Basic Biomechanics Mechanics-study of forces and motions produced by their action. Biomechanics-apply that to the structure and function of the human body.
Basic Biomechanics Statics deal with factors associated with nonmoving. Dynamics deal with moving systems –Kinetics are the forces causing the motion –Kinematics are time, space and mass of the moving system.
Basic Biomechanics Kinematics- –Osteokinematics bones moving in space in regard to joint surface (flexion) –Arthrokinematics are the manner in which joint surfaces move in relation to each other.(concave)
Basic Biomechanics Vector- quantity having both magnitude and direction –Force-push or pull action –You throw a ball with direction and speed
Basic Biomechanics Scalar- has only magnitude. –Length, area, volume, mass –Mass is the amount of matter a body contains. –Inertia is change in motion in either speed or direction.
Basic Biomechanics Law of Inertia- an object at rest tends to stay at rest, and an object in motion tends to stay in motion.
Basic Biomechanics Think about what happens with your head in a car. It is not in motion, so when acceleration/deceleration happen your neck is not always happy.
Basic Biomechanics Law of Acceleration-the amount of acceleration depends on the strength of the force applied to an object.
Basic Biomechanics Acceleration is inversely proportional to the mass of an object. –If you roll a soccer ball, then a bowling ball, with the same force, the heavier object will not travel as far.
Basic Biomechanics Law of action-reaction- every action there is an equal and opposite reaction. –Strength of reaction is equal to strength of action, just in the opposite direction. –Harder you jump harder you rebound.
Basic Biomechanics Go outside and create a demonstration of one of the laws of physics for us all to understand.
Basic Biomechanics Force (a vector describe magnitude and direction –Linear force- 2 forces act on the same line in the same direction or opposite direction. or
Basic Biomechanics Parallel Forces- –In the same plane and in the same or opposite directions.
Basic Biomechanics Concurrent Forces- two or more forces act from the same common point but pull in different directions
Basic Biomechanics Force Couple- two forces act in an equal but opposite direction resulting in a turning effect.
Torque –Angle of Pull: angle between muscle insertion and bone on which it inserts. Components of Force –Angular Force: force of a muscle contributing to bone's movement around a joint axis; greatest when muscles angle of pull is perpendicular to bone (i.e. 90 degrees). –Stabilizing force: degree of parallel forces generated on the lever (bone and joint) when the muscles angle of pull is less than 90 degrees. –Dislocating force: degree of parallel forces generated on the lever (bone and joint) when the muscle's angle of pull is greater than 90 degrees.
Basic Biomechanics State of equilibrium- all torques actin on it are even. Center of gravity- COG-balance point of an object at which torque on all sides are equal.
Basic Biomechanics Base of support is that part of the body that is in contact with the supporting surface. (BOS) Line of gravity is the imaginary vertical line that passes through the COG to center of earth. (LOG) Draw this in your notes pg 78
Basic Biomechanics Equilibriums –Sable- to disturb you would have to raise COG –Unstable- only slight force needed to disturb –Neutral- COG is not raise or lowered to disturb. –Lower COG is more stable.
Basic Biomechanics The closer COG is to center of BOS the more stable you will be
Basic Biomechanics Lets try it together. Stand up and stand on both legs, then balance on one standing straight up. Then lean to the side you are standing on. What changes.
Basic Biomechanics List some ways to increase stability –W–Wider base of support –G–Greater mass (which will decrease speed) –I–Increase friction (carpet vs ice) –F–Focus on stationary
Basic Biomechanics Simple Machines –4 types of Machines Lever Wheel and Axle Inclined plane The pulley
Basic Biomechanics Lever is a rigid bar that can rotate about a fixed point when a force is applied to overcome resistance.
Basic Biomechanics A-Axis is the fixed point around which the lever rotates. F-Force causes the lever to move. (muscle in the body) R-Resistance that must be overcome for motion to occur. ( can be gravity or the weight to move.)
Basic Biomechanics Force Arm distance between force and axis Resistance arm is distance from axis to resistance. A F R
Basic Biomechanics First-class lever –Axis is located between the force and the resistance. –Balance
Basic Biomechanics Second Class Lever –Has the axis at one end, the resistance in the middle, and force at the other end. –power
Basic Biomechanics Third class Leaver –Has the axis at one end with the force in the middle and resistance at the opposite end. –ROM
Basic Biomechanics The body has more 3 rd class levers because the body favors the advantage of ROM. Levers can change class depending on where the resistance is, if there is resistance added vs just gravity. Or if the direction gravity comes from changes. Pg 83-84
Basic Biomechanics Mechanical Advantage- ratio between the force arm and resistance arm. MA=FA RA Less force is needed when mechanical advantage is greater. Page 85 force arm on leg
Basic Biomechanics Pulley is a grooved wheel that turns on axle with rope or cable. –It allows for change of direction of force or to change the magnitude of a force.
Basic Biomechanics Fixed pulley is one attached to a beam. It acts like a fist class lever, it is used to change directions. Medical malleolus Acts as a pulley for the Tendon of peroneus longus
Basic Biomechanics Movable pulley has one end of the rope attached to a beam then the rope runs through the pulley to the other end where the force is applied. What is gained in force is lost in distance.
Basic Biomechanics Wheel and Axle- a lever in disguise. –Wheel with a crank attached. It helps increase the force exerted. –Large radius requires less force.
Basic Biomechanics Incline Plane is a flat surface that slants. –It creates more distance with less effort
Simple Machines Basic rule of simple machines: what is gained in force is lost in distance.