Stability & Levers

Created by

Kacie Jones

Cards (22)

Centre of Mass (CoM)
the point at which a body is balanced in all directions/ the point from which the weight of a body appears to act
Stability
the ability of a body to resist motion & remain at rest/ the ability of a body to withstand a force applied & return to its original position without damage
Centre of Mass
location is dependent on the distribution of body mass & can be manipulated to improve sporting technique by altering body shape
can move outside the body & acts as a point of rotation
density & position are difficulties when locating the CoM
e.g Fosbury Flop high jump technique - uses a j-curve to allow greater velocity in approach, athlete CoM is moving outside of body & below the bar when jumping, requires less force at take-off to clear the same height
Stability
more stable = harder to move
it an object is stable, it wants to stay still
Factors Affecting Stability
mass of the body - greater mass of body = greater stability (sumo wrestlers typically have a high mass)
height of CoM - lower CoM = greater stability (gymnasts flex at knee & hip to lower CoM when landing jumps)
base of support - greater size of base of support = greater stability, can be moving 2 points of contact wider or increasing the number of points of contact (2 feet 2 hands in a bridge position)
line of gravity - more central line of gravity is to base of support = greater stability (netball goal shooters line of gravity falls within her base of support)
Maximising Stability
sprinter preparing in the blocks
crouched position gives low CoM
base of support is large, 5 points of contact
line of gravity falls within base of support
high mass due to high proportion of muscle mass
Minimising Stability
when set is called sprinter lifts their hips, raising their CoM
one knee is lifted, reducing points of contact
leans forwards, shifting line of gravity to edge of base of support
reduces stability ready for movement
Lever Systems
the coordination of our bones & muscles to create human movement
2 Main Functions of Lever Systems
to generate muscular effort to overcome a given load
to increase the speed of a given movement
Components of a Lever System
lever (bone)
fulcrum (joint)
effort (muscular force)
load (weight/resistance)
Lever
rigid structure which rotates around a fixed point
Fulcrum
the fixed point about which the lever rotates
Effort
the force applied by the user of the lever system
Load
the force applied by the lever system
1st Class Lever
extension of the neck when preparing to head a football
the effort is the muscles in the neck contracting, the fulcrum is the neck joint, & the load is the weight of the head
has a mechanical advantage

load-fulcrum-effort
2nd Class Lever
calf raise
the fulcrum is the toes/ball of the foot (ankle), the load is the weight of the performers body weight & gravity, & the effort is the gastrocnemius contracting
have a mechanical advantage

fulcrum-load-effort
3rd Class Lever
flexion of the elbow during a bicep curl
the fulcrum is the elbow joint, the effort is the bicep brachii contracting, & the load is the performer weight & the weight their holding
most common lever in the body

load-effort-fulcrum
Way to Remember Levers
1-F-N
2-L-A
3-E-E
Effort Arm
the distance from the fulcrum to the effort
Load Arm
the distance from the load to the fulcrum
Mechanical Advantage
when a levers effort arm is longer than its load arm
means a large load can be moved with relatively little effort
occurs in second class levers
Mechanical Disadvantage
when a levers load arm is longer than its effort arm
means a large effort is required to life a relatively small load
occurs in third class levers