basic concepts of biomechanics
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BASIC CONCEPTS OF BIOMECHANICS. MOTION & MOVEMENT. MOTION. Motion. Linear motion – straight or curved line. Motion along a line. All parts same speed / direction. Angular motion – circle or part of a circle. Movement around a fixed point or axis. - PowerPoint PPT PresentationTRANSCRIPT
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BASIC CONCEPTS OF BIOMECHANICS
MOTION & MOVEMENT
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MOTION
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Motion1. Linear motion – straight or curved line. Motion along a line. All parts same speed / direction.
2. Angular motion – circle or part of a circle. Movement around a fixed point or axis.
3. General motion – combination of linear and angular motion
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With a partner identify other sporting examples of:
1. Pure linear motion
2. Pure angular motion
3. General motion
You need to be able to explain why they are each type of motion
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What is a FORCE?
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Forces
A push or pull that alters or tends to alter, the state of motion of a body
“A force is that which alters or tends to alter a body’s state of rest or of uniform motion in a straight line.”If a body changes direction or speed, a force has been applied
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So give sporting examples of what a force can do.
Can it move something that is still to move?
E.G.,
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Force …… can …….
A. Cause a body at rest to move
B. Cause a moving body to change direction, accelerate or decelerate
C. Change an object’s shape.
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Look at this example and see where you can work out the F or force and what effect it has.
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A penalty kick or a goal keeper saving a shotEffect of force Example:
A force can cause a body at rest to move F exerted by foot – moves the ball from rest
A force can cause a moving body to change direction F exerted by GK hands redirects the ball
A force can cause a moving body to accelerate More F into kick = greater acceleration of the
ball
A force can cause a moving body to decelerate Wind resistance decelerates the ball
GK hands decelerates the ball
A force can cause a body to change its shape Ball out of shape on kick / foot contact
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A tennis player
Effect of force Example:
A force can cause a body at rest to move
F by leg muscles to move the ‘returner’ into position
A force can cause a moving body to change direction
Force of racket (body muscles) will be exerted onto ball and send ball in new direction (direction on the F applied)
A force can cause a moving body to accelerate
Greater muscular F exerted via racket to ball = greater acceleration of ball to server (lighter ball = greater acceleration too).
A force can cause a moving body to decelerate
Wind in opposing direction decelerates ball.Resistance, so decelerates ball (gives more time before contact)
Time in air = greater gravitational decelerationA force can cause a
body to change its shape
Racket contact with ball – ball warped (and racket)
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A sprint start out of the blocks and then completing a shuttle sprint
Effect of force Example:
A force can cause a body at rest to move Unless net (unbalanced) F acts, sprinters will stay
in blocks – stillA force can cause a moving body to change direction F from muscles and arms, pushes on blocks (N3L)
and pushes sprinter to change direction out of blocks.
A force can cause a moving body to accelerate Greater F – Quicker start time out of blocks and
acceleration down track
A force can cause a moving body to decelerate Greater wind resistance decelerates the sprinter
A force can cause a body to change its shape Air resistance – sprinters cheeks!
Drive from blocks – footwear and foot flatten / expand with F application
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What 2 factors will significantly affect the effects of FORCES being applied on the body or objects?
Size of the force
Direction of the force
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The link between FORCE and MOTION?
Without forces being applied, there will be no change in motion!
Whether still of moving.
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Laws of Motion
Sir Isaac Newton
3 Laws of Motion :
1 INERTIA2 ACCELERATION3 ACTION & REACTION
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1 Newton's First Law of Motion - INERTIA
This is the law of inertia, and states:
‘Everybody at rest, or moving with constant velocity in a straight line, will continue in that state unless acted upon by an external force exerted upon it’
Objects tend to remain either at rest or in straight line motion.
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Newton's First Law of Motion - INERTIA
In simple terms, to change the motion of an object or performer a force must be applied.
A golf ball will only move from the tee when a force is applied to it from the golf club
A sprinter will only move out of the blocks when they exert force from their muscles
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2 Newton's Second Law of Motion - ACCELERATION
This is the law of acceleration, and states:
‘The acceleration of a body is proportional to the force causing it and the acceleration takes place in the direction in which the force acts’
This law describes the relationship between net force, acceleration, and mass
Often described as:
F = ma Force = mass x acceleration
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2 Newton's Second Law of Motion - ACCELERATION
This law suggests that the greater the mass of an object, the greater the force required to give the same amount of acceleration and also the greater the force applied the greater the acceleration
For example, less force is applied to the shuttlecock than to a shot put in order for it to move
F - ma
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2 Newton's Second Law of Motion - ACCELERATION
At a constant velocity the force of tire friction (F1) and the force of air resistance (F2) have a vector sum that equals the force applied by the cyclist (Fa).
The net force is therefore 0.
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2 Newton's Second Law of Motion - ACCELERATION
More mass results in less acceleration when the same force is applied.
With the same force applied, the riders and the bike with twice as much mass will have half the acceleration, with all other factors constant.
Note that the second rider is not pedaling.
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In small groups Newton’s 2nd law One person is to
use the bats and balls to devise a sporting example to explain how mass and acceleration affect each other.
Those taking part can only agree or disagree.
If you do disagree you take over as the teacher.
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In small groups Newton’s 3nd law Are you able to do
the same for the third Law?
Those taking part can only agree or disagree.
If you do disagree you take over as the teacher.
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3 Newton's Third Law of Motion – ACTION & REACTION
This is the law of reaction, and states:
‘To every action there is an equal and opposite reaction’
When a swimmer for example exerts a force on the starting blocks, the blocks exert an equal and opposite reaction force upon the swimmer, propelling them into the pool
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3 Newton's Third Law of Motion – ACTION & REACTION
The American football player's foot is pushing against the ground, but it is the ground pushing against the foot that accelerates the player forward to catch a pass.
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Applying Newton’s Laws – SPRINT START
1st Law – INERTIA - remains at set unless a force affects them
2nd Law – ACCELERATION - push harder to get more acceleration
3rd Law – ACTION & REACTION - action force is muscular force, reaction force pushes athlete off blocks
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Free Flow Diagrams Draw a free flow diagram
using Newton's laws of motion to describe the resultant forces impacting on the ball. If you agree
with what is being drawn then allow them to continue.
If you disagree then you take over.
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What is ‘mass’?The amount of
material of which it is made.
Shot put vs foam ball
Used to advantage in sports?
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Centre of Mass The point at which the body is
balanced in all directions
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What factors affect the centre of mass?
Distribution of mass – symmetrical
Body position and shape – unsymmetrical; males vs females
Changing positions – HJ (Western Roll vs Fosbury Flop
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Class task With a partner one of you stand with your back
against a wall. Your heels against the wall
Try and place a ball down on the floor without moving your feet.
See if your partner can place the ball further away?
Why do you fall forwards?
Or if you don’t fall why do you feel like falling?
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Centre of Mass - summary
Distribution of weight around a balance point
The centre of a body's mass. In the
human body it is the point, which all parts are in balance with one another.
It is dependant on current position in space, anatomical structure, gender.
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Where is the CoM and why in this Sprint Start
Technique?
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What is ‘stability’?
Relates to how difficult it is to disturb a body from a balanced position
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Stability Is determined by :
Position of athlete’s centre of mass
Position of the athlete’s line of gravity= a line extending from the centre of mass vertically down to the ground.
Size of the athlete’s area of support
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Task gently apply a force to move the person adopting different stances.
Adopt a wide stance arms down Adopt a wide stance arms up Feet together arms down Feet together arms up
Is there a difference in how easy it was to move the person?
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Application of force.
We talked about angular and linear motion at the beginning of the class, so how can we create these types of motions?
Investigate how you can cause these
actions using the tennis ball. Think about the force that you are
applying and the centre of mass.
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Centre of Mass and Application of Force
Linear motion – force passes through the centre of mass DIRECT FORCE
Angular motion – force passes outside the centre of mass ECCENTRIC FORCE
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Application of Force & Centre of MassApplication
of FType of F Type of M Egs of this
F passes through
the C of M
DIRECT LINEAR •Tennis drive•Vertical jump•Shot put
F passes outside the
C of M
Movement in circle (part)
around axis of rotation
ECCENTRIC
ANGULAR
•Tennis topspin or slice•Curve ball / spin•Beckham free kick•Golf wedge shot
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Class task throwing a tennis ball.
Throw a tennis ball into the air making it spin.
Draw a diagram that shows the centre of mass, the point of application of Force Action/Reaction
Direction of force. What is the scientific name given to the
force resulting in the angular motion.
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Task Using the bat and ball in your groups can
you cause the ball to move in a linear motion by applying a direct force?
Can you apply an eccentric force to cause the body to move with an angular motion.
What would be a really good sporting example?
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Class task Sprint start Draw a free flow diagram of a sprinter
in the blocks. Explain the Laws of motion, mass, and
force.
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Adjusting body shape & angular motion
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