PHYSICS OF
FORCE, WORK, POWER, VELOCITY AND ACCELERATION
Physics
relating to the force, work, power, velocity and acceleration defines the
quantities and establishes their relationship with mathematical treatment. This
helps us establishing thrust formula, power and work expression for aircraft
gas turbine engines.
Force:
Force is
defined as external influence acting on a body to make a change in the state of
rest or state of motion of the body. It is a vector quantity having a magnitude
and direction of action.
Velocity: This is the change in
speed of a moving body per unit time in a specific direction of motion. This is
a vector quantity having a magnitude and the direction.
Acceleration: This is the rate of change of velocity of a moving body.
Relationship of Force, Velocity and Acceleration: The relationship is
established on the basis of Newton ’s
Laws of motion. There are 3 Laws stating the nature of state of rest and state
of motion of a body. These Laws are as follows:
First Law: "A body will
continue its state of rest or of uniform motion in a straight line unless
compelled by some external force to change its state."
This is actually the law of INERTIA. It is due to
the inertia that body at rest tends to remain at rest, and a body in motion
tends to continue its motion with the same velocity (speed and direction), in a
straight line. The law expresses the necessity of an external force to overcome
the effect of inertia.
An aircraft in level flight (cruise) is under zero
resultant force, but it continues to fly at constant speed and direction due to
inertia. To accelerate (or decelerate) the aircraft, Pilot must increase
throttle to create extra thrust as an unbalanced force.
This law has a close relationship with ‘momentum’.
Momentum is the product of mass (m) and velocity (V) and is a vector having
magnitude and direction. The direction of momentum of a body is the same as the
direction of related motion.
From Newton 's
first law, under no external force, momentum of a body is constant (either ZERO
or a non-zero constant quantity). To change the momentum, an external force
must act on to the body.
How much force will be required to make a change
in motion or momentum, or, how much change in momentum will be effected by a
force, is expressed in the 2nd Law.
Second Law: "The rate of change
of momentum of a body is proportional to the applied force and takes place in
the direction in which the force acts."
This law states the relationship between the force
applied to an object and the resultant change of momentum in that
direction.
Normally, the mass of an object is constant and
the relation becomes:
F = (mv-mu)/t = m(v-u)/t =ma
Where, m
is the mass, u is the initial
velocity, v is the velocity after t second, F is the applied force acting in the direction of motion, a is the acceleration, mu is the initial momentum, mv is the momentum after t seconds.
This formula has direct
application in mathematical treatment of jet-propulsion of an aircraft gas
turbine engine.
Third Law: "For every action, there is an equal and opposite
reaction."
This
law gives the mutual relationship between bodies acting on each other with or
without contact. The action and reaction always exist in a pair.
The
condition of a book resting on a table will produce an action and reaction
pair. The weight of the book will exert a force on the top of the table, and
the table will exert a lift on the book to prevent it from falling down under
gravity.
In
the physics of jet-propulsion, the 2nd Law is used in mathematical
formulation of the action force applied by the engine on to the working
fluid (air and gas flow) undergoing change in momentum. According to the 3rd
law, there is a reaction pair of this action force applied on to the engine by
the gas. This reaction is the propulsive force or the thrust. Thus,
the 2nd law action force formula is taken as the reaction force
(thrust) formula.
Work: Work is a quantity found
by multiplying force acting on a body and the distance through which the body
has displaced in the direction of the force due to its action. It is a scalar,
having only the quantity. If there is no displacement in the direction of
force, it is said that the force has not performed any work, or the work
performed is zero.
Energy:
This is
the capacity of doing work.
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