Chapter 5

Chapter 5

  • The effect of forces on a body is what we have considered so far.
  • The shape of the body will be examined.
    • The shape and size of the body change when a force is applied.
    • The body can be stretched, compressed, bent, or twisted depending on how the force is applied.
    • The body is distorted beyond its elastic limit if the force is large.
    • A bigger force will break the body.
    • The damaging effects of forces on bones and tissue will be examined.
  • Every part of the body is pulled apart by the applied force.
    • The cohesive force that holds the material together is resisting this force.
    • When the applied force exceeds the cohesive force, the material breaks.
    • The compression is elastic initially, but a large force will cause permanent damage.
  • A bar is stretched due to applied force.
  • Some materials are listed in Table 5.1.
  • The strength of these materials is shown.
  • An analogy can be drawn between a spring and a material.
  • When the stretching force is removed, work can be done by the stretched spring.
  • Expanding Eq can be seen as a sign of this.
  • By analogy with the spring.
  • Knowledge of the maximum energy that parts of the body can safely absorb allows us to estimate the risk of injury.
    • The bone is elastic until it breaks.
  • Consider the broken leg bones that have a combined length of 90 cm and an average area of 6 cm2.
    • The total energy absorbed by the bones of one leg is from Eq.
  • The two legs have more energy than this value.
    • The leg bones may break if all this energy is absorbed.
  • If the joints of the body bend and the energy of the fall is redistributed, it is possible to jump safely from a height greater than 56 cm.
    • There is a chance of injury in a fall from a small height.
  • A large force is put on an object in a collision.
    • The force starts at zero, increases to some maximum value, and then decreases to zero again.
  • It is difficult to determine the magnitude of the force during a collision because it takes place in a short period of time.
  • The collision force is larger in a fast collision than it is in a slower collision.
  • The injurious effects of collision were calculated in the preceding section.
    • The concept of impulsive force can be used to perform similar calculations.
    • The damage is caused by the force that causes it.
    • It depends on the type of collision.
    • The collision time is very short if the objects are hard.
    • The impulsive force is reduced if one of the objects is soft and yields during the collision.
    • It is less damaging to fall into soft sand than it is on a hard concrete surface.
  • Estimate of the collision duration is a difficult part of the problem.
    • If the impact surface is hard, such as concrete, and the person falls with his/her joints locked, the collision time is estimated to be about 10-2 seconds.
    • If the person bends his/her knees, the collision time is longer.
  • The force per unit area that may cause a bone break is shown in Table 5.1.
    • If the person falls on his/her heels, the impact may be 2 cm2.
  • We obtained this result from energy considerations.
    • It is reasonable to assume a 2- cm2 impact area.
    • The area may be smaller or larger depending on the nature of the landing.
    • There are more examples of calculating the injurious effect of impulsive forces.
  • The impact force can be calculated from the distance the center of mass of the body travels during the collision.
    • There is a bag in the dashboard.
    • In a crash, the bag expands and protects the passenger.
    • If contact with the hard surfaces of the car is to be avoided, the forward motion of the passenger must be stopped in 30 cm of motion.
  • The average speed.
  • There is a collision protective device.

  • The strength of body tissue is estimated.
  • The average stopping force and force per cm2 are at a 105 km impact speed.
    • The passenger would probably be hurt by the force.
  • The possibility that the bag may be triggered during normal driving has been considered in the design of this safety system.
    • If the bag were to remain expanded, it would make it harder for the driver to control the vehicle, so the bag is only expanded for a short time to cushion the impact.
  • Neck bones can be fractured by a moderate force.
  • If the impact is sudden, as in a rear-end collision, the body is accelerated in the forward direction by the back of the seat, and the neck is suddenly pulled back at full speed.
  • People who jumped out of airplanes with parachutes that failed to open and then survived because they landed on soft snow have been reported.
    • The body made a 1-m deep depression in the snow on impact.
    • The impact force that acts on the body during a landing can be calculated to verify the credibility of these reports.
  • We discussed the damaging effects of large impulsive forces in the beginning of the chapter.
    • The impact of feet with the ground in walking and running is one of the smaller repetitive forces that our bodies are subject to.
    • There is still a question as to the extent of the smaller repetitive forces that are encountered in exercise and sport.
    • Osteoarthritis is often caused by repetitive impact.
  • Osteoarthritis is a joint disease caused by wear and tear on the components of the joint.
    • The joint loses strength and flexibility as a result of wear and tear.
    • The underlying bone may begin to erode.
    • Osteoarthritis is a major cause of disability.
    • The most common affected joint is the knee.
    • The majority of men and women are affected by this condition after the age of 65.
  • A number of studies have been done to determine the link between exercise and arthritis.
    • The conclusion is that joint injury is related to osteoarthritis.
    • People who engage in high impact injury prone sports are more likely to have osteoarthritis.
    • There appears to be little risk associated with running 20 to 40 km a week.
  • An injured joint is more likely to wear and tear over time.
    • Un-lubricated bones have a higher coefficient of friction.
    • The ability of the joint to lubricate is usually compromised by a joint injury.
    • A simple picture would lead one to believe that the progress of osteoarthritis would be more rapid in the joints of people who are regular runners than in a control group of non- runners.
    • This doesn't seem to be the case.
    • Osteoarthritis seems to progress at the same rate in both groups, indicating that the joints have the ability to repair themselves.
    • The conclusions are subject to further study.
  • A 50 kilo runner trips and falls on his hand.
    • The length of the arm is 1 m and the area of the bone is 4 cm2.
  • The area of impact is 4 cm2 and the duration is 10-2 seconds.
    • The area of impact is 1 cm2.
  • Assume that the object is hard, that the area of contact with the skull is 1 cm2, and that the impact time is 10 to 3 seconds.
  • If you use the data provided in the text, you can figure out the mass of the head and the area of the neck.
  • A boxer is punching a bag.
    • His fist hits the bag at a speed of 7 m/s.
    • His hand came to a stop as a result of hitting the bag.
    • If the moving part of his hand is less than 5 kilo, you can calculate the rebound velocity and energy of the bag.