Principles of Biomechanics and Exercise

Stephan BetterBodyz van Breenen
Aquatic Fitness Therapy Training
Principles of Biomechanics
and Exercise

Biomechanics: “…. The study of forces
and the effects of those forces on living
things.
A force is not clearly defined..Only the
effects of a force

Effect of a force ?
Movement, Deformation, Biological change
“Any action which tends to cause a change
in motion/shape of a body

First Law
“Every object will remain at rest or continue
in its state of uniform motion unless it is
acted upon by an external force”

Law of Inertia
Inertia = body’s reluctance to change
Resistance to change its state of motion

Second Law
“When a net force acts on an object the
change in motion that is produced (the
acceleration) takes place in the direction of
the net force. This acceleration is proportional
to the net force and inversely proportional to
the mass of the object”

Law of Acceleration
Force = mass x acceleration (F = ma)

Third Law
“Every action has an equal and opposite
reaction”
Law of Action-Reaction
Forces come in pairs of equal and opposite forces

Most mechanical forces acting on the skeleton are
generated either through impact with the ground
(i.e., gravitational loading) or through muscle
contractions (i.e., muscle loading)

People who participate in sports that involve
weight-supported (e.g., non–weight-bearing)
exercise, such as cyclists and swimmers, have
commonly been found to have low BMD levels.
Because these activities generate relatively high
levels of muscle forces but no impact forces

Impact activities, through either ground- or joint-
reaction forces they generate, confer a unique
benefit on bone strength

Physical activities that involve impact forces, and
therefore generate both gravitation and muscle
loading, are most likely to have beneficial effects
on bone metabolism and reduce fracture risk

Newton’s Law of Gravitation:
Force is proportional to the product of their
masses and inversely proportional to the
distance between them

Gravity
Perpendicular & down Toward center of earth
g = -9.81 m/s2 (sea level)

Weight (Force)
Gravitational force of the earth on a body
Fwt = m x g
Where; wt = weight
m = mass
g = gravitational constant (~ 9.81 m/s2)

Reaction Forces Newtons third law
“Every action has an equal and opposite
reaction

Friction Forces
Resistance to movement between two surfaces in
contact

Maximum friction depends on
a) Magnitude of force pressing surfaces together
b) Surface factors

What is motion ?
Motion is a change in position with time

Linear motion
Translation
All of the parts of a body move the same distance
in the same direction at the same time
Units = Metres (m), can also be curvilinear

Angular motion
Rotation
Occurs when all of the parts of a body move
through the same angle, in the same direction, at
the same time
Units = Radian (rad) or degree (°)

Rotation about an axis
Axis (internal or external)
The central line through point of rotation,
perpendicular to the plane of the rotary motion

General motion
Combination of linear and angular
Most human motion is general motion

Distance vs Displacement
Distance = length or angle actually travelled
Scalar
Displacement = length or angle b/w start & end
Vector - length and direction

Angular displacement (θ)
Angular position (θ) angular position of a body
relative to zero angle
Angular displacement change in angular
position vector quantity
+ve anticlockwise
-ve clockwise

Angular Displacement Formula.
The angular displacement is defined as the angle
through which an object moves on a circular path.
It is the angle, in radians, between the initial and
final positions

Linear velocity (v)
Linear Velocity (vector)
Rate at which a body moves from one location
to another.
Units = meters per second (m.s-1)
v = s/t

Linear velocity (v)
Linear Acceleration (vector)
Change in velocity occurring over a given time
interval
Units = metres per second per second (m.s-2)
a = (v2-v1)/ t

Angular velocity (ω)
Average angular velocity:
Units: °.s-1, rad.s-1, rev.s-1 Vector

Angular velocity (ω)
Average angular speed:
Units: °.s-1, rad.s-1, rev.s-1 Scalar

Angular velocity formula
When an object is traveling along a circular
path, the central angle corresponding to the
object's position on the circle is changing.
The angular velocity, represented by w, is
the rate of change of this angle with respect
to time.

Angular Acceleration Formula.
The angular acceleration of a rotating
object is the rate at which the angular
velocity changes with respect to time. It is
the change in the angular velocity, divided
by the change in time

Absolute Vs. Relative joint angles
Absolute joint angles
Right-hand* horizontal OR vertical to distal end
of segment
Relative joint angles
Between segments

Linear & angular motion
Segment rotations produce linear motion of
Whole body
Point on a body
Body segment
Implement or equipment

Linear & angular motion
Key concept:
The motion of any point on a rotating body
(e.g. wheel) can be described in linear terms
Key information:
Axis of rotation
Radius of rotation

Linear & angular velocity
Linear variables for a point on a rotating body
are related to the angular variables for that body
Linear velocity;
v = r
v = m.s-1 = rad.s-1

linear angular acceleration formula
In rotational motion, tangential acceleration is a
measure of how quickly a tangential velocity
changes. It always acts perpendicular to the
centripetal acceleration of a rotating object. It is
equal to the angular acceleration α, times the
radius of the rotation.

Principles of Biomechanics and Exercise

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