PHYSICS 231 INTRODUCTORY PHYSICS I

Slides:

Advertisements

Similar presentations

Advertisements

Chapter 4 The Laws of Motion.

APC -Unit 2. 2 nd Law A 72kg person stands on a scale which sits on a floor of elevator. It starts to move from rest upward with speed v(t) = 3t +

Applying Newton’s Laws

Newton’s Laws of Motion (Applications)

AP Physics Chapter 5 Force and Motion – I.

Applying Newton’s Laws. A systematic approach for 1 st or 2 nd Law Problems 1.Identify the system to be analyzed. This may be only a part of a more complicated.

Constant Force Motion and the Free Body Diagram Teacher Excellence Workshop June 19, 2009.

Physics 215 – Fall 2014Lecture Welcome back to Physics 215 Today’s agenda: Weight, elevators, and normal forces Static and kinetic friction Tension.

PHYSICS 231 INTRODUCTORY PHYSICS I

Chapter 5 The Laws of Motion.

Chapter 4 Forces and Mass. Classical Mechanics does not apply for very tiny objects (< atomic sizes) objects moving near the speed of light.

PHYSICS 231 INTRODUCTORY PHYSICS I

Chapter 4 Forces and Mass.

Ballistic Cart Demo Discuss law of cosines for planeinwindb problem Other HW problems?

Physics 101: Lecture 9, Pg 1 Physics 101: Application of Newton's Laws l Review of the different types of forces discussed in Chapter 4: Gravitational,

Newton’s 3rd Law of Motion By: Heather Britton. Newton’s 3rd Law of Motion Newton’s 3rd Law of Motion states Whenever one object exerts a force on a second.

Kinds of Forces Lecturer: Professor Stephen T. Thornton

Newton’s Laws of Motion Problems MC Questions

Applications of Newton’s Laws

Newton’s Laws Problems

FORCES. A force is an influence on a system or object which, acting alone, will cause the motion of the system or object to change. If a system or object.

Force Chapter 6. Force Any push or pull exerted on an object.

Classical Mechanics Describes the relationship between the motion of objects in our everyday world and the forces acting on them Conditions when Classical.

Physics 203 – College Physics I Department of Physics – The Citadel Physics 203 College Physics I Fall 2012 S. A. Yost Chapter 4 Newton’s Laws – Part 3.

EVERY-DAY FORCES Force of gravity Normal force Force of friction Universal force of gravity.

Newton’s 3rd law and Friction Lecture 4. Newtons First Law If no net external force is applied to an object, its velocity will remain constant ("inert").

Newton’s Laws of Motion

Newton’s Laws The Study of Dynamics.

Forces and Mass. Classical Mechanics does not apply for very tiny objects (< atomic sizes) objects moving near the speed of light.

Newton’s Laws of Motion

Chapter 4 The Laws of Motion. Classical Mechanics Describes the relationship between the motion of objects in our everyday world and the forces acting.

SECOND LAW OF MOTION If there is a net force acting on an object, the object will have an acceleration and the object’s velocity will change. Newton's.

Chapter 4 Forces and the Laws of Motion. Newton’s First Law An object at rest remains at rest, and an object in motion continues in motion with constant.

Applications of Newton’s Laws of Motion

Chapter 4 Dynamics: Newton’s Laws of Motion

PHYS16 – Lecture 10 & 11 Force and Newton’s Laws September 29 and October 1, 2010

Forces and Free-Body Diagrams

Chapter 4 The Laws of Motion Phy 2053 Conceptual Questions Phy 2053 Conceptual Questions.

Phys 250 Ch4 p1 Force and Motion Some History: The Copernican Revolution with Copernicus, Galileo, Kepler... Newton’s Principia: laws of motion physics.

1 Some application & Forces of Friction. 2 Example: When two objects of unequal mass are hung vertically over a frictionless pulley of negligible mass,

Chapter 4 The Laws of Motion. Classes of Forces Contact forces involve physical contact between two objects Field forces act through empty space No physical.

Force and Motion This week – This week – Force and Motion – Chapter 4 Force and Motion – Chapter 4.

Forces Chapter 4. Forces A push or a pull  Gravitational  Electromagnetic  Weak  Strong.

Force & Newton’s Laws of Motion. FORCE Act of pulling or pushing Act of pulling or pushing Vector quantity that causes an acceleration when unbalanced.

Applications & Examples of Newton’s Laws. Forces are VECTORS!! Newton’s 2 nd Law: ∑F = ma ∑F = VECTOR SUM of all forces on mass m  Need VECTOR addition.

Remember!!!! Force Vocabulary is due tomorrow

Unit 2 1D Vectors & Newton’s Laws of Motion. A. Vectors and Scalars.

1 Applying Newton’s Laws Assumptions Assumptions Objects behave as particles Objects behave as particles can ignore rotational motion (for now) can ignore.

AP Physics C I.B Newton’s Laws of Motion. Note: the net force is the sum of the forces acting on an object, as well as ma.

The tendency of objects to resist change in their state of motion is called inertia  Inertia is measured quantitatively by the object's mass.  Objects.

Force Chapter 6. Force Any push or pull exerted on an object.

Chapter 5 Two Dimensional Forces Equilibrium An object either at rest or moving with a constant velocity is said to be in equilibrium The net force acting.

Chapter 5 The Laws of Motion.

Chapter 4 Dynamics: Aim: How can we describe Newton’s Laws of Motion? © 2014 Pearson Education, Inc.

Physics 215 – Fall 2014Lecture Welcome back to Physics 215 Today’s agenda: More on free-body diagrams and force components Applying Newton’s laws.

Physics Section 4.4 Describe various types of forces Weight is a measure of the gravitational force exerted on an object. It depends upon the objects.

Weight = mass x acceleration due to gravity

Newton’s Third Law If two objects interact, the force exerted by object 1 on object 2 is equal in magnitude and opposite in direction to the force.

PHY 151: Lecture Forces of Friction 5.9 Newton’s Second Law.

Physics Section 4.4 Describe various types of forces Weight is a measure of the gravitational force exerted on an object. It depends upon the objects.

1 Chapter 5 The Laws of Motion. 2 Force Forces are what cause any change in the velocity of an object A force is that which causes an acceleration The.

Raymond A. Serway Chris Vuille Chapter Four The Laws of Motion.

Problems – 1 A ball of mass ____ grams is tossed straight up in the air. Assuming air resistance can be ignored, draw an FBD for the ball on its way up.

The Laws of Motion. Classical Mechanics Describes the relationship between the motion of objects in our everyday world and the forces acting on them Describes.

Physics 111: Mechanics Lecture 5

Two Dimensional Forces

Inclined Planes.

Force Problems.

Presentation transcript:

PHYSICS 231 INTRODUCTORY PHYSICS I Lecture 5

Main points of last lecture Range (yi=yf): Relative velocity: Newton’s Laws: If SF = 0, velocity doesn’t change. vbe = vbr + vre

Newton’s Third Law Force on “1” due to “2” Single isolated force cannot exist For every action there is an equal and opposite reaction Action and Reaction Forces act on different objects

Free-body Diagram Draw arrows for all forces acting ON object If the object is in “equilibrium” (at rest or constant v) Otherwise, find acceleration by Ignore rotational motion for now. Treat object as a particle.

Example 4.1 Two blocks sit on a frictionless table. The masses are M1=2 kg and M2=3 Kg. A horizontal force F=5 N is applied to Block 1. What is the acceleration of the blocks? What is the force of block 1 on block 2? F M2 M1 1. a = 1 m/s2 2. F21= 3 N

Mechanical Forces Gravity: w=mg (down) Normal forces Strings, ropes and Pulleys Friction Springs (later)

Rules for Ropes and Pulleys Force from rope points AWAY from object (Rope can only pull) Magnitude of the force is Tension Tension is same everywhere in the rope Tension does not change when going over pulley Approximations: Neglect mass of rope and pulley, neglect friction in pulley

Example 4.2 I pull a 5 kg mass up with a rope, so that it accelerates 2 m/s2. What is the tension in the rope? T = 59 N

Example 4.3 - Atwood Machine a) Find acceleration b) Find T, the tension in the string c) Find force ceiling must exert on pulley 7 kg 5 kg a) a = g/6 = 1.635 m/s2 b) T = 57.2 N c) Fpulley=2T = 114.5 N

Example 4.4a T1 is _____ T2 cos(10o)=0.985 sin(10o)=0.173 Which statements are correct? Assume the objects are in static equilibrium. T1 is _____ T2 A) Less than B) Equal to C) Greater than cos(10o)=0.985 sin(10o)=0.173

Example 4.4b T2 is ______ T3 cos(10o)=0.985 sin(10o)=0.173 Which statements are correct? Assume the objects are static. T2 is ______ T3 A) Less than B) Equal to C) Greater than cos(10o)=0.985 sin(10o)=0.173

Example 4.4c T3 is ______ Mg cos(10o)=0.985 sin(10o)=0.173 Which statements are correct? Assume the objects are static. T3 is ______ Mg A) Less than B) Equal to C) Greater than cos(10o)=0.985 sin(10o)=0.173

Example 4.4d T1+T2 is ______ Mg cos(10o)=0.985 sin(10o)=0.173 Which statements are correct? Assume the objects are static. T1+T2 is ______ Mg A) Less than B) Equal to C) Greater than cos(10o)=0.985 sin(10o)=0.173

Example 4.4 Given that Mlight = 25 kg, find all three tensions T3 = 245.3 N, T1 = 147.4 N, T2 = 195.7 N

Cable Pull Demo

Inclined Planes Choose x along the incline and y perpendicular to incline Replace force of gravity with its components 30.0

Example 4.5 Find the acceleration and the tension a = 4.43 m/s2, T= 53.7 N

Example 4.6 M Find M such that the box slides at constant v M=15.6 kg

Frictional Forces RESISTIVE force between object and neighbors or the medium Examples: Sliding a box Air resistance Rolling resistance

Sliding Friction Parallel to surface, opposing direction of motion ~ independent of the area of contact Depends on the surfaces in contact Object at rest: Static friction Object in motion: Kinetic friction

f F Static Friction, ƒs Just enough force to keep object at rest. ms is coefficient of static friction N is the normal force f F

f F Kinetic Friction, ƒk mk is coefficient of kinetic friction Friction force opposes direction of motion N is the normal force F

Coefficients of Friction

Example 4.7 The man pushes/pulls with a force of 200 N. The child and sled combo has a mass of 30 kg and the coefficient of kinetic friction is 0.15. For each case: What is the frictional force opposing his efforts? What is the acceleration of the child? f=59 N, a=3.80 m/s2 / f=29.1 N, a=4.8 m/s2

Example 4.8 a) ms = 0.5 b) a=1.96 m/s2 c) 39.25 N Given m1 = 10 kg and m2 = 5 kg: a) What value of ms would stop the block from sliding? b) If the box is sliding and mk = 0.2, what is the acceleration? c) What is the tension of the rope? a) ms = 0.5 b) a=1.96 m/s2 c) 39.25 N

Example 4.9 What is the minimum ms required to prevent a sled from slipping down a hill of slope 30 degrees? ms = 0.577

Other kinds of friction Air resistance, F ~ Area  v2 Rolling resistance, F ~ v Terminal velocity:

Coffee Filter Demo

Example 4.9 An elevator falls with acceleration a = 8.0 m/s2. If a 200-lb person stood on a bathroom scale during the fall, what would the scale read? 36.9 lbs

Accelerating Reference Frames Equivalent to “Fictitious” gravitational force

Fictitious Force: Derivation Eq. of motion in fixed frame F-maf looks like force in new frame, maf acts like fake gravitational force!

Example 4.10 You are calibrating an accelerometer so that you can measure the steady horizontal acceleration of a car by measuring the angle a ball swings backwards. If M = 2.5 kg and the acceleration, a = 3.0 m/s2: a) At what angle does the ball swing backwards? b) What is the tension in the string? q q = 17 deg T= 25.6 N

Example 4.11a A fisherman catches a 20 lb trout (mass=9.072 kg), and takes the trout in an elevator to the 78th floor to impress his girl friend, who is the CEO of a large accounting firm. The fish is hanging on a scale, which reads 20 lb.s while the fisherman is stationary. Later, he returns via the elevator to the ground floor with the fish still hanging from the scale. In the instant just after the elevator begins to move upward, the reading on the scale will be ______________ 20 lbs. Greater than Less than Equal to

Example 4.11b A fisherman catches a 20 lb trout (mass=9.072 kg), and takes the trout in an elevator to the 78th floor to impress his girl friend, who is the CEO of a large accounting firm. The fish is hanging on a scale, which reads 20 lb.s while the fisherman is stationary. Later, he returns via the elevator to the ground floor with the fish still hanging from the scale. On the way back down, while descending at constant velocity, the reading on the scale will be ________________ 20 lbs. Greater than Less than Equal to

Example 4.11c A fisherman catches a 20 lb trout (mass=9.072 kg), and takes the trout in an elevator to the 78th floor to impress his girl friend, who is the CEO of a large accounting firm. The fish is hanging on a scale, which reads 20 lb.s while the fisherman is stationary. Later, he returns via the elevator to the ground floor with the fish still hanging from the scale. In the instant just before the elevator comes to a stop on the 78th floor, the mass of the fish will be ______________ 9.072 kg. Greater than Less than Equal to