WHAT IS THE EFFECT OF AIR RESISTANCE ON A FALLING OBJECT? BY: SAM HATALA F AIR RESISTANCE mg.

Slides:

Advertisements

Similar presentations

Potential Energy Work Kinetic Energy.

Advertisements

ConcepTest Clicker Questions

© 2005 Pearson Prentice Hall This work is protected by United States copyright laws and is provided solely for the use of instructors in teaching their.

An object is released from rest on a planet that

ENERGY TRANSFORMATION. ● The Law of Conservation of Energy states that energy cannot be created nor destroyed. ● Energy can be transformed from one form.

Fall Final Review WKS: WORD PROBLEMS Part II. 1. A car travels at a constant speed of 15 m/s for 10 seconds. How far did it go?

Warm-up  How much force would be needed to move a dog that is 65kg at an acceleration of 2 m/s 2 ? (Find the weight!)  Find the Weight for the following:

Fall Final Review WKS: WORD PROBLEMS. Average Speed 1. A rock is dropped from the top of a tall cliff 9 meters above the ground. The ball falls freely.

. They all fall at the same rate!  Air Resistance o Force in the opposite direction of the motion of an object through air o Also called drag o Can.

Studying the Force of Gravity

Motion of mass on a parachute  Falling objects increase their speed as they fall.  This is due to their weight (the force of gravity) that pulls them.

It takes work to lift a mass against the pull (force) of gravity The force of gravity is m·g, where m is the mass, and g is the gravitational acceleration.

 Calculate the acceleration that this object experiences 30 kg 150 N.

Chapter 7: Work and Energy (Ewen et al. 2005) Objectives: Related kinetic and potential energy to the law of conservation of mechanical energy. Related.

Section 6.2 Using Newton’s Laws

Thursday, October 11 Journal: Define gravity and inertia. Schedule: Gravity Notes Gravity Video Homework: None.

Integrated Science Unit 1, Chapter 3.

Chapter 3 Forces.

Unit 07 “Work, Power, Energy and Energy Conservation” Lab Predicting the Final Velocity of a Car Using the Conservation of Mechanical Energy.

Energy and Conservation Physics Chapter 5-2 (p ) Chapter 5-3 (p )

ENERGY The measure of the ability to do work Conservation of energy -energy can change forms but can not be destroyed -the total amount of energy in the.

Physics 3.3. Work WWWWork is defined as Force in the direction of motion x the distance moved. WWWWork is also defined as the change in total.

Unit 2 Lesson 2 Kinetic and Potential Energy

Work and Energy.

THE LANGUAGE OF PHYSICS. ACCELERATION= a a= (v f -v i )/t v f - final velocity, v i - initial velocity UNITS ARE m/s 2 CONSTANT a NEGATIVE a POSITIVE.

Chapter 2 Sir Isaac Newton’s Three Laws of Motion.

Gravity Gravity is the force that pulls objects toward the center of the earth.

Goal: To projectile motions Objectives: 1)To understand freefall motions in 1 D 2)To understand freefall motions in 2D 3)To understand air drag and terminal.

Projectile - an object for which the only force acting upon it is gravity. The force of air resistance is negligibly small or nonexistent for a projectile.

Chapter 2.2 Objectives and Vocabulary acceleration deceleration Newton's second law Define and calculate acceleration. Explain the relationship between.

What factor does the final velocity of the car change by if the height is doubled? STARTER #2.

Conservation of Mechanical Energy Mechanical Energy – The sum of Potential and Kinetic Energies ME=PE+KE The conservation of mechanical energy states that.

Energy 1. Work 2. Kinetic Energy 3. Work-Energy Principle 4. Friction 5. Potential Energy 6. Conservation of Energy ©2013 Robert Chuckrow.

Work and Energy 5. What is a force? a. change in speed over time b. the tendency to resist change in motion c. a push or pull d. apparent weightlessness.

Everyone grab a small whiteboard and a dry erase marker.

Section 15.1Energy and Its Forms

Section 6-3 Gravitational Potential Energy. Warm-Up #1 A sailboat is moving at a constant velocity. Is work being done by a net external force acting.

Unit 1, Chapter 3 Integrated Science. Unit One: Forces and Motion 3.1 Force, Mass and Acceleration 3.2 Weight, Gravity and Friction 3.3 Equilibrium, Action.

STORED ENERGY Wood is stored chemical energy until it is burned and the potential energy is released. A ball held above the ground has potential energy.

Gravitational Force  Gravity= a force of attraction between objects, “pulls” objects toward each other  Law of universal gravitation= all objects in.

examples that align with this definition of work?

Unit 2 Lesson 2 Kinetic and Potential Energy

Forces Chapter 3.

Gravity Key Concepts What factors affect the gravitational force between two objects? Why do objects accelerate during freefall?

Chapter 5.2 Notes Potential Energy.

NEWTON’S 2nd LAW.

Unit 2 Lesson 2 Kinetic and Potential Energy

Work and Energy.

Gravity & Laws of motion

Terminal Velocity.

Unit 2 Lesson 2 Kinetic and Potential Energy

SSA Review - 9 Forces & Motion

Emma Taila & Nicolas Petruzzelli

Unit 2 Force & Motion Ch 6 Sec 4 Gravity.

FCAT Review - 9 Forces & Motion

Key Terms to use in assessment

Projectile Motion Projectile - an object for which the only force acting upon it is gravity. The force of air resistance is negligibly small or nonexistent.

Force and Motion Vocabulary

By Bryan Tran and Cooper Schultz

Work and Energy.

Energy comes in many forms: mechanical, electrical , magnetic, solar,

Some definitions: Weight vs mass

LAW OF FALLING BODIES.

Gravity Key Concepts What factors affect the gravitational force between two objects? Why do objects accelerate during freefall?

Kinetic and Potential Energy

Force and Motion Vocabulary

Free fall and Air Resistance

Gravity and Freefall.

Pre Assessment Discussion

Presentation transcript:

WHAT IS THE EFFECT OF AIR RESISTANCE ON A FALLING OBJECT? BY: SAM HATALA F AIR RESISTANCE mg

EXPERIMENT BACKGROUND The experiment I have conducted investigates the application of Newton’s Second Law to a foam ball dropped through the air from a predetermined height. Newton’s Second Law states that in the presence of unequal force, an object will accelerate and, therefore, its speed, direction or both will change. In this case, the opposing forces acting on the ball, gravity and air resistance, fight to control the behavior of the ball. Gravity works to pull the ball to the ground while air resistance, commonly called the drag force, works to resist the downward pull of gravity. As the ball falls through the air, its velocity will increase until the drag force equals the force of gravity. This state of equilibrium is known as terminal velocity. The purpose of this experiment is to analyze the relationship between the force of gravity on the foam ball as it falls through the air and its terminal velocity, which is affected by the presence of air resistance. I will also assess the relationship between the kinetic energy of the actual ball drop and a theoretical ball drop.

EXPERIMENT PROCEDURE Using the Verniar Lab Quest 2 System and the Verniar Motion Detector, I was able to measure the velocity, acceleration, position, and time of descent of a foam ball. The motion detector was set on top of a desk.83m tall, so that the end of the sensor stuck out from the end of the desk. The ball was then dropped from a position.17m under the sensor. The data was collected and then recorded. I created graphs of my data in Excel, which allowed me to formulate a better analysis. Next, I solved for the theoretical velocity of the ball, using conservation of energy, and compared it with the actual velocities recorded. After that, I found the difference in kinetic energy values for the actual ball drop and the theoretical ball drop, using the actual velocities and theoretical velocities I had solved for earlier, and graphed this data.

EXPERIMENT ILLUSTRATION Desk Sensor

HYPOTHESIS Air resistance will have a negligible effect on the ball’s change in velocity, because the ball’s velocity will not be great enough to create a significant resistance force, from the height at which the ball is released.

RECORDED DATA Time (s)Position (m)Veloc. (m/s)Theo. Veloc.Accel. (m/s²)KE actual*KE theor.* *times mass

DATA ANALYSIS PE = KE KE = ½mv² mgh = ½mv² = (.5v²)m 2gh = v² v = √(2gh) Position (m)Veloc. (m/s)Theo. Veloc KE actualKE theor

Actual Theoretical

HYPOTHESIS Air resistance will have a negligible effect on the ball’s change in velocity, because the ball’s velocity will not be great enough to create a significant resistance force, from the height at which the ball is released.

CONCLUSION Through the process of performing my experiment and analyzing my recorded data, I have demonstrated that my hypothesis is accurate, in suggesting that the height of the ball drop is insufficient to allow the full extent of air resistance to be realized. If dropped from a greater height, the ball would achieve a higher velocity and air resistance would, likewise, be greater. However, I also proved that even over a relatively small distance of less than one meter, air resistance does have an effect on the velocity of the downward fall, forcing it toward a constant value, as acceleration approaches zero.