Presentation is loading. Please wait.

Presentation is loading. Please wait.

Basic Biomechanics Chapter 3. Terms  Mechanics Study of physical actions and forces  Kinematics: Description of motion (e.g, how fast, how high, etc.)

Published bySilvester Ellis Modified over 8 years ago

Similar presentations

Presentation on theme: "Basic Biomechanics Chapter 3. Terms  Mechanics Study of physical actions and forces  Kinematics: Description of motion (e.g, how fast, how high, etc.)"— Presentation transcript:

1 Basic Biomechanics Chapter 3

2 Terms  Mechanics Study of physical actions and forces  Kinematics: Description of motion (e.g, how fast, how high, etc.) without consideration given to its mass or the forces acting on it.  Kinetics: The study of forces associated with motion. Example: Pushing on the table may or may not move the table, depending upon the strength and direction of the push

3 Machines  The musculoskeletal system is a series of simple machines  Machines are used to create a mechanical advantage  They may balance multiple forces  Enhance force thus reducing the amount of force needed to produce  Enhance the range of motion or the speed of movement

4 Levers  Levers are used to alter the resulting direction of the applied force  A lever is a rigid bar (bone) that turns about an axis of rotation or fulcrum (joint)  The lever rotates about the axis as a result of a force (from muscle contraction)  The force acts against a resistance (weight, gravity, opponent, etc.)

5 Levers  The relationship of the points determines the type of lever  The axis (joint), force (muscle insertion point), and the resistance (weight, etc.)

6 First Class A F R FARFAR

7

8  Neck extension  Erector spinae and Splenius A F R

9 First Class

10  Elbow extension  Triceps A F R

11 First Class  Designed for speed and range of motion when the axis is closer to the force  Designed for strength when the axis is closer to the resistance A F R A

12 Second Class A FR ARFARF

13

14  Plantar flexion  Gastrocnemius and Soleus A F R

15 Second Class

16  Designed more for force

17 Third Class A F R AFRAFR

18

19  Elbow flexion  Biceps brachii and Brachialis A F R

20 Third Class

21 Table 3.1 CLASS ARRANGEMENTARM MOVEMENT FUNCTIONAL DESIGN RELATIONSHIP TO AXIS PRACTICAL EXAMPLE HUMAN EXAMPLE 1 ST F-A-R Resistance arm and force arm in opposite direction Balanced movements Axis near middle SeesawErector spinae neck extension Speed and range of motion Axis near force ScissorsTriceps Force (Strength) Axis near resistance Crow bar 2 ND A-R-F Resistance arm and force arm in same direction Force (Strength) Axis near resistance Wheel barrow, nutcracker Gatroc and soleus 3 RD A-F-R Resistance arm and force arm in same direction Speed and range of motion Axis near force Shoveling dirt, catapult Biceps brachii

22 Factors In Use of Anatomical Levers  A lever system can be balanced if the F and FA equal the R and RA F

23 Balanced A R F Force Arm Resistance Arm

24 Balance with More Force A R F Force ArmResistance Arm

25 Balanced with Less Force A R F Force Arm Resistance Arm

26 Factors In Use of Anatomical Levers  A lever system can become unbalance when enough torque is produced  Torque is the turning effect of a force; inside the body it caused rotation around a joint.  Torque = Force (from the muscle) x Force Arm (distance from muscle insertion from the joint)

27 Practical Application  Force is produced by the muscle  FA the distance from joint (i.e. axis or folcrum) to insertion of the force  Resistance could be a weight, gravity, etc.  RA the distance from joint to the center of the resistance Force Resistance

28 Examples 1. How much torque needs to be produced to move 45 kg when the RA is 0.25 m and the FA is 0.1 meters?  Use the formula F x FA = R x RA  Note: A Newton is the unit of force required to accelerate a mass of one kilogram one meter per second per second. Force Resistance

29 Example 1  F x 0.1 meters = 45 Kg x 0.25 meters  F x 0.1 kg = 11.25 Kg-meters  F = 112.5 Kg A 45 ? FA = 0.1 RA = 0.25

30 Example 2: Increasing the FA 2. What if the FA was increased to 0.15 meters?  F x 0.15 meters = 45 Kg x 0.25 meters  F x 0.15 = 11.25 Kg-meters  F = 75 Kg A 45 ? FA = 0.15 RA = 0.25

31 Example 3: Decreasing the RA 3. What if the RA was decreased to 0.2 meters?  F x 0.1 meters = 45 Kg x 0.2 meters  F x 0.1 = 9 Kg-meters  F = 90 Kg A 45 ? FA = 0.1 RA = 0.2

32 Summary  The actual torque needed to move a given resistance depends on the length of the FA and RA  As the FA increases or RA decreases, the required torque decreases.  As the FA decreases or RA increases, the required torque increases.

33 Levers Continued  Inside the body, several joints can be “added” together to increase leverage (e.g. shoulder, elbow, and wrist.  An increase in leverage can increase velocity

34 Lever Length  Where is the velocity or speed the greatest; at S’ or Z’?  How can this principle be applied to tennis? S’Z’ SZ

35 Lever Length  A longer lever would increase speed at the end of the racquet unless the extra weight was too great. Then the speed may actually be slower.

36 Wheels and Axles  Wheels and axles can enhance speed and range of motion  They function as a form of lever  Mechanical advantage = radius of wheel / radius of axle R = 3” R = 1”

37 Wheels and Axles  Consider the humerus as an axle and the forearm/hand as the wheel  The rotator cuff muscles inward rotate the humerus a small amount  The hand will travel a large amount  A little effort to rotate the humerus, results in a significant amount of movement at the hand H

38

Download ppt "Basic Biomechanics Chapter 3. Terms  Mechanics Study of physical actions and forces  Kinematics: Description of motion (e.g, how fast, how high, etc.)"

Similar presentations

Chapter 10: Movement and Forces 10.1 The skeletal system provides movement and protection 10.2 The muscular system makes movement possible 10.3 Muscles.

Chapter 10: Movement and Forces 10.1 The skeletal system provides movement and protection 10.2 The muscular system makes movement possible 10.3 Muscles.
Machines and the Body By, Vijaya George.

Machines and the Body By, Vijaya George.
The Study of Levers Types of Levers Mechanical Advantage

The Study of Levers Types of Levers Mechanical Advantage
Force and Motion https://www.youtube.com/watch?v=8iKhLGK7HGk https://www.youtube.com/watch?v=8iKhLGK7HGk.

Force and Motion
Big Idea Science Standard 6.h; 6.i Students know how to compare joints in the body (wrist, shoulder, thigh) with structures used in machines and simple.

Big Idea Science Standard 6.h; 6.i Students know how to compare joints in the body (wrist, shoulder, thigh) with structures used in machines and simple.
Biomechanics of musculoskeletal system (pp ) -Objectives

Biomechanics of musculoskeletal system (pp ) -Objectives
By: Adhithi Raghavan Period 1.  Force - the push or pull on an object.  Work- when you exert a force on an object to make the object move a distance.

By: Adhithi Raghavan Period 1.  Force - the push or pull on an object.  Work- when you exert a force on an object to make the object move a distance.
Biomechanics Principles of Levers.

Biomechanics Principles of Levers.
ACE’s Essentials of Exercise Science for Fitness Professionals

ACE’s Essentials of Exercise Science for Fitness Professionals
The Basics of Physics.

The Basics of Physics.
Factors Influencing Production of Muscular Tension and Applied Force n Force-velocity relationship - Fig 6.17, p 162 n Length - tension relationship -

Factors Influencing Production of Muscular Tension and Applied Force n Force-velocity relationship - Fig 6.17, p 162 n Length - tension relationship -
An analysis of human movement: Joints, Muscles and Mechanics in specified sporting actions (including planes and axes) What you need to know: Analyse shoulder.

An analysis of human movement: Joints, Muscles and Mechanics in specified sporting actions (including planes and axes) What you need to know: Analyse shoulder.
Lever system of the body

Lever system of the body
Levers.

Levers.
KINESIOLOGY دکترامیر هوشنگ واحدی متخصص طب فیزیکی و توانبخشی قسمت 3.

KINESIOLOGY دکترامیر هوشنگ واحدی متخصص طب فیزیکی و توانبخشی قسمت 3.
Levers. Definition A simple machine A board or bar that rests on a turning point called the fulcrum Used to change the amount, the strength and the direction.

Levers. Definition A simple machine A board or bar that rests on a turning point called the fulcrum Used to change the amount, the strength and the direction.
4 FUNCTIONS of MACHINES 1. Balance 2 or more Forces 2. Force advantage 3. Linear ROM and/or Speed 4. Change direction of F motive.

4 FUNCTIONS of MACHINES 1. Balance 2 or more Forces 2. Force advantage 3. Linear ROM and/or Speed 4. Change direction of F motive.
Math Review Scalar Quantities: (Magnitude only) Mass Mass Volume Volume Density Density Speed Speed Vector Quantities (Magnitude and direction) Force Force.

Math Review Scalar Quantities: (Magnitude only) Mass Mass Volume Volume Density Density Speed Speed Vector Quantities (Magnitude and direction) Force Force.
Levers kinesiology unit 7.

Levers kinesiology unit 7.
Module 2562 A.2.1 FORCE FORCE is push or pull the unit is the NEWTON (10 N is approx the weight of 1 kg) force changes the state of motion of an object.

Module 2562 A.2.1 FORCE FORCE is push or pull the unit is the NEWTON (10 N is approx the weight of 1 kg) force changes the state of motion of an object.

Similar presentations

Ads by Google