Transcript Document

CHAPTER 6
BIOMECHANICAL PRINCIPLES OF FORCE
PRODUCTION
Coefficient of restitution
Summation of momentum
KEY KNOWLEDGE
• Newton’s laws of motion, including an understanding of force, mass
and weight, acceleration and inertia applied to sport and physical
activities.
• The principle of conservation and transfer to momentum, impulse
and sequential and/or simultaneous force summation applied to
sport and physical activities.
• Angular motion including torque, angular velocity, momentum and
moment of inertia and their application to sport and physical
activities.
• Elasticity and the coefficient of restitution of sport equipment and
the effect of rebound velocity on performance.
• INERTIA
• The tendency of an object to resist change in its state of motion.
• An object will remain in a state of rest or constant motion unless acted
upon by
• an external force. Inertia is a tendency for a body to resist change in its
state of motion, whether that be at rest or moving with a constant
velocity.
• It is much harder to move or change the state of motion of an object that
has a greater amount of inertia.
• The amount of inertia an object has is directly related to its mass.
•
The more massive an object, the greater the force needed to change its
state of motion.
• The amount of force needed to move a 100 kg barbell is much greater
than the amount needed to move a 5 kg barbell. The heavier barbell has
much greater inertia than the lighter one.
• A wet football requires greater force to move it a set distance than a dry
football because as the ball becomes waterlogged the mass increases.
MASS AND WEIGHT
• Mass- the amount of matter that makes up an object.
• Weight- the measure of gravitational force acting on a body
Mass and weight are two different quantities that are often used
interchangeably.
Mass is a measure of the amount of matter an object is made up of.
The units of mass
are kilograms, and because body ‘weight’ is often given in kilograms
the two terms
are often used to mean the same thing. However, weight is a force
that is exerted on
the body by gravity. Weight is directly proportional to the mass of an
object. It can
be calculated by multiplying mass by the acceleration due to gravity
(9.8 m/s2). As
weight is a force, the units are newtons.
FORCE
•
•
•
•
•
•
•
•
The force of gravity will pull a ball
back to the ground after it has been thrown, hit or kicked.
The force generated in a muscle when it contracts pulls on the bone to
produce movement.
A force is defined as a push or pull.
Forces can produce movement or change the motion of an object.
The force a cyclist applies to the pedals produces movement of the bike,
which is a change in the motion of the bike from stationary to moving.
The forces absorbed by a baseball glove when a ball is caught correctly
prevent the player getting hurt by the impact of the ball.
The force changes the motion of the ball by stopping
the flight of the ball. Even though all forces produce or alter
movement, it is not always obvious.
MOMENTUM
• Momentum is a measure of the amount of motion that an object has. The
amount of momentum
• an object has is directly related to its mass and its velocity. Momentum is
equal to the mass of the object multiplied by the velocity of the object and
has the units kg m/s:
momentum = mass × velocity
IMPACT
• A collision between two objects can be considered to be an impact.
• In sport, the impact occurs between a ball and another contact surface
such as a bat, body part or ground surface.
• The type of collision that occurs determines the motion of the ball after
impact.