Chapter 10 Simple Machine
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CHAPTER 10
Simple machines
CHAPTER 10
Simple machines UNIT 10.1 Analysing lever
List things around them that use the principle of the lever State what a lever can do Identify load, force and fulcrum of the lever Classify lever Explain what is meant by the moment of force Solve problems related to levers
Lever is
What is Lever ?
a) A simple machine b) Enables small effort to overcome a heavy load c) Can be used to lift heavy objects
d) Makes work easier A lever is a simple machine which turns about a fixed point called the FULCRUM (F) when a force called the EFFORT (E) is applied to overcome a resisting force known as the LOAD (L).
Types of Simple Machines
Wedge Lever
Wheel and axle
6 types of simple machines Screw Pulley
Inclined plane
What is Lever ? A lever has 3 parts a)Fulcrum (F) – the turning point or pivot b)Effort (E) – the force applied to overcome a resisting force called the load
c)Load (L) – the resisting force exerted by an object
Simple Machines E F
L
E
L
F L
E F
E L
E
E
L L L
E
F
What is Lever ? Lever can be classified into a) 1st class b)
2nd class
c)
3rd class
Classes of Levers
Lever
A lever is a simple machine which turns about a fixed point called the FULCRUM (F) when a force called the EFFORT (E) is applied to overcome a resisting force known as the LOAD (L).
3 classes of levers
First class
Second class
Third class
First Class Lever
1st class
E F
First class lever
Relative position of F, E and L
F between E and L
L
Common characteristics
• Small force is used to move a large load • Effort moves through a longer distance than the load • Effort is further from the fulcrum than the load
Common devices
• Claw hammer • Pliers • Scissors • Crowbar
Second Class Lever
2nd class
Second class lever
Relative position of F, E and L
L between F and E
Common characteristics
• Small force is used to move a large load • Effort moves through a longer distance than the load • Effort is further from the fulcrum than the load
E
F L
Common devices
• Wheelbarrow • Bottle opener • Paper cutter • Nutcracker
Third Class Lever
3rd class
E
F
Third class lever
Relative position of F, E and L
E between F and L
Common characteristics
• Large force is used to move a small load • Load moves through a longer distance than the effort • Load is further from the fulcrum than the effort
L
Common devices
• Fishing rod • Broom • Ice tongs • Human arm
1st class
E F
=
L
F
E
=
F
L
E
=
F
E
L
L
2nd class
E
F L
3rd class
E
F L
F E
L
E
F L
F
E
E
L
L L E
F
E
E
L
F
L
L
E
F
E
E
F
F
L L
What is the Moment of a Force? When we loosen a bolt using a spanner, a force that is applied has a turning effect on the spanner. This turning effect of force is known as the moment of force Spanner
Spanner P
Q
Force 18 cm
Force 7 cm
a) It is easier to loosen the bolt if you hold the spanner at position P than Q because the turning effect is greater. b) It is also easier to loosen the bolt if a larger force is applied at P to cause a greater turning effect.
What is the Moment of a Force? • The moment of a force is the turning effect of the force • The moment of a force is defined as: Moment of a force (N m)
= Force (N) x
The moment of a force can be increased by
Perpendicular distance from the pivot to the force (m)
Increasing the size of the force Applying the force at a further distance from the pivot
To Calculate the Moment of a Force
Opening a door
0.6 m
4N
Moment of a force (N m)
= Force (N) x = 4N
x
= 2.4 N m
Perpendicular distance from the pivot to the force (m)
0.6 m
Principle of Moments in a Lever The effort and the load produce opposing moments
Anticlockwise moment
When the lever is in EQUILIBRIUM, the sum of the anticlockwise moments about a point is equal to the sum of the clockwise
Principle Of Moments in a Lever When the lever system is balanced
Anticlockwise moment
Load (N) x Distance of load from fulcrum (m)
=
=
Clockwise moment
Effort (N) x Distance of effort from fulcrum (m)
Moments in a Lever
30 cm
x
250 g
400 g
Calculate the value of x using the equation below: Load (N) x Distance of load from fulcrum (m)
=
Effort (N) x Distance of effort from fulcrum (m)
Answer : 18.75 cm
CHAPTER 10
Simple machines UNIT 10.1
Appreciating the innovative efforts in the design of machine
Devices that Using the Principle of Levers
A spade Tongs
A hockey stick
Devices using the principle of levers A crane
A fishing rod A fire engine
SMK Perempuan Likas Sabah
Simple machines
CHAPTER 10
Simple machines UNIT 10.1 Analysing lever
List things around them that use the principle of the lever State what a lever can do Identify load, force and fulcrum of the lever Classify lever Explain what is meant by the moment of force Solve problems related to levers
Lever is
What is Lever ?
a) A simple machine b) Enables small effort to overcome a heavy load c) Can be used to lift heavy objects
d) Makes work easier A lever is a simple machine which turns about a fixed point called the FULCRUM (F) when a force called the EFFORT (E) is applied to overcome a resisting force known as the LOAD (L).
Types of Simple Machines
Wedge Lever
Wheel and axle
6 types of simple machines Screw Pulley
Inclined plane
What is Lever ? A lever has 3 parts a)Fulcrum (F) – the turning point or pivot b)Effort (E) – the force applied to overcome a resisting force called the load
c)Load (L) – the resisting force exerted by an object
Simple Machines E F
L
E
L
F L
E F
E L
E
E
L L L
E
F
What is Lever ? Lever can be classified into a) 1st class b)
2nd class
c)
3rd class
Classes of Levers
Lever
A lever is a simple machine which turns about a fixed point called the FULCRUM (F) when a force called the EFFORT (E) is applied to overcome a resisting force known as the LOAD (L).
3 classes of levers
First class
Second class
Third class
First Class Lever
1st class
E F
First class lever
Relative position of F, E and L
F between E and L
L
Common characteristics
• Small force is used to move a large load • Effort moves through a longer distance than the load • Effort is further from the fulcrum than the load
Common devices
• Claw hammer • Pliers • Scissors • Crowbar
Second Class Lever
2nd class
Second class lever
Relative position of F, E and L
L between F and E
Common characteristics
• Small force is used to move a large load • Effort moves through a longer distance than the load • Effort is further from the fulcrum than the load
E
F L
Common devices
• Wheelbarrow • Bottle opener • Paper cutter • Nutcracker
Third Class Lever
3rd class
E
F
Third class lever
Relative position of F, E and L
E between F and L
Common characteristics
• Large force is used to move a small load • Load moves through a longer distance than the effort • Load is further from the fulcrum than the effort
L
Common devices
• Fishing rod • Broom • Ice tongs • Human arm
1st class
E F
=
L
F
E
=
F
L
E
=
F
E
L
L
2nd class
E
F L
3rd class
E
F L
F E
L
E
F L
F
E
E
L
L L E
F
E
E
L
F
L
L
E
F
E
E
F
F
L L
What is the Moment of a Force? When we loosen a bolt using a spanner, a force that is applied has a turning effect on the spanner. This turning effect of force is known as the moment of force Spanner
Spanner P
Q
Force 18 cm
Force 7 cm
a) It is easier to loosen the bolt if you hold the spanner at position P than Q because the turning effect is greater. b) It is also easier to loosen the bolt if a larger force is applied at P to cause a greater turning effect.
What is the Moment of a Force? • The moment of a force is the turning effect of the force • The moment of a force is defined as: Moment of a force (N m)
= Force (N) x
The moment of a force can be increased by
Perpendicular distance from the pivot to the force (m)
Increasing the size of the force Applying the force at a further distance from the pivot
To Calculate the Moment of a Force
Opening a door
0.6 m
4N
Moment of a force (N m)
= Force (N) x = 4N
x
= 2.4 N m
Perpendicular distance from the pivot to the force (m)
0.6 m
Principle of Moments in a Lever The effort and the load produce opposing moments
Anticlockwise moment
When the lever is in EQUILIBRIUM, the sum of the anticlockwise moments about a point is equal to the sum of the clockwise
Principle Of Moments in a Lever When the lever system is balanced
Anticlockwise moment
Load (N) x Distance of load from fulcrum (m)
=
=
Clockwise moment
Effort (N) x Distance of effort from fulcrum (m)
Moments in a Lever
30 cm
x
250 g
400 g
Calculate the value of x using the equation below: Load (N) x Distance of load from fulcrum (m)
=
Effort (N) x Distance of effort from fulcrum (m)
Answer : 18.75 cm
CHAPTER 10
Simple machines UNIT 10.1
Appreciating the innovative efforts in the design of machine
Devices that Using the Principle of Levers
A spade Tongs
A hockey stick
Devices using the principle of levers A crane
A fishing rod A fire engine
SMK Perempuan Likas Sabah
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