced in the
combustion chamber.
The exhaust system takes away much of the heat, but parts
of the engine, such as the cylinder walls, pistons, and cylinder head,
absorb large amounts of the heat. If a part of the engine gets too hot,
the oil film fails to protect it. This lack of lubrication can ruin the
engine.
On the other hand, if an engine runs at too low a temperature,
it is inefficient, the oil gets dirty (adding wear and subtracting horsepower),
deposits form, and fuel mileage is poor-- not to mention exhaust emissions!
For these reasons, the cooling system is designed to stay out of the action
until the engine is warmed up.
There are two types of cooling systems; liquid cooling
and air cooling. Most auto engines are cooled by the liquid type; air cooling
is used more frequently for airplanes, motorcycles and lawnmowers.
Liquid cooled engines have passages for the liquid, or
coolant, through the cylinder block and head. The coolant has to have indirect
contact with such engine parts as the combustion chamber, the cylinder
walls, and the valve seats and guides. Running through the passages in
the engine heats the coolant (it absorbs the heat from the engine parts),
and going through the radiator cools it. After getting "cool" again in
the radiator, the coolant comes back through the engine. This business
continues as long as the engine is running, with the coolant absorbing
and removing the engine's heat, and the radiator cooling the coolant.
A cooling system pressure tester is used to check the
pressure in the cooling system, which allows the mechanic to determine
if the system has any slow leaks. The leak can then be found and fixed
before it causes a major problem.
The Heater Core
The heater core is a smaller version of the radiator that
is used to keep your toes warm when it's cold outside.
The heater core is mounted under the dash board. Some
of the hot coolant is routed through this little radiator, by more hoses.
A small electric fan is also mounted there especially for the purpose of
directing the heat inside the car. To turn this fan on, you use a switch
called "fan" or "blower," located on your control panel. The principle
is exactly the same as the one used in the radiator for your engine, except
that the heat is released inside the car instead of outside. Most engines
use the heater core to warm the air coming from the air conditioner if
the dash setting is not on "cold". More efficient designs don't do this
because it makes the engine work harder than it has to. They cycle the
compressor on and off to lessen the cooling output.
If your car is running hot, turning the heater on will help to reduce the heat
in the engine. Unfortunately, most cars don't overheat in the winter.
Cooling System Operation
Radiator
The radiator is a device designed to dissipate the heat
which the coolant has absorbed from the engine. It is constructed to hold
a large amount of water in tubes or passages which provide a large area
in contact with the atmosphere. It usually consists of a radiator core,
with its water-carrying tubes and large cooling area, which are connected
to a receiving tank (end cap) at the top and to a dispensing tank at the
bottom. Side flow radiators have their "endcaps" on the sides, which allows
a lower hood line.
In operation, water is pumped from the engine to the top
(receiving) tank, where it spreads over the tops of the tubes. As the water
passes down through the tubes, it loses its heat to the airstream which
passes around the outside of the tubes. To help spread the heated water
over the top of all the tubes, a baffle plate is often placed in the upper
tank, directly under the inlet hose from the engine.
Sooner or later, almost everyone has to deal with an overheating
car. Since water is readily available, it is not beyond the ability of
most people to add some to their radiator if it's low. BUT PRECAUTIONS
MUST BE TAKEN OR SERIOUS BURNS CAN RESULT. Here are a few pointers for
dealing with an overheated radiator:
-
Turn off the A/C. If the car is not seriously overheating,
this will reduce the engine's temperature. The AC evaporator is located
in front of the radiator, and it adds heat to the air going to your engine.
The hotter the incoming air is, the less efficient the radiator will be.
-
Turn on your heater (set on highest temperature setting,
with blower on highest setting). This will be uncomfortable for you, but
it will cool the engine by transferring the heat to the air. Roll down
the windows, and remember how 'hot' you'll get if your engine needs replacement!
-
If you're stuck in traffic, pull over and stop. Unless you're
moving, very little cool air reaches the radiator. Open the hood and let
the engine cool off. This takes time, so be patient. Use the time to go
get a jug of water or antifreeze.
-
Check the overflow tank coolant level. If it's empty, the
radiator is probably low on coolant.
-
Check the pressure of the system by wrapping a cloth around
the upper radiator hose and squeezing it. If it's still under pressure
(hot) it will not squeeze easily. Wait until it does.
-
Place a large cloth over the radiator cap, and CAREFULLY
release the pressure.DANGER: SERIOUS BURNS CAN RESULT FROM THE HOT COOLANT.
IF IN DOUBT, WAIT UNTIL THE ENGINE COOLS COMPLETELY.
-
If the coolant is low, start the engine, and slowly add the
water or coolant necessary to fill it up. THE ENGINE MUST BE RUNNING.
ADDING COOLANT TO A WARM ENGINE CAN CRACK THE BLOCK. By running the
engine, the coolant keeps moving and reduces the chances of this type of
damage occurring.
Water Pump
Water pumps come in many designs, but most include a rotating
impeller, which forces the coolant through the engine block. In most rear
wheel drive cars, the fan is installed on the end of the water pump shaft.
Many water pumps have a spring-loaded seal to avoid leakage of water around
the pump shaft. Modern pumps are fitted with pre-packed ball bearings,
which are sealed at each end to eliminate the need for lubrication.
Impeller type water pumps must turn rapidly to be efficient,
and worn or loose drive belts can permit slippage which is not easily detected.
Expansion (Overflow) Tank
Several cooling systems make use of a clear plastic container,
which is connected to the overflow tube from the radiator. This container
provides extra storage space for the coolant when it expands and is called
the expansion, or overflow tank. It is also known as the coolant reservoir,
or overflow canister.
As the engine heats up, the coolant inside it expands.
Without the expansion tank, the coolant would flow out of the overflow
tube and be lost from the cooling system onto the street. Instead, the
coolant flows into the expansion tank.
Since a vacuum is created in the cooling system when the
engine cools, the vacuum causes some of the coolant in the expansion tube
to be sucked back into the system. Because a cooling system with an expansion
tank is virtually a closed system, the coolant can flow between the system
and the expansion tank as it expands and contracts. This way, no coolant
is lost if the system is functioning properly.
Another function of the expansion tank is to remove air
bubbles from the cooling system. Coolant without air-bubbles is much more
efficient than coolant with air bubbles, because it absorbs heat much faster.
The advantage of the expansion tank is that while the level of coolant contained
in it rises and falls, the radiator is always full.
Older cars can easily be fitted with expansion tanks, simply by mounting the tank
near the radiator, connecting it to the overflow tube, and replacing the radiator cap.
Radiator Cap (Pressure Cap)
The radiator cap acts as more than just a "lid" for your
radiator; it keeps your engine cool by sealing and pressurizing the coolant
inside it.
What makes the radiator cap special is that it is designed
to hold the coolant in your radiator under a predetermined amount of pressure.
If the coolant was not kept under pressure, it would start to boil, and
soon you would have boiled all of your coolant away.
However, the radiator (or pressure) cap prevents this
from happening by exerting enough pressure to keep the coolant from boiling.
Normally, water (coolant) boils at 212 degrees F, but if the pressure is
increased, the boiling temperature is also increased. Since the boiling
point goes up when the pressure goes up, the coolant can be safely heated
to a temperature above 212 degrees F without boiling.
What makes this important is that the higher the temperature
of the coolant is, the greater the temperature gap between it and the air
temperature is. This is the principle that causes the cooling system to
work; the hotter the coolant is, the faster the heat in it moves to the
radiator and the air passing by. So, a cooling system under pressure takes
heat away from the engine faster, which makes it more efficient.
If your cooling system is under too much pressure, it
can "blow its top!" To prevent this, the radiator cap has a pressure relief
valve. The valve has a preset rating that allows it to take just up to
a certain amount of pressure. When you turn the cap on the filler neck
of the radiator, you seal the upper and lower sealing surfaces of the filler
neck. The pressure relief valve spring is compressed against the lower
seal when you lock the cap.
The radiator filler neck has an overflow tube right between
the two sealing surfaces. If the pressure in the cooling system exceeds
the preset rating of your cap, its pressure relief valve allows the lower
seal to be lifted from its seat. Then the excess pressure (coolant,air)
can squish through the overflow tube to the ground or the coolant reservoir.
Once enough pressure has been released (the caps preset rating), the pressure
relief valve is again closed by the spring.
The pressure cap can be tested with a cooling system pressure
tester, using an adapter, to make certain that it is living up to its pressure
rating. It should be replaced if it fails the test.
Note: Most radiator pressure caps are not meant to be
removed. Coolant should always be added through the expansion (overflow)
tank. NEVER REMOVE THE RADIATOR CAP FROM A HOT ENGINE. REMOVING THE PRESSURE
CAN CAUSE STEAM TO SHOOT OUT AND SERIOUSLY BURN YOU.
Cooling Fans
The reason the coolant goes into the radiator is to allow
air to pass through it and cool the coolant. When you are driving fast
enough, the air rushes through the grille of the car and passes through
the radiator core. If you aren't driving fast enough to push air through
the radiator, then the fan will pull the air through.
The fan improves cooling when you are driving at slow
speeds, or if the engine is idling. It is usually mounted on the water
pump shaft, and is turned by the same belt that drives the water pump and
the alternator, although it can be mounted as an independent unit. Most
independently mounted fans are electric.
Belt Powered Fans
The fan's activity is not always necessary, and it takes
power from the engine to spin. For this reason a thermostatic control,
or fan clutch, is often used to reduce drive torque when it isn't needed
(variable-speed fan). A different type of fan uses centrifugal force to
move its flexible plastic blades, by flattening them when the engine rpm
is high (flexible-blade fan). The less angle the blade shave, the less
power they use. The idea of these units is to save horsepower and reduce
the noise the fan makes.
A fan can have from four to six blades to suck the air through the radiator.
Often the radiator has a shroud for the fan to keep it from recirculating
the same hot air that has collected behind the radiator. Many fans have
irregularly spaced blades to reduce resonant noise.
Electric Fans
Front-wheel drive engines mounted transversely usually
use electric fans to cool the engine. The radiator is located in the usual
place, but an electric motor drives the fan. A thermostatic switch is used
to turn the fan on and off at predetermined temperature settings, which
it senses. The exception to this is air conditioning. If you turn on the
air conditioner, you bypass the thermostatic switch, and the fan runs continuously.
If you turn off the air conditioner, the thermostatic switch is re-activated,
and goes back to turning the fan on and off, according to its instructions.
Many cars have one electric fan for normal cooling and a separate one just
for when the air conditioner is on.
There are some really nice features about the electric
fan. The nicest feature is that you don't have to keep an eye on the treacherous
old fan belt -- there isn't one, so you don't have to worry about its health
and fitness. It's also quieter, and less of a power drain on the engine.
They also help your engine by continuing to cool it after it's turned off.
V-Belt (Fan Belt)
The fan (drive) belt wedges neatly into the different pulley grooves. The belt
uses the tension and friction to turn the auxiliary devices.
The fan belt is usually V-shaped, so it is also called
a V-belt. The fan belt friction comes from the sides of the belt and the
sides of the pulley grooves to transmit power from one pulley to the other
through the belt. Since the sides of the belt are used for transmission
of power, the sides have very large surface areas. The reason that the
belt does not slip is because of the wedging action of the belt as it curves
into the pulley grooves.
Because your belts are so essential to so many parts of
your engine, it is a very good idea to periodically check their condition.
Check for cracking, splitting, or fraying, especially before summer. Also,
check the tightness of the belt and have it adjusted according to your
owner's manual specifications. Belts have a tendency to loosen with use.
On the other hand, you don't want the belt to be too tight, or it will
put too much pressure on the accessory bearings and cause them to die an
early death. If a belt is over three years old, have it replaced even if
it looks good.
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