Camshaft:
Functions, Types, Parts, Diagram,
Working
Editing Date£º2024-07-28
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Camshaft:
Functions,
Types, Parts, Diagram, Working
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In four-stroke engines, the camshaft is
responsible for the timely operation of the
valves, helping to perform different processes
during the engine cycle. It is driven by the
engine crankshaft and sits on top of the engine.
The size and number of cams on the camshaft can
vary depending on the engine size and the number
of cylinders present.
Continue reading to learn about its functions,
construction, types, workings, and much more.
The
camshaft is a cylindrical shaft
with cams that controls the
opening of intake and exhaust
valves of the engine.
The intake
cams on the camshaft control the
intake valves while the exhaust
cams control the exhaust valves.
The
camshaft is located at the top
of the IC engine inside the
cylinder head. Other than cams,
the camshaft also has bearing
journals to support the
camshaft.
DOHC (Double overhead camshaft)
of V engine
Some
engines have both intake and
exhaust cams on the same shaft.
The SOHC (Single overhead
camshaft) engine uses a single
camshaft per cylinder bank.
While some engines have intake
cams on separate shafts and
exhaust cams on separate shafts.
DOHC (Double overhead camshaft)
engines use a two camshaft per
cylinder bank.
Therefore,
engines can run on single or
multiple camshafts. The
V-engines with DOHC have 4
camshafts i.e. Two camshafts for
each cylinder bank.
Cam rotates to actuate
the tappet of the
valves. The eccentric
profile of the cam opens
and closes the valve for
the right duration. The
shape of the cam varies
based on the Opening
duration, Type of tappet
used (Flat/Roller).
The cam profile consists
of following regions:
The surface of the cam
that comes in contact
with the tappet
(follower) can be
divided as cam heel and
cam lobe portions.
Cam heel£ºWhile working
when the tappet
(follower) is moving
over the cam heel
portion, the tappet has
no vertical movement.
The cam heel is the
portion of the cam where
the tappet has no lift.
Hence the valve remains
closed.
Cam lobe£ºCam lobe is
responsible for opening
and closing of the
valves. When the tappet
is passing over the cam
lobe surface, it moves
in a vertical direction.
This causes opening and
closing movement of the
valve.
Base circle£ºIt is the
circle that can be drawn
from the centre of the
cam that touches the cam
heel surface.
Cam lift£ºIt is
equivalent to the
vertical distance
travelled by the tappet
(follower). It is also
called a lobe lift, a
height of cam lobe from
its base circle.
Nose£ºIt is the point on
the cam profile at the
maximum lift.
Lobe separation angle£ºThe relative positions
of the intake and
exhaust cams are stated
in terms of lobe
separation angle. It
gives the angle between
centerlines of the
intake cam lobe and
exhaust cam lobes of the
same cylinder.
All the cams and cam
bearing journals are
mounted on the shaft. It
possesses higher
torsional rigidity, as
the twisting of the
camshaft can affect the
valve timing.
The role
of the camshaft bearing is to
support the camshaft. In the
case of a multi-cylinder engine,
the camshaft uses a number of
bearings at different locations
to bear the dynamic loadings.
One of the
ends of the camshaft has
provision for the mounting of
the Driving gear or Sprocket. It
is driven by the crankshaft
through chain/belt/gear drive.
The
Purpose of the thrust plate is
to stop the axial (horizontal)
movement of the camshaft. The
thrust force arises due to the
interaction between the cam
lobes and the tappets. This
force acts in the axial
direction of the camshaft. This
causes movement of the camshaft
in axial direction.
The thrust
plate is mounted on the camshaft
before timing gear and fitted on
the engine block. This plate
holds the camshaft on the engine
block.
The
camshaft is driven by the
crankshaft through a timing belt
or timing chain. As shown in the
above figure, the cams on the
camshaft are structured in such
a way that it operates the
valves of each cylinder at the
right time and for the right
duration.
A cam
actuates the tappet (follower).
The tappet is further connected
with the pushrod, rocker arm to
operate the valve.
When the
tappet passes over the cam heel
surface, the tappet never moves
in a vertical direction and the
valve remains in closed
condition. When the tappet
passes over the cam lobe
surface, the tappet moves in
vertical direction, thus causing
the valves to open and close.
It occurs
a few degrees before the end of
the exhaust stroke and a few
degrees after starting the
suction stroke.
The overlap between the intake and
exhaust valves is due to the overlapping
of the intake and exhaust lobes on the
camshaft.
In single overhead camshaft, as the
position of intake and exhaust cams is
fixed, therefore in these camshafts the
valve overlap is fixed. While In dual
overhead camshaft as intake and exhaust
valves are operated by separate cams.
Thus in this system, the overlap between
intake and exhaust valves can be
adjusted.
1.
Single overhead camshaft (SOHC)£ºThis
system uses a single camshaft
for controlling the intake and
exhaust valves.
Here, the
camshaft is mostly placed in the
middle of the intake and exhaust
valves. Hence this system
necessarily requires rocker arms
for the actuation of valves.
2.
Double overhead camshaft (DOHC)£ºThis
system uses two separate
camshafts for controlling intake
and exhaust valves. The variable
valve timing is possible with
the DOHC system.
The other
advantage of using DOHC is that
it doesn¡¯t require a rocker arm
as the cams are mounted above
the valves.
But this
system takes more space in the
engine head as compared to SOHC
due to the extra camshaft. Thus
it makes engines more bulky.
1. Flat
tappet camshaft£ºThese
camshaft are designed to actuate
a flat tappet. The flat tappet
is subjected to more friction in
comparison with roller tappets.
See below figure that indicates
the difference between the cam
profiles in flat and roller
tappet camshafts.
2.
Roller tappet camshaft£ºThese
camshafts are designed for
actuating roller tappet. The
roller tappet has a bearing or
roller that contacts the cam
surface.
The cam
lobes designed for the roller
tappet have a more rounded
profile at the maximum lift (see
above diagram). Thus on the
roller cam surface, the tappet
stays at maximum lift position
for longer duration. Therefore
in the roller tappet camshaft,
the valves remain fully open
state (at maximum lift) for a
longer time.
The camshaft is run by the crankshaft at
half of the speed of the crankshaft.
It is necessary that the camshaft should
operate in such a way that the intake
and exhaust valve open and close at the
right time. It means that the valve
should open and close based on the
position of the piston during the
combustion cycle.
The coordination between position of
piston and valve opening is achieved by
one of the following three drives.
After machining, the camshafts undergo a
heat treating (surface hardening)
process. The cam surface wears due to
the friction between the cam surface and
tappet. This reduces the life of the
camshafts. Thus to increase wear
resistance of the cam surface, the
surface hardening is performed for
camshafts. Induction hardening,
Nitriding are the methods used for
surface hardening of the camshafts.
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