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Camshaft Design and Theory

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Camshaft Design and Theory Camshaft The brain of the engine Controls valvetrain operation Rotates at crankshaft speed Along with the crankshaft it determines ... – PowerPoint PPT presentation

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Title: Camshaft Design and Theory


1
Camshaft Design and Theory
2
Camshaft
  • The brain of the engine
  • Controls valvetrain operation
  • Rotates at ½ crankshaft speed
  • Along with the crankshaft it determines firing
    order
  • Along with the induction and exhaust systems it
    determines the useful rpm range of the engine

3
Camshaft Design
  • Features
  • Max lift or nose
  • Flank
  • Opening clearance ramp
  • Closing clearance ramp
  • Base circle
  • Exhaust opening timing figure
  • Exhaust closing timing figure
  • Intake opening timing figure
  • Intake closing timing figure
  • Intake to exhaust lobe separation

4
Camshaft Measurements
  • Lift
  • Duration
  • Lobe separation angle
  • Valve overlap
  • Intake valve opening (IVO)
  • Intake valve closing (IVC)
  • Exhaust valve opening (EVO)
  • Exhaust valve closing (EVC)

5
Lift
  • Lobe lift is the distance the lifter moves in one
    direction
  • Lobe lift is the difference in measurement
    between the nose of the lobe and the base circle
    of the lobe
  • Valve lift is what most people are taking about
    when they refer to lift and is simply lobe lift
    multiplied by the rocker arm ratio

6
Lift
  • Increasing the lift opens the valve further.
    This reduces the restriction to airflow at the
    valve and allows air to flow more freely into the
    cylinder.
  • At some point the valve can be opened to a point
    at which the port is the valve is no longer the
    greatest restriction to airflow, and at that
    point opening the valve further will not increase
    airflow.
  • The distance a valve can be opened is limited by
    duration, rocker arm ratio, lifter design,
    camshaft design and valve to piston clearance.

7
Duration
  • Duration is the length of time (measured in
    degrees of crankshaft rotation) that the valve
    remains open
  • The point at which a valve is considered open
    will be given along with the duration figure
    (i.e. .004, .006, .050)
  • Example (240 degrees _at_ .050)

8
Duration
  • At higher engine speeds the valve opens and shuts
    in a shorter amount of time. This limits how
    completely the cylinder can be filled.
  • Longer duration camshafts hold the valve open
    longer, increasing the amount of time the
    cylinder has to fill.

9
Duration Vs. Time
  • At 2000 RPM a camshaft with 200 degrees of intake
    valve duration, the intake valve is open for
    0.0166 seconds/cycle
  • At 6500 RPM the valve is only open for .005128
    seconds/cycle
  • If we substituted a camshaft with 245 degrees of
    duration this time would increase to .0204
    seconds/cycle _at_ 2000RPM and .00628 seconds/cycle
    at 6500RPM
  • This is a 22 increase in time available to fill
    the cylinder

10
Lobe Separation Angle
  • Lobe separation angle (LSA) is the number of
    degrees separating the point of peak exhaust lift
    and peak intake lift.
  • Lobe separation angle directly impacts the amount
    of valve overlap.
  • Because of this, production vehicles usually
    employ a wide LSA to reduce valve overlap and
    increase idle quality.

11
Valve Overlap
  • Valve overlap is the time in which both the
    intake and exhaust valves are open.
  • Valve overlap is affected by LSA and duration.
  • Valve overlap is used because of the principle of
    exhaust scavenging (the exiting exhaust gases
    help pull in the fresh intake charge,
    especially at higher rpm when fill time is
    limited).
  • At low RPM when intake port speed is low, a long
    valve overlap period will cause reversion into
    the intake port (the cylinder pressure exceeds
    the force of the air in the intake port and
    exhaust gasses are forced into the intake port).
  • This causes the lumpy idle associated with big
    camshafts.

12
Intake Valve Closing
  • Most critical valve opening/closing point
  • To early of an IVC and the cylinder may not have
    time to fill completely
  • To late of an IVC and the cylinder pressure will
    overcome the inertia of the incoming airflow and
    revert flow back into the intake port
  • This causes a serious disruption to flow and
    destroys any pressure waving tuning

13
Exhaust Valve Opening
  • 2nd most critical valve opening/closing event
  • Determines the balance between power event
    efficiency and exhaust pumping losses
  • To early of an exhaust opening will reduce the
    amount of energy converted from cylinder pressure
    to mechanical force on the piston
  • To late of an EVO will cause an increase in the
    amount of power needed to expel the burned
    exhaust gases from the cylinder

14
Exhaust Valve Closing
  • Along with IVO it is the least critical valve
    timing event
  • Along with IVO it determines the amount of valve
    overlap and exhaust scavenging
  • Too early of an EVC will not allow the exhaust
    gas to be fully purged from the cylinder
  • Too late of an EVC will allow fresh air/fuel mix
    to be purged into the exhaust system

15
Intake Valve Opening
  • Along with EVC it is the least critical valve
    timing event
  • Along with EVC it determines the amount of valve
    overlap and exhaust scavenging
  • Too early of an IVO will allow exhaust gas
    reversion into the intake ports causing major
    flow disruption and intake charge dilution
  • Too late of an IVO will limit the time available
    for the cylinder to completely fill

16
Cam Phase Graph
17
Cam Card
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