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Physics and Forces Dynamics Newton’s Laws of Motion  Newton's laws are only valid in inertial reference frames:  This excludes rotating and accelerating.

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Presentation on theme: "Physics and Forces Dynamics Newton’s Laws of Motion  Newton's laws are only valid in inertial reference frames:  This excludes rotating and accelerating."— Presentation transcript:

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2 Physics and Forces Dynamics

3 Newton’s Laws of Motion  Newton's laws are only valid in inertial reference frames:  This excludes rotating and accelerating frames.  For instance, when your car accelerates, it is not an inertial reference frame.  That's why you suddenly seem to accelerate backwards without any force acting on you. You’re not accelerating, you’re sitting still.  The reference frame, the car, is accelerating underneath you.

4  Newton’s second law is the relation between acceleration and force.  Acceleration is proportional to force and inversely proportional to mass.

5  Mass is measured in kilograms (kg).  Acceleration is measured in meters/second 2 (m/s 2 )  Therefore, the unit of force, the Newton, can be found from Newton’s second law.  Σ F = ma

6 Weight  Close to the surface of the Earth, where the gravitational force is nearly constant, the weight is:  What is the weight of a 25 kg object located near the surface of Earth?

7 Mass vs. Weight  Mass is a measure of the inertia of an object or the amount of matter it contains.  Weight is the force exerted on that object by gravity.  If you go to the moon, whose gravitational acceleration is about 1/6 g, you will weigh much less. Your mass, however, will be the same.

8  An object at rest must have no net force on it. If it is sitting on a table, the force of gravity is still there; what other force is there?  The force exerted perpendicular to a surface is called the normal force. It is exactly as large as needed to balance the force from the object  If the normal force gets too big, something breaks! Resting Force  An 8 N vase is sitting on a table. What is the normal force supplied by the table?

9 Weight and Normal Force  Since the normal force on a surface must counterbalance the weight of an object, the normal force is really just equal to the force of gravity…

10  The symbol " Σ " means "the sum of".  Sometimes Σ F is written as F net, it means the same thing.  It means you have to add up all the forces acting on an object.  The arrow above "F" reminds you that force is a vector. We won't always write the arrow but remember it's there.  It means that when you add forces, you have to add them like vectors: forces have direction, and they can cancel out.

11  Two forces act on an object. One force is 40N to the west and the other force is 40N to the east. What is the net force acting on the object?  Two forces act on an object. One force is 8.0 N to the north and the other force is 6.0N to the south. What is the net force acting on the object?

12 Newton’s Third Law  Whenever one object exerts a force on a second object, the second object exerts an equal force in the opposite direction on the first object.

13 Drawing Free Body Diagrams  1. Draw and label a dot to represent the first object.  2. Draw an arrow from the dot pointing in the direction of one of the forces that is acting on that object. Label that arrow with the name of the force.  3. Repeat for every force that is acting on the object. Try to draw each of the arrows to roughly the same scale, bigger forces getting bigger arrows.  4. Draw a separate arrow next to your free body diagram indicating the likely direction of the acceleration of the object.

14 Sample Problem  A blimp hovers in the sky.  Draw a free body diagram.  Determine Σ F in the x and y directions

15 Sample Problem  A boy pulls a sled along (with constant velocity) on a string.  Draw a free body diagram.  Determine Σ F in the x and y directions

16 Sample Problem  A man accelerates a crate along a rough surface.  Draw a free body diagram.  Determine Σ F in the x and y directions

17 Kinetic Friction Force  On a microscopic scale, most surfaces are rough. The exact details are not yet known, but the force can be modeled in a simple way.  For kinetic – sliding friction, we write:  μ k is the symbol for kinetic friction, and is different for every pair of surfaces.

18 Static Friction Force  Static friction is the frictional force between two surfaces that are not moving along each other.  Static friction keeps objects from moving when a force is first applied:  μ s is the symbol for static friction, and is different for every pair of surfaces.  The static friction force is greater than or equal to the kinetic friction which is why it is harder to start an object moving than to keep it moving.

19 Sample Question  Two people push the back of a car with an applied force of 2000 N so it accelerates at 2 m/s 2. What is the force of friction between the tires and the road if the car’s mass is 800 kg?

20 Sample Question  Someone pushes a dresser with an applied force of 500 N so it accelerates at 3 m/s 2. What is the coefficient of kinetic friction between the dresser and the floor if the dresser’s mass is 100 kg?

21 Tension  When a cord or rope pulls on an object, it is said to be under tension, and the force it exerts is called a tension force, F T.  A 25 kg lamp is hanging from a rope. What is the tension force being supplied by the rope?

22 Putting It Together  An 1800 kg elevator moves up and down on a cable. Calculate the tension force in the cable for the following cases: a) the elevator moves at a constant speed upward. b) the elevator accelerates upward at a rate of 2.4 m/s 2. c) the elevator accelerates downward at a rate of 2.4 m/s 2. d) the elevator moves at a constant speed downward.

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24  Two blocks, with masses m 1 = 400 g and m 2 = 600 g, are connected by a string and lie on a frictionless tabletop. A force F = 3.5 N is applied to block m 2.  a. Find the acceleration of each object.  b. Find the tension force in the string between two objects.

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26  A 12 kg load hangs from one end of a rope that passes over a small frictionless pulley. A 15 kg counterweight is suspended from the other end of the rope. The system is released from rest. a. Find the acceleration of each mass. b. What is the tension force in the rope?

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29  A 500 g block lies on a horizontal tabletop with negligible friction. The block is connected by string to the second block with a mass of 300 g. The string passes over a light frictionless pulley as shown above. The system is released from rest.  Find the acceleration of the system by simultaneously solving the system of two equations.  What is the tension force in the string?

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32 Hooke’s Law  Robert Hooke observed the relationship between the force necessary to compress a spring and how much the spring was compressed.  F spring = -kx  k represents the spring constant and is measured in N/m.  x represents how much the spring is compressed.  The - sign tells us that this is a restorative force.

33 Sample Problem  What is the spring constant of a hanging spring that has a resting length of 20 cm and stretches to 50 cm when a 100 g mass is put on it?


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