Biomechanical Principles of Force and Momentum. Newton’s Three Laws of Motion O Newton has 3 Law’s of motion, these are: O 1. The Law of Inertia O An.

Biomechanical Principles of Force

and Momentum

Newton’s Three Laws of Motion

O Newton has 3 Law’s of motion, these are:O 1. The Law of Inertia

O An object will remain at rest or in a uniform motion in a straight line unless acted upon by an unbalanced force.

O 2. The Law of Force, Mass & AccelerationO F = M x AO The acceleration of an object depends on

the mass and force of an object.O 3. The Law of Action & Reaction

O For every action there is an equal and opposite reaction.

Biomechanical Principles of ForceO Force is a push or pull on an object upon

interaction with another objectO Two important points to be aware of

O The point of application of the Force (where the force is applied)

O The line of action of the Force

Picture taken from; http://www.wikihow.com/Stop-on-Ice-Skates

ReferenceMontana State University.(1998), http://btc.montana.edu/olympics/physbio/glossary/g06.html The Physics classroom.(2014). http://www.physicsclassroom.com/class/newtlaws/u2l2a.cfm

Biomechanical Principle of Force

O Force is calculated by

F = ma (F = Force, m = Mass, a = Acceleration)

O Force is reported in the unit called Newtons (SI units)O To describe results as Newton we say

“10.0 N” is 10 newtons of force

Pic Taken from Dharma Consulting ; http://dharmaconsulting.com/products/accelerating-change/

Types of ForceO Contact Forces:

O Applied forceO Gravitational forceO Normal forceO Frictional forceO Air resistance forceO Tension forceO Spring force

O Action at distance forces:O GravitationalO ElectricalO Magnetic

The Physics classroom.(2014). http://www.physicsclassroom.com/class/newtlaws/u2l2a.cfm

Biomechanical Principles of ForceClassroom Activity1. Each student go up to a wall specified by the teacher and try and push it down. Explain why you could or couldn’t move that wall

2. Pair up with someone your own size, stand back to back and try and move the other person back. Try this same concept with someone who is bigger and smaller than you

Examples of ForceO http://www.youtube.com/watch?v=fqQVpQ0AeAc

O Ground vs MassO http://www.youtube.com/watch?v=eiYMK7wf57g

Biomechanical Principle of Momentum

O Momentum is the product of the mass and the velocity of an object.

O Easy description of momentum “how strong a moving object is”O The lighter the object the less momentum they will have when moving. Eg : a small

pebble or rockO The heavier the object the more momentum this will have when moving ; Eg : Train or Car

O Momentum is calculated by the mass of the body multiplied by its velocity. (Measured in kilogram metres per second.)

momentum = mass X velocity(speed)

Pic taken from http://www.mikanet.com/museum/item.php?cat=2&index=53

Ref ; Chapter 3—Applying biomechanics to sport pg75 Retrieved 7th March, 2014 from https://www.oup.com.au/titles/secondary/health__and__physical_education/physical_education/queensland/9780195573862/03_RUS_QSPE_3pp.pdf.

Physics for kids.(2014). Retrieved March 7, 2014 from http://scienceforkids.kidipede.com/physics/space/momentum.htm

Momentum

O Momentum = mass x accelerationO When an object has momentum it is in

motion. There are two types of motion:O Linear motion: movement in a particular

direction.O Rotational motion: movement about an axis.

O Physics of Football – MomentumO https://www.youtube.com/watch?v=hTZI-kpp

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Biomechanical Principle of Momentum

Velocity affects momentum.

Examples of this areO A batter, either in cricket or baseball trying to hit the ball further will swing

the bat quicker, increasing the velocity to apply more momentum

1. Pic taken from http://www.wallpapergate.com/wallpaper10227.html2. Pic taken from http://news.xinhuanet.com/english/2008-08/20/content_9554767.htm

In most sports, mass is constant, so velocity becomes the main factor influencing momentum.

Biomechanical Principle of Momentum

Example of mass effecting momentumO Chances of stopping a baseball. Its fast but because of

its weight you have a chance to stop it, whereas if a car was coming at you, because of the weight which would increase the momentum this would be impossible to stop

O Momentum can also be used to increase the execution of skills in sports.

O Example of this is the difference between kicking on the run and kicking off one step

1. Kicking on the run (AFL) ; http://www.youtube.com/watch?v=GPW2ywB7EGk

2. Short Pass (Soccer) ; http://www.youtube.com/watch?v=iThOfiT-1to

3. One step kick (AFL) ; http://m.youtube.com/watch?v=4AwCi1mIv6M

Biomechanical Principle of Momentum

Transfer of momentum

“Newton’s first law of motion explains that once a body is in motion, it will tend to stay in motion unless acted on by another force. The principle of the transfer of momentum states that momentum cannot be lost—it is just transferred from one object to another.” (Applied Biomechanics of Sport, pg 91)

This is simply transferring the weight from one object to another

Eg ; The run up gathers the momentum to increase the distance covered in the triple jump or long jump

Biomechanical Principle of Momentum

Classroom Activity

Look at the difference in distance between a standing jump off two feet and a jump coming off a run of 5+ steps. Do this in pairs or if location is appropriateRef ; Chapter 3—Applying biomechanics to sport pg91 Retrieved 7th March, 2014 from https://www.oup.com.au/titles/secondary/health__and__physical_education/physical_education/queensland/9780195573862/03_RUS_QSPE_3pp.pdf.

Activity 2Refer to Appendix A : Momentum of the Human Body. Read and complete task in groups of 4-5

Ref : Corrie,M.,Malpeli,R.,Seery,P.,Whittle,R.(2010). Biomechanical Principles of force production. Phyiscal Education VCE unit 1 & 2 1st ed. Nelson Cenage Learning. Pg 105

ConclusionO Newton’s 3 laws of motion are a critical

component of biomechanics. These are:O 1. The Law of InertiaO 2. The Law of Force, Mass & AccelerationO 3. The Law of Action & Reaction

O Force = mass x accelerationO Types of force: Applied force, Gravitational force,

Normal force, Frictional force, Air resistance force, Tension force, Spring force.

O Momentum = mass x accelerationO Two types of motion: linear & rotational