II. The Simple Machines (p )

Slides:

Advertisements

Similar presentations

Simple Machines.

Advertisements

Machines - Ch. 9 I. Introduction to Machines Machines Force Work Mechanical Advantage.

Simple Machines Unit 2.

5.3 Simple Machines.

Simple Machines Chapter 7-Part 2.

Chapter 5 Lesson 3.

Simple Machines.

Unit 3 Work, Power, and Machines

Types of Simple Machines

CHAPTER 8 MACHINES.

Simple machines and mechanisms Lesson 5.0 and 5.1 Pages

Chapter 5 Math Review. Work  Conservation of Energy can never get more work out than you put in trade-off between force and distance W in = W out F e.

Simple Machines The six types of simple machines are:

Machines - Ch. 7 II. The Simple Machines (Chapter 8)  Introduction to Machines  Mechanical Advantage  Lever  Pulley  Wheel & Axle.

Lesson 2: Simple Machines

Simple Machines & Mechanical Advantage RHS Technology Education.

Work and Machines Chapter 5 Sec 2. What is a Machine?  Any device that makes work easier.

Section 2 Simple Machines.

CONSTRUCTIVE THOUGHTS Simple Machines 7.2. Six Types of Simple Machines leverpulley wheel and axle inclined plane screwwedge.

5.3 Simple Machines. 6 Types  Lever Pulley Wheel and axle  Inclined Plane Screw Wedge.

MachinesMachines Machines  Machines  Force  Work  Power  Mechanical Advantage  Ideal Machines  6 Simple Machines  Efficiency.

Work and Machines Chap 5. Work 5.1 What is Work?  Work transfer of energy that occurs when a force makes an object move W = Fd W:work (J) F:force (N)

MachinesMachines Machines  Machines  Force  Work  Power  Mechanical Advantage  Ideal Machines  6 Simple Machines  Efficiency.

6.3 – Simple Machines Guided notes.

Simple Machines.

Simple Machines 5.3 Physical Science.

Unit 3 Work, Power, and Machines

Ch. 6 Work and Machines.

Simple Machines There are 6 types of simple machines: the inclined plane, the wedge, the screw, the lever, the pulley, and the wheel and axle.

Lever A lever is a bar that is free to turn, about a fixed point.

P. Sci. Unit 3 Work, Power, and Machines SPS8: Students will determine relationships among force, mass, and motion. SPS8.e: Calculate amounts of work and.

Physical Science Chapter 12.  devices that change the direction of a force or the size of a force that help us to do work  machines will multiply your.

Classification of simple machines: Simple machines are divided into two families: 1)The Lever family and 2) The inclined plane family.

Wedge Inclined Plane Screw Wheel and Axle Lever Pulley.

Chapter 14 Lesson 4 The Simple Machine.

Section 4 Simple Machines.

Machine- a device that makes work easier by changing the direction or size of the force.

Chapter 5: Machines II. The Simple Machines Inclined Plane Lever Screw

Machines and Mechanical Advantage Archimedes (Greek mathematician, 287 to 212 B.C.) said, “Give me a place to stand and I will move the Earth,” meaning.

Work and Simple Machines. Work When a force causes an object to move – work is done. When a force causes an object to move – work is done.

Simple Machines. Types of Simple Machines How do machines make work easier? Machines make work easier by: multiplying the size of the force you exert.

Work & Machines. Work  Work transfer of energy through motion force exerted through a __________ W = Fd Distance must be in direction of ______! W:work.

Machines and Mechanical Advantage Archimedes (Greek mathematician, 287 to 212 B.C.) said, “Give me a place to stand and I will move the Earth,” meaning.

Physical Science Chapter 5 Work and Machines 1 Note to self: Find videos.

6.3 – Simple Machines.

Simple Machines Foldable

Machines, Mechanical Advantage, and Efficiency. Ideal Machines In an ideal machine, work going in is equal to the work going out, this means it has 100%

Review of Chapter 4 Book “M”. Section 1 What is work? Work is done on an object when the object moves in the same direction in which the force is exerted.

14.4 Simple Machines. The 6 Simple Machines Lever Wheel and Axle Inclined Plane Wedge Screw Pulley.

Simple Machines Chapter 5 Section 3.

Work and Machines Chapter 5. What machines do you use in your life to help you do some type of work?

Physical Chapter Seven Simple Machines Levers Pulleys Inclined Planes Screws Wheel & Axle Wedge Compound Machines.

Simple Machines W O R K M e c h a n i c a l A d v a n t a g e Force Effort E f f i c i e n c y 1.

Chapter 7 Review.

Simple Machines, Mechanical Advantage, and Work. Machines  Machines make work easier by changing direction of a force, multiplying a force, or increasing.

Topic: Simple Machines PSSA: C / S8.C.3.1. Objective: TLW compare different types of simple machines. TLW compare different types of simple machines.

Types of Machines Levers Simple machine that has a bar that pivots at a fixed point This fixed point is called the fulcrum The load Input force 3 Types.

Simple Machines A simple machine is a device that can multiply a force or change the direction of a force.

Work & Machines.

II. The Simple Machines (p )

Machines The Simple Machines Lever Pulley Wheel & Axle Inclined Plane

Chapter 6 – Work and Machines

Machines - Ch. 12 Introduction to Machines Work, Power, Energy

Chapter 5 Lesson 3.

Chapter 5, Section 3 Notes Simple Machines.

II. The Simple Machines (p )

Presentation transcript:

II. The Simple Machines (p.180-183) Machines - Ch. 7 II. The Simple Machines (p.180-183) Lever Pulley Wheel & Axle Inclined Plane Screw Wedge

A. Lever Lever a bar that is free to pivot about a fixed point, or fulcrum “Give me a place to stand and I will move the Earth.” – Archimedes Engraving from Mechanics Magazine, London, 1824 Resistance arm Effort arm Fulcrum

A. Lever Le must be greater than Lr in order to multiply the force. Ideal Mechanical Advantage (IMA) frictionless machine Effort arm length Resistance arm length Le must be greater than Lr in order to multiply the force.

A. Lever First Class Lever can increase force, distance, or neither changes direction of force

A. Lever Second Class Lever always increases force

A. Lever Third Class Levers always increases distance

B. Pulley Pulley grooved wheel with a rope or chain running along the groove a “flexible first-class lever” F Le Lr

B. Pulley Ideal Mechanical Advantage (IMA) equal to the number of supporting ropes IMA = 0 IMA = 1 IMA = 2

B. Pulley Fixed Pulley IMA = 1 does not increase force changes direction of force

B. Pulley Movable Pulley IMA = 2 increases force doesn’t change direction

B. Pulley Block & Tackle combination of fixed & movable pulleys increases force (IMA = 4) may or may not change direction

C. Wheel and Axle Wheel and Axle two wheels of different sizes that rotate together a pair of “rotating levers” Wheel Axle

C. Wheel and Axle Ideal Mechanical Advantage (IMA) effort force is usu. applied to wheel axle moves less distance but with greater force effort radius resistance radius

Problems Lr Le Lr = 20 cm IMA = Le ÷ Lr Le = 140 cm You use a 160 cm plank to lift a large rock. If the rock is 20 cm from the fulcrum, what is the plank’s IMA? GIVEN: Lr = 20 cm Le = 140 cm IMA = ? WORK: IMA = Le ÷ Lr IMA = (140 cm) ÷ (20 cm) IMA = 7 IMA Le Lr 20cm 160cm

Problems rr re re = 20 cm IMA = re ÷ rr rr = 5 cm A crank on a pasta maker has a radius of 20 cm. The turning shaft has a radius of 5 cm. What is the IMA of this wheel and axle? GIVEN: re = 20 cm rr = 5 cm IMA = ? WORK: IMA = re ÷ rr IMA = (20 cm) ÷ (5 cm) IMA = 4 IMA re rr 20 cm 5 cm

Problems rr re IMA = 6 re = IMA · rr re = ? re = (6)(4 cm) rr = 4 cm A steering wheel requires a mechanical advantage of 6. What radius does the wheel need to have if the steering column has a radius of 4 cm? GIVEN: IMA = 6 re = ? rr = 4 cm WORK: re = IMA · rr re = (6)(4 cm) re = 24 cm IMA re rr rr re

Problems Lr Le Fr = 150 N Le = IMA · Lr Fe = 15 N Le = (10)(0.3) You need to lift a 150 N box using only 15 N of force. How long does the lever need to be if the resistance arm is 0.3m? GIVEN: Fr = 150 N Fe = 15 N Lr = 0.3 m Le = ? MA = 10 WORK: Le = IMA · Lr Le = (10)(0.3) Le = 3 m Total length = Le + Lr Total length = 3.3 m 15N 0.3m ? 150N IMA Le Lr