TODAY and TOMORROW 1) Video about RAMPS is important

Slides:

Advertisements

Similar presentations

Forces at Angles. Recall: In this case the Applied Force is horizontal only If the F=Ff, it means the object is either at rest or moving at a constant.

Advertisements

Forces applied at an Angle & Inclined Planes

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 “

Force Free-body Diagrams 1 Steps to Solving the Problem Drawings Calculations.

10/1 Friction  Text: Chapter 4 section 9  HW 9/30 “Block on a Ramp” due Friday 10/4  Suggested Problems: Ch 4: 56, 58, 60, 74, 75, 76, 79, 102  Talk.

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.

TODAY AND TOMORROW 1) New video up you need to watch/note 2) Some brief reminders of ramps, then new with ramps/pulleys 3) We spend time at the boards.

Unit 2 Lesson 2. Bellringer…Tuesday (new bellringer page) Write an equation of a line parallel to 4x + 2y = 8 and through (-3, 1)

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.

Friction Ffriction = μFNormal.

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.

Forces on Inclined Planes Unit 3, Presentation 3.

Resolving Forces Into Vector Components Physics Montwood High School R

Objects on Inclined Planes I guess you could call them ramps if you want.

Physics 11 Dynamics 14 – Inclined Planes Mr. Jean.

 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.

DAY 25 LETS GO! TODAY AT A GLANCE: 1) You try a math example and learn about pulleys. 2) We look at pulleys in a different way. 3) LOTS of learning/graphing.

9/30 Friction  Text: Chapter 4 section 9  HW 9/30 “Skier” due Thursday 10/3  Suggested Problems: Ch 4: 56, 58, 60, 74, 75, 76, 79, 102  Talk about.

Poll The angle of the hill is 30 . If the ball is moving up the hill, what is its acceleration, if the +x direction is defined to be “to the right, down.

4-8 Applications Involving Friction, Inclines

 A system can consist of one or more objects that affect each other.  Often, these objects are connected or in contact.

Chapter 4 Equilibrium Equilibrium Under the Action of Concurrent Forces.

How do you start the rotation of an object? How do you open an door? What did we learn about the best way to open a door? The most efficient way to open.

11/12 do now – on a new sheet Sketch a set of graphs that relate the variables shown on the axes for an object that is thrown off a building horizontally.

Angled Work Physics.

Newton’s third law of motion 1 Force 2

Inclined Planes, Tension, & Multiple Objects Clicker Review

Physics 11 Advanced Mr. Jean April 11th, 2012.

on an inclined surface. The surface makes 30⁰ angle with horizon.

Acceleration of a Single Body Sliding Down an Incline

V = 20 m/s magnitude of the velocity vector.

Inclined Planes  Introduction Components Normal Force

A mosquito collides head on with a car traveling 60 mph

Journal 9/22/16 Objective Tonight’s Homework

Copyright © John O’Connor For non-commercial purposes only….. Enjoy!

TODAY Today's Goal: 1) Lab In! 2) Finalize our understanding of ramps and FORCES. Homework: Given out. To make sure we can understand impulse through graphs.

A child of mass m rides on a sled down a slick, ice-covered hill inclined at an angle θ with respect to the horizontal. Draw a sketch Draw a free body.

Homework Class Example Variations Weekend homework

DAY 19 LETS GO! THE END OF THE QUARTER Topic 3 Forces continues

Refresher: *Acceleration is only caused by an unbalanced net force acting on an object. F = ma F = F1 + F2 + … *The weight of an object is referred to.

DAY 25 LETS GO! TODAY AT A GLANCE:

Key Areas covered Resolving the weight of an object on a slope into a component acting down the slope and a component acting normal to the slope. Systems.

Aim: How does friction affect an objects motion?

Weight Components on a Ramp

Two Dimensional Forces

Inclined Planes.

Exam#1 (chapter 1-6) time: Tuesday 02/19 8:00 pm- 10:00 pm

7.3 Forces in Two Dimensions

Find The Net Force on These

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.

SECTION 5.3 FORCE AND MOTION IN 2 DIMENSIONS

Aim: How do we explain motion along an inclined plane?

Physics 1 – Nov 15, 2016 P3 Challenge –

Motion on Inclined Planes

Key Areas covered Resolving the weight of an object on a slope into a component acting down the slope and a component acting normal to the slope. Systems.

Activating Prior Knowledge-

Geometry Section 3.5.

Aim: How do we explain motion along an inclined plane?

Inclined Planes .

TODAY Today's Goal: 1) New topic: Impulse and Momentum. Lets start learning about Impulse 2) Apply our idea to collisions through graphs. Homework: Given.

The Normal Force The normal force is a force that opposes the Earth’s gravitational attraction and is perpendicular to the surface that an object rests.

In practice we are given an angle (generally from the horizontal or vertical) and we use trigonometry 20N 20 sin 300N cos 300N.

Forces applied at an Angle & Inclined Planes

Exam#1 (chapter 1-8) time: Wednesday 03/06 8:30 am- 9:20 am

Force Problems.

Consider an object on an inclined plane:

Vectors and Scalars.

Gravitational Force and Inclined Planes

Friction Equilibrium.

Presentation transcript:

TODAY and TOMORROW 1) Video about RAMPS is important 2) Lab: for next class 3) Quiz next class: 4 questions on all kinds of force stuff

Discuss how to write/submit lab (See last class notes) Part 2/3 Discuss how to write/submit lab (See last class notes)

What you will be submitting For Each Part: Overall -A picture of the setup. -What you did to find the goal (your process, equipment used) -The graph of what you are supposed to find -The actual result of the relationship -An explanation on WHY the result happened (i.e. the physics on why the relationship is the way it is) -On a paper, each part has its own section -All group member names -Each section is clearly labeled -The analysis questions -A lab name that will make me smile/laugh/chortle as I read them

Block is in contact with 1 thing. With friction, that makes 2 forces. Plus 1 non-contact force. But…it will accelerate down the ramp. Lets draw the forces

The idea The friction and normal force are not in X or Y. But the block will also not accelerate in X or Y. So we will create a NEW frame of reference to make the physics easier. Downhill/Uphill is X, Perpendicular to ramp is Y So the weight is now not in the new X or Y, need to find its X and Y components

1) Lets draw in the parallel and perpendicular parts of the weight 2) The two angles are the same due to geometry Weight perpendicular to ramp (Y) 3) Using Sin and Cos we can find the X and Y parts of the weight MgCos (θ) Ramp angle Weight parallel to ramp (X) Weight MgSin (θ) θ

Normal Force 4) Draw the forces now on the block in X and Y Friction if moving downhill 5) Depending on the way the block is moving, draw friction Weight perpendicular to ramp (Y) Friction if moving uphill MgCos (θ) Weight parallel to ramp (X) MgSin (θ)

RAMP REVIEW Instead of X and Y, we are going to rotate to a ‘New X’ and ‘New Y’: ‘New X’ : Down/Uphill ‘New Y’ : Perpendicular to the hill Weight in X is the SIN of the weight. Weight in Y (perpendicular to ramp) is the COS of the weight

Lets create Net Force Equations and solve for the acceleration! Moving downhill:

Lets create Net Force Equations and solve for the acceleration! Moving Downhill

Lets create Net Force Equations and solve for the acceleration! Moving uphill:

Lets create Net Force Equations and solve for the acceleration! Moving uphill: