Simple Machines

Simple Machines Dennis Papesh Holy Angels School Dayton, Ohio papeshdr@holyangels.cc dpapesh@aol.com

The Event • Teams will measure and calculate the IMA, AMA, and Efficiency of various simple machines. • Students will determine the above at four different stations. • The machines may be a) a lever, b) an inclined plane, c) a pulley system, or d) a wheel and axle system.

The Event • Any or all of the machines may be enclosed or hidden from the student’s view as long as the student has reasonable access to the input and output connections. • The student may be asked to use the information to solve a problem using the machine in a specific way.

The Event • Three of the stations will be single simple machines. • One of the stations will be combinations of machines used in series where students will determine the overall IMA, AMA, and Efficiency. • Non-programmable calculators may be used.

Nat’l Competition • Teams will construct the simple machines from materials provided so that their simple machine achieves the target IMA, AMA, and efficiency indicated by the judges. • Teams will then measure and calculate the IMA, AMA, and efficiency of their machines.

Nat’l Competition • Teams will be required to draw and label their set-up. • At the combination station, teams will only be required to determine the IMA, AMA, and efficiency. No construction required as the station will be set up by the judge. • Application and extension questions may be asked at any or all stations.

What is a simple machine? • A machine is anything that changes the size or direction of forces used in doing work • or • A device which multiplies or divides force • It is a ‘simple’ machine because we are only using one at a time • Otherwise, it would be a compound machine

A machine makes work easier by changing at least one of three factors • The amount of force you exert, or • The distance over which you exert the force, or • The direction in which you exert the force.

What is “mechanical advantage” ? • In simple terms, the mechanical advantage is the number of times a machine increases a force exerted on it.

What is the IMAorIdeal Mechanical Advantage ? • The IMA is the mechanical advantage (MA) a machine would have if no other forces, such as friction, are acting upon the machine. • It is the MA of a machine operating at 100% efficiency

What is efficiency ? • The efficiency of a machine compares the work output to the work input. • The less friction there is, the closer the output work is to the input work. • It is always expressed as a percent. • The higher the percent, the more efficient the machine is.

Efficiency Efficiency = AMA X 100 IMA

Calculating efficiency • Efficiency = Work Output Work Input 100 X

Force / Newtons • Force is calculated in Newtons • To convert from mass to Newtons Mass in kg x 9.8m/s/s (which is the acceleration due to gravity on earth) 235 g = .235 kg .235 kg x 9.8m/s/s = 2.303 N

What are the simple machines? • Wedge • Screw • Inclined Plane • Pulley and Block and Tackle • Wheel and Axle • Lever • 1st class, 2nd class, 3rd class

The Wedge • Yes, I know, the rules do not list the wedge as one of the testable machines. • Will I teach my students how to work with the wedge? • Yes, indeed • Mistakes are sometimes made in event test preparations.

The Wedge(Two inclined planes back to back) Output distance Input distance Input distance Output distance IMA =

The Screw • Yes, I know, the rules do not list the screw as one of the testable machines. • Will I teach my students to work with this machine? • Yes • Remember, mistakes are sometimes made.

Screw • Inclined plane wound around a tapered cylinder. • The longer the inclined plane, the less effort, but • The greater distance over which the effort must be applied. • We have to turn the screw more times but with less effort.

The Screw Circumference pitch • IMA = 2πr pitch IMA =

The Screw • Pitch is the distance between threads. pitch

The Screw • The circumference is not necessarily the circumference of the screw. • It is usually the circumference of the device used to turn the screw. • For example, the circumference of the handle of the screwdriver, or • The circumference of the circle described by the handle of a brace and bit.

The Screw • Circumference of circle described as handle rotates • Distance between threads (pitch)

The Inclined Plane(Ramp) Input distance Output distance Input distance Output distance Length of incline Height of incline IMA = IMA = or

Inclined Plane • IMA = 2 m 1 m Length of incline Height of incline 2 m 1 m = = 2

Inclined Plane • IMA = 10 m 2 m Input distance Output distance 10 m 2 m = = 5

AMA by F(out)/F(in) • AMA can be calculated by dividing the force out (often the weight of the object) by the force in. • AMA = resistance force/effort force • Inputting 3 Newtons and lifting 6 Newtons gives you an AMA of 2. • F(out)/F(in) = 6N/3N = 2

The Pulley • IMA = 1 • Only one rope supporting mass (B) • Advantage is you can use body weight to help lift mass. A B

The Pulley • IMA = 2 • Two ropes supporting mass (A) and (B) A B

The Block and Tackle • The block and tackle is the use of more than one pulley to increase mechanical advantage.

The Block and Tackle • IMA = 3 • 3 ropes supporting weight. • B, C, and D • You must pull the rope 3 units down for every one unit the mass rises. B D A C

The Wheel and Axle Radius of outer circle Radius of inner circle IMA =

IMA of a Wheel and Axle • IMA = 5 cm 1 cm Outer radius Inner radius 5 cm 1cm = = 5

Wheel and Axle • What if this doesn’t loosen the bolt?

Wheel and Axle • We get a larger wrench which has a greater wheel radius. • Or we put a piece of pipe over the end and break off the head of the bolt.

IMA by D(in)/D(out) • IMA, especially on wheel and axles, pulleys, or block and tackle set-ups can be calculated by dividing the effort distance ((D(in)) by the load distance ((D(out)). • Effort moves 6 cm and load moves 2 cm • IMA = D(in)/D(out) = 6 cm / 2cm = 3

IMA v. AMA • IMA is calculated using distance • Input 10m / Output 2m = IMA of 5 • AMA is calculated using force or mass • Output 500N / Input 100 N = AMA of 5 • Both are pure numbers (no units)

The Lever • 1st Class (LFE) Effort Fulcrum Load

The Lever • 2nd Class (FLE) Effort Load Fulcrum

The Lever • 3rd Class (FEL) Load Effort Fulcrum

IMA of 1st Class Lever Load Distance • IMA = Effort Distance Effort Distance Load Distance

IMA of a 1st Class Lever 16 cm 8 cm = Effort distance Load distance 16 cm 8 cm Effort Distance Load Distance = 2 IMI =

IMA of a 1st Class Lever 2 cm 24 cm • IMA = 24 cm 2 cm Effort Distance Load Distance = = 12

IMA of a 2nd Class Lever • IMA = Load Distance Effort Distance Effort Distance Load Distance

IMA of a 2nd Class Lever • IMA = 30 cm 50 cm Effort Distance Load Distance 50 cm 30 cm = = 1.67

IMA of a 2nd Class Lever • IMA = 10 cm 50 cm 50 cm 10 cm Effort Distance Load Distance = 5 =

IMA of a 3rd Class Lever • IMA = Effort Distance Load Distance Effort Distance Load Distance It will be less than 1 You gain distance or speed rather than less effort

IMA of a 3rd Class Lever • IMA = 10 cm 50 cm Effort Distance Load Distance 10 cm 50 cm = = 0.2

IMA of all levers (The IMA of all levers can also be calculated by dividing the distance the effort moves divided by the distance the load moves.)

Problem 1 10 cm • IMA = 9 (effort distance / load distance) • If effort (input) is 500N, what is the maximum weight (output) which could be lifted. • 500 N x 9 (IMA) = 4500 N 90 cm

Simple Machines

Simple Machines

Presentation Transcript

Simple Machines

Simple Machines

Simple Machines

Simple Machines

SIMPLE MACHINES

Simple Machines

Simple Machines

Simple machines.

Simple Machines

Simple Machines

Simple Machines

Simple Machines

SIMPLE MACHINES

Simple Machines

Simple Machines

Simple Machines

Simple Machines

Simple Machines

Simple Machines

Simple Machines

SIMPLE MACHINES

Simple Machines