I NCLINED P LANES I LOVE these!. W HAT E XACTLY WILL WE BE LOOKING AT ? Visualize an object placed on a ramp. In physics we refer to the ramp as an “

Slides:



Advertisements
Similar presentations
Normal Force Force on an object perpendicular to the surface (Fn)
Advertisements

Newton’s Second Law The net force on a body is equal to the product of the body’s mass and its acceleration.
Make a sketch Problem: A 10.0 kg box is pulled along a horizontal surface by a rope that makes a 30.0 o angle with the horizontal. The tension in the rope.
Net Force Problems There are 2 basic types of net force problems
Forces applied at an Angle & Inclined Planes
Forces and the Laws of MotionSection 4 Click below to watch the Visual Concept. Visual Concept Everyday Forces.
Inclined Planes Lecture and Lab!!. Inclined Planes and Gravitational Force To analyze the forces acting on an object on an inclined plane (a tilted surface),
Constant Force Motion and the Free Body Diagram Teacher Excellence Workshop June 19, 2009.
Newton’s 2nd Law some examples
Chapter 4- Forces and Motion
Department of Physics and Applied Physics , F2010, Lecture 7 Physics I LECTURE 7 9/27/10.
Forces and The Laws of Motion
Inclined Plane Problems
Dynamics – Ramps and Inclines
Newton’s Laws - continued
Chapter 4 Preview Objectives Force Force Diagrams
CBA #1 Review Graphing Motion 1-D Kinematics
Lesson #33 Topic: Lesson #33 Topic: Net force in two dimensions Objectives: (After this class I will be able to) 1.Examine Normal force and observe different.
Chapter 4 Changes in Motion Objectives
Quiz 4.
Newton’s Laws The Study of Dynamics.
Review for Dynamics test Page 1Page 1 - Net force with weight Page 2Page 2 - Friction on a level surface Page 3 Page 3 - Inclined Plane Page 4 Page 4.
Review for Dynamics test Page 1Page 1 - Net force with weight Page 2Page 2 - Friction on a level surface Page 3 Page 3 - Inclined Plane Page 4 Page 4.
Newton’s Laws - continued Friction, Inclined Planes, N3L, Law of Gravitation.
Vectors and Linear Motion. Vector Quantities: Have a magnitude And direction ex: meters, velocity, acceleration Scalar Quantities: Have only a magnitude.
Forces and Free Body Diagrams. Common Forces Gravity- attractive force between two objects that have mass. AKA Weight To calculate Weight: –Force of Gravity.
Resolving the gravitational forces on an inclined plane
Newton 2nd Law problems - Atwood Machines -Incline Planes -Tension Problems -Other Object Connected problems.
Forces Summarizing a few things we know…. From the Bowling Ball activities we have evidence that… Forces are responsible for changes in motion – F same.
Force Diagrams And Types of Forces. Review Force = push or pull. Measured in Newtons. –1 lb = 4.45 N F net = ma a = F net / m Big force = big acceleration.
Bellwork Pick up a free-body diagram sheet and begin working on it.
Friction Friction Problem Situations. Friction Friction F f is a force that resists motion Friction involves objects in contact with each other. Friction.
Inclined Planes. An inclined plane is a type of simple machine An inclined plane is a large and flat object that is tilted so that one end is higher than.
Unit 2 Notes. Free Body Diagrams Show an object and the forces acting on it The object is represented by a circle (you can write the object’s name inside.
Friction. Biblical Reference And they pulled him up with the ropes and lifted him out of the cistern. Jeremiah 38:13.
Forces and the Laws of Motion
Resolving Forces Into Vector Components Physics Montwood High School R
Box slides along horizontal at velocity constant. FfFf FpFp FwFw v c therefore,  F = 0 ; F p + F f = 0 ; F F = -F p Rest, therefore,  F = 0 ; F W +
Forces on an incline. The Gravitational force FgFg FgFg FgFg FgFg FgFg FgFg The gravitational force on an object always points straight down and maintains.
4.8 Friction and inclines.
© Houghton Mifflin Harcourt Publishing Company Preview Objectives Force Force Diagrams Chapter 4 Section 1 Changes in Motion.
Objects on Inclined Planes I guess you could call them ramps if you want.
 With a large perpendicular force and a small parallel force, the tendency to slide is very small. An example of this would be a 15 degree slope. The.
Lesson 4.4 Everyday Forces Essential Question: What are some of the everyday forces?
Applications of Newton’s Laws Physics 11. Numerous Applications Apparent weight Free fall Inclined planes Atwood’s machines Universal Law of Gravitation.
Practice with Inclined Planes
Physics Chapter 7 Forces and Motion in Two Dimensions.
Weight = mass x acceleration due to gravity
“ Friendship is like peeing on yourself; everyone can see it, but only you get the warm feeling it brings.” Funnyquotes.com Course web page
Three blocks of masses M 1 =2 kg, M 2 =4 kg, and M 3 =6 kg are connected by strings on a frictionless inclined plane of 60 o, as shown in the figure below.
Inclined Plane Problems. Axes for Inclined Planes X axis is parallel to the inclined plane Y axis is perpendicular to the inclined plane Friction force.
4-8 Applications Involving Friction, Inclines
The “Spring Force” If an object is attached to a spring and then pulled or pushed, the spring will exert a force that is proportional to the displacement.
FRICTION and Newton’s second law. The “Normal” Force, N When an object is pressed against a surface, the surface pushes back. (That’s Newton’s 3 rd Law)
Review problems Mechanics Revision. A parcel of mass 3kg is released from rest at the top of a straight chute which is fixed at a 40 o angle to the horizontal.
Inclined Plane Problems
Dynamics of a Particle moving in a Straight Line
Aim: How do we explain motion along an inclined plane?
1. A ball of mass m is suspended from two strings of unequal length as shown above. The magnitudes of the tensions T1 and T2 in the strings must satisfy.
Dyanmics Normal Force and Inclines
Aim: How do we explain motion along an inclined plane?
Motion on Inclined Planes
Aim: How do we explain motion along an inclined plane?
Inclined Planes .
Warm-up What forces were acting on your rocket when it was moving up into the air? What forces were acting on your rocket when it was coming back down.
________________: Find the acceleration of a block of mass m on a ______________ ramp that makes an angle q with the horizontal. Inclined Plane frictionless.
Forces applied at an Angle & Inclined Planes
Free Body Diagrams and Types of Forces
Forces The unedited story.
Gravitational Force and Inclined Planes
Presentation transcript:

I NCLINED P LANES I LOVE these!

W HAT E XACTLY WILL WE BE LOOKING AT ? Visualize an object placed on a ramp. In physics we refer to the ramp as an “ inclined plane.” o We are still NEGLECTING friction so, if you put an object on an incline…what will it do? o Yup! It will slide down the incline. But, WHY will it slide down the incline?

WHY WILL IT SLIDE DOWN THE INCLINE ? Seems simple… It moves downhill because of gravity. If there is no friction (to resist the motion), then gravity is “allowed” to accelerate it down the incline. The force of gravity IS why it is pulled downhill…but there is more to it. o What is the direction of the gravitational force on the box?

L OOK AT THE D IRECTION OF G RAVITY … The force of gravity (i.e. weight) ALWAYS acts directly down (toward the center of Earth). Hang on…the box doesn’t move straight down – it moves down the hill. The concept of net force (F net ) indicates that there must be a force acting parallel to the motion, that causes it to accelerate down the incline. o What is this parallel force? F g = mg motion

W HAT IS THIS PARALLEL FORCE ? Let’s say that the incline makes an angle of  with the ground. The box pushes down on the incline and the incline pushes back on the box. The support force that the incline supplies to the box is the normal force. Remember that the normal force is always perpendicular to the surface. o We will use the normal force to lay out the rest of the picture. F g = mg motion  FNFN Do NOT draw the normal force vertically upward…it must be perpendicular to the surface!

L ET THE NORMAL FORCE HELP YOU … Extend the normal force in the opposite direction. This force is the component of the weight that is perpendicular to the surface. o This still isn’t parallel to the motion…but we’re getting there... F g = mg motion  FNFN FF

W HAT IS THE FORCE DOWN THE HILL ? Draw a line PARALLEL to the incline This force is the component of the weight that is parallel to the surface. The “parallel force” is what causes the pull down the hill! o We use F p to find F net … o So how do we find F p ? F g = mg motion  FNFN FpFp FF

F OCUS ON THE TRIANGLES. Notice that the inclined plane itself is a right triangle. Notice that the triangle made up of F , F p and mg is also a right triangle. These two triangles are similar triangles. o How does it help us that these two triangles are similar? F g = mg motion  FNFN FpFp FF

H OW DOES IT HELP US THAT THESE TWO TRIANGLES ARE SIMILAR ? The base angle of the inclined plane (  ) is the same as the angle between F  and mg. You also want to pay attention to where the right angle is. o You now have the picture you need to analyze the situation. F g = mg motion  FNFN FpFp FF 

W HAT DO WE DO NOW ? Let’s do a problem! A block is released (from rest) from the top of an incline that makes an angle of 30  with the ground. Neglecting friction, what is the acceleration of the block down the incline? F g = mg motion 30 FNFN o Visualize the forces acting on the box as well as the direction of the acceleration.

W HAT DO WE DO NOW ? If the block is going to move down the incline there must be a force directed PARALLEL to that motion. We now know that we need to break the weight (mg) up into parallel and perpendicular components. F g = mg motion 30 FNFN F  = mgcos30  F p = mgsin30  30 o The parallel component (F p = mgsin30  ) is (part of) the net force.

W HAT DO WE DO NOW ? F net = ma The net force includes all forces (or components of forces that are parallel to the motion) F p = ma mgsin30  = ma To solve for the acceleration divide both sides by mass. mgsin30  = a m gsin30  = a (9.8)sin30  = a = 4.9m/s 2 F g = mg motion 30 FNFN F  = mgcos30  F p = mgsin30  30 That’s it… … KNOW HOW TO SET UP THE DIAGRAM! … UNDERSTAND HOW TO WORK WITH F net !

W HAT IF WE PUSH THE BOX ? A 5-kg block is pushed up an incline via a force of 30N as shown. If the incline makes an angle of 30  with the ground and friction is neglected, what is the acceleration of the block? motion 30 o Visualize the forces acting on the box as well as the direction of the acceleration. F = 30N

W HAT IF WE PUSH THE BOX ? Don’t forget about the weight (straight down) and the normal force (perpendicular to the surface and upward). Don’t forget to break the weight (i.e. force of gravity) into components that are parallel to and perpendicular to the incline. motion 30 o Now you are ready. F = 30N F g = mg FNFN F  = mgcos30  F p = mgsin30 

W HAT IF WE PUSH THE BOX ? F net = ma The net force includes all forces (or components of forces that are parallel to the motion) F - F p = ma F is positive b/c it is in the same direction as the motion and F p is negative b/c it is in the opposite direction of the motion. F - mgsin30  = ma To solve for the acceleration divide both sides by mass. F - mgsin30  = a m 30 – (5)(9.8)sin 30  = a = 1.1m/s 2 5 F p = mgsin30  motion 30 F = 30N F g = mg FNFN F  = mgcos30  That’s it… … KNOW HOW TO SET UP THE DIAGRAM! … UNDERSTAND HOW TO WORK WITH F net !

G OT IT ? Try it on your own… …BUT… …remember you have lots of support. 1) We will do this in class together. 2) Use Mrs. McGrath’s pencast for help 3) See the notes on the back of handout 4-5 for help 4) ASK QUESTIONS!