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Biomechanics

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Title: Biomechanics


1
Biomechanics
2
Biomechanics -- Defined
  • Bio - life living organism
  • Mechanics - the branch of physics concerned with
    the analysis of the action of forces on matter or
    material systems
  • Biomechanics the study of forces and their
    effects on living systems
  • Exercise Sport Biomechanics the study of
    forces and their effects on humans in exercise
    and sport
  • Applied or Functional Biomechanics (the focus
    of this class) the examination of the
    application of biomechanics in the exercise and
    sports field

3
Human Biomechanics
  • Applications of biomechanics (human biomechanics)
  • Purpose of the science understand, protect and
    enhance human function
  • Role in sport ultimately, to improve
    performance
  • Role in therapy rehabilitate, re-educate
  • Role in product design to design products that
  • optimally support human
    function
  • Role in injury prevention to minimize adverse
    stress and strain on the body through movement
    analysis, technique design and product
    development
  • Role in the workplace Ergonomics - to maximize
    productivity by minimizing worker fatigue and
    discomfort
  • Who uses biomechanics?

4
Mechanics - analysis of the action of forces on
matter or material systems
Mechanics
Deformable Body Mechanics
Fluid Mechanics
Rigid Body Mechanics
Relativistic Mechanics
Quantum Mechanics
Rigid Body objects are assumed to be perfectly
rigid Deformable Body objects can be deformed
by a force Fluid Gas or fluid
5
Humans Rigid or Deformable?
  • Biological tissue, including the human body, is
    by nature, deformable. It can absorb forces, it
    can stretch, bend, compress.
  • With regards to gross human movement, these
    deformations are relatively small, and for the
    sake of simplicity, Applied or Functional
    Biomechanics largely ignores these properties.
  • Each segment of the body is considered a rigid
    body linked together by joints.
  • In reality, repeated plastic deformation of
    biological tissue will result in injury.

6
Stress Strain Curve
  • Import curve here

Repetitive or prolonged stress at this strain
will eventually result in microdamage
(i.e. stress fracture)
7
Bone Stress-Strain Curve
Bone is relatively rigid note the rapid strain
Boney body segments determine human rigidity in
biomechanical terms
8
Branches of Rigid Body Mechanics
Rigid Body Mechanics
Statics
Dynamics
Statics mechanics of objects
Kinematics
Kinetics
at rest, or at constant velocity
Dynamics mechanics of objects in accelerated
motion
Kinematics describes the motion of a body
without regard to the forces or torques that may
produce the motion
Kinetics describes the effect of forces on the
body i.e.. muscular force, gravitational force,
external resistance force, ground reaction force,
etc.
9
Basic Dimensions and Units of Measurement Used in
Mechanics Biomechanics
  • Biomechanics is a quantifiable science,
    measurable, and can be expressed in numbers
  • Systeme-Internationale dUnites (SI Units)
  • Length measured in meters (m)
  • Time measured in seconds (s)
  • Mass measured in kilograms (kg), the measure of
    inertia, or resistance to a change in motion of
    an object

10
Mass vs. Weight
  • Mass is the measure of inertia, whereas Weight is
    the measure of the force of gravity acting on an
    object.

11
Additional Dimensions Units of Measure
  • Length millimeter (mm), centimeter (cm),
    kilometer (km), etc. are all based on the meter
    (m)
  • Time Minutes, hours, days, weeks, months,
    years, etc. can all be derived from the second
    (s)
  • Mass milligram (mg), gram (g), etc. are all
    based on the kilogram (kg)

12
Forces Torques
  • Force a push or pull exerted by one object on
    another come in pairs (Newtons 3rd Law)
    creates acceleration or deformation (Newtons 2nd
    Law) causes an object to start, stop, change
    direction, speed up or slow down (Newtons 1st
    Law)
  • SI Unit of Force is the Newton (N) force
    required to accelerate a 1 kg mass 1/m/s/s
  • Force is described by its size (magnitude) and
    direction
  • The angular equivalent of F is Torque (T) a
    Torque rotates an object about an A of R
  • T F x moment arm
  • Resultant Force the summation of all forces
    acting on a body determines the direction of the
    body

13
Forces (cont.)
  • Internal Forces and Torques forces or torques
    that act within the studied object i.e. the
    human body, or the object being manipulated by
    the human pole vault, soccer ball, etc. Internal
    forces can cause movement of body segments at a
    joint but cannot produce a change in the motion
    of a bodys C of M. Muscular force is the primary
    internal force examined in biomechanics. As the
    overwhelming majority of motion in the human body
    is angular, torque forces are more applicable in
    biomechanics.
  • (The terms Force and Torque will be used
    interchangeably throughout this course.
    Essentially, if the term Force is used to
    describe angular motion, "Torque is implied.)

14
Forces (cont.)
  • External Forces forces that act on an object as
    a result of its interaction with the environment
    surrounding it
  • Most External Forces are contact forces,
    requiring interaction w/ another object, body or
    fluid
  • Some External Forces are non-contact forces
    including gravitational, magnetic and electrical
    forces
  • The science of biomechanics largely deals with
    contact forces and gravity (weight), which
    accelerates objects at 9.8 m/s
  • Contact forces can be sub-divided into normal
    reaction force and friction

15
Contact Forces
  • Normal Reaction Force
  • line of action of the force is
  • perpendicular to the surfaces in
  • contact
  • Friction Force line
    of action
  • of the force is
    parallel to the
  • surfaces in contact

16
Reaction Friction Forces
17
Newtons Laws of Motion
  • Newtons Laws help to explain the relationship
    between forces and their impact on individual
    joints, as well as on total body motion.
  • Knowledge of these concepts can help one
    understand athletic movement, improve athletic
    function, understand mechanisms of injury, treat
    and prevent injury

18
Newtons Laws (cont.)
  • Newtons 1st Law Law of Inertia
  • A body remains at rest or in motion except when
    compelled by an external force to change its
    state. A force is required to start, stop, or
    alter motion
  • Inertia the tendency of a body to remain at
    rest or resist a change in velocity
  • Inertia is directly proportional to its mass
  • The angular equivalent is Mass Moment of Inertia

19
Mass Moment of Inertia
  • Mass Moment of Inertia (I) The resistance to
    change in a bodys angular velocity
  • Dependent on both the objects mass and on the
    distribution of mass about its axis of rotation
  • Radius of Gyration the average distance between
    the A of R and the C of M of a body (p)
  • I mass of the object multiplied by the square
    of the R of G
  • I m x p2

20
Law of Inertia Biomechanical Application
  • How can an athlete control their Mass Moment of
    Inertia? In other words how can they manipulate
    the resistance to change in angular velocity to
    attain a goal?

21
Newtons Laws (cont.)
  • Newtons 2nd Law Law of Acceleration
  • The acceleration of a body is directly
    proportional to the F causing it, takes place in
    the same direction in which the F acts, and is
    inversely proportional to the mass of the body
  • A velocity / time
  • F ma (Force mass x acceleration) (linear)
  • Angular equivalent of F is Torque (T)
  • T F x moment arm (rotational force applied to
    the A of R, through a moment arm)
  • T has the same relationship with direction and
    mass moment of inertia as F has with direction
    and mass
  • As I (moment of Inertia) increases (due to
    increased R of G or increased mass), Acceleration
    decreases

22
Newtons Laws (cont.)
  • Newtons 2nd (cont.)
  • Impulse-Momentum Relationship from Fma, we can
    derive Momentum (p) and Impulse
  • Impulse Force x time (Ft)
  • Momentum mass x velocity (mv)
  • Ft mv (impulse momentum)
  • If Ft increases, mv increases
  • Mass is considered constant
  • within biomechanics, therefore,
  • an increase in impulse implies an
  • increase in velocity
  • How are the principles of
  • Impulse and Momentum
  • used in the design of sports
  • equipment?

23
Newtons 2nd (cont.) Impulse-Momentum
  • Because Mass is constant, and because external
    forces are largely non-modifiable, in the world
    of sports and exercise, the duration of force
    application is the most modifiable
  • If the Force is not constant, impulse is the avg.
    force times the duration of that average force
  • Essentially, calculating force as average force
    holds that force as a constant, however it is the
    peak force that we need to minimize
  • If the application of Force is prolonged
    (increased time), in order to maintain the same
    magnitude of impulse (Ft), the Force magnitude
    (average and peak) must be lowered
  • Conversely, if the application
  • of Force happens more rapidly
  • (decreased time), there will be a
  • higher Force (avg. peak) in
  • order to maintain impulse

24
Newtons 2nd (cont.) Impulse-Momentum
25
Newtons 2nd Law (cont.) Impulse-Momentum
26
Newtons 2nd Law (cont.) Impulse-Momentum
27
Newtons Laws (cont.)
  • Newtons 2nd Law (cont.)
  • Work-Energy Relationship -- from Fma,
  • we can also derive Work (W)
  • Work Force x Distance
  • (W FD) (linear)
  • Angular equivalent Torque x Angular
    displacement (T x degrees)
  • Measured in Newton meters (Nm)
  • Work is a measure of strength,
  • measured by the extent to
  • which a force moves a body over
  • a distance without regard to time

28
Newtons Laws (cont.)
  • Newtons 2nd (cont.)
  • Power (P) the rate of work W/time
  • W/t F x D/t or F x Velocity (WFV)
  • Training power in an athlete requires doing work
    quickly, or explosively
  • How is Power measured and trained in sport and
    exercise?

29
Measuring and Training Power in the Athlete
30
Power in Sport
31
Newtons Laws (cont.)
  • Newtons 3rd Law Law of Action-Reaction
  • For every action, there is an equal and opposite
    reaction
  • The two bodies react
  • simultaneously, according
  • to Fma each body
  • experiences a different
  • acceleration effect which
  • is dependent on its mass

32
References
  • Neumann, D.A. (2002). Kinesiology of the
    Musculoskeletal System. St. Louis, Missouri.
    Mosby.
  • McGinnis, P.M. (2005). Biomechanics of Sport and
    Exercise 2nd ed. Champaign, IL. Human Kinetics.

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