Difference between revisions of "Pulley" - New World Encyclopedia
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| − | {{ | + | {{Images OK}}{{Submitted}}{{Approved}}{{Paid}}{{Copyedited}} |
| − | + | [[Image:PulleyShip.JPG|thumb|right|275px|Pulleys on a ship. In this context, pulleys are usually known as [[block (sailing)|block]]s.]] | |
| − | [[Image:PulleyShip.JPG|thumb|right|Pulleys on a ship. In this context, pulleys are usually known as [[block (sailing)|block]]s.]] | ||
| − | Pulleys are usually used in sets designed to reduce the amount of | + | A '''pulley''' is a wheel with a groove along its edge for holding a rope or cable. It is a [[simple machine]] that helps change the direction and point of application of a pulling [[force]]. Pulleys are usually used in sets designed to reduce the amount of force needed to lift a load. The [[magnitude (mathematics)|magnitude]] of the force is reduced, but it must act through a longer distance. Consequently, the amount of [[Mechanical work|work]] necessary for the load to reach a particular height is the same as the amount of work needed without the pulleys. |
| + | {{toc}} | ||
| + | Pulleys can be found in many different applications around us. Not only are they used for the obvious lifting of objects, such as by [[crane (machine)|crane]]s, but they are also used in modern [[automobile]]s and [[airplane]]s. Pulleys are also essential for most machines in some form or other. | ||
| − | + | == History == | |
| + | As is the case with all the [[simple machine]]s, the origin of the pulley is unknown. When early peoples lifted heavy objects by throwing vines or other crude ropes over tree limbs, they used the idea of a single fixed pulley to change the direction of a force. But since there was no wheel to turn, this use resulted in considerable [[friction]]. | ||
| − | + | The earliest evidence of pulleys dates back to [[Ancient Egypt]] in the Twelfth Dynasty (1991-1802 B.C.E.), although these were probably not used to gain [[mechanical advantage]] but rather to change the direction of the pull.<ref>Dieter Arnold, ''Building in Egypt: Pharaonic Stone Masonry'' (Oxford University Press, 1991, ISBN 978-0195063509).</ref> There is also evidence of their use in [[Mesopotamia]] in the early second millennium B.C.E.<ref> P.R.S. Moorey, ''Ancient Mesopotamian Materials and Industries'' (Eisenbrauns, 1999, ISBN 978-1575060422).</ref> | |
| − | |||
| − | It is not recorded when or by whom the pulley was first developed. It is believed however that [[Archimedes]] developed the first documented [[block and tackle]] pulley system, as recorded by [[Plutarch]]. Plutarch reported that Archimedes moved an entire warship, laden with men, using compound pulleys and his own strength. | + | It is not recorded when or by whom the pulley was first developed. It is believed however that [[Archimedes]] developed the first documented [[block and tackle]] pulley system, as recorded by [[Plutarch]]. Plutarch reported that Archimedes moved an entire warship, laden with men, using compound pulleys and his own strength. |
| − | ==Types of | + | ==Types of Pulleys== |
| − | [[Image:Pulley.jpg| | + | [[Image:Pulley.jpg|180px|thumb|left|A fixed pulley.]] |
| − | [[Image:Polea-simple-movil2.jpg| | + | [[Image:Polea-simple-movil2.jpg|180px|thumb|right|A movable pulley.]] |
| − | * '''Fixed''' A ''fixed'' or ''class 1'' pulley has a fixed [[axle]]. | + | * '''Fixed''' A ''fixed'' or ''class 1'' pulley has a fixed [[axle]]. That is, the axle is "fixed" or anchored in place. A fixed pulley is used to redirect the [[force]] in a rope (called a [[belt (mechanical)|belt]] when it goes in a full circle. A fixed pulley has a [[mechanical advantage]] of one. |
| − | * '''Movable''' A ''movable'' or ''class 2'' pulley has a free axle. | + | * '''Movable''' A ''movable'' or ''class 2'' pulley has a free axle. That is, the axle is "free" to move in space. A movable pulley is used to transform forces. A movable pulley has a mechanical advantage of two. That is, if one end of the rope is anchored, pulling on the other end of the rope will apply a doubled force to the object attached to the pulley. |
* '''Compound''' A ''compound pulley'' is a combination fixed and movable pulley system. | * '''Compound''' A ''compound pulley'' is a combination fixed and movable pulley system. | ||
| − | ** Block and tackle - A ''block and tackle'' is a compound pulley where several pulleys are mounted on each axle, further increasing the mechanical advantage. | + | ** '''Block and tackle''' - A ''block and tackle'' is a compound pulley where several pulleys are mounted on each axle, further increasing the mechanical advantage. |
| − | + | ||
Pulleys are able to change the direction of the force. | Pulleys are able to change the direction of the force. | ||
| − | == Theory of | + | == Theory of Operation == |
<gallery> | <gallery> | ||
Image:Pulley0.png|Diagram 1 - A basic equation for a pulley: In equilibrium, the force ''F'' on the pulley axle is equal and opposite to the sum of the [[Tension (mechanics)|tension]]s in each line leaving the pulley, and these tensions are equal. | Image:Pulley0.png|Diagram 1 - A basic equation for a pulley: In equilibrium, the force ''F'' on the pulley axle is equal and opposite to the sum of the [[Tension (mechanics)|tension]]s in each line leaving the pulley, and these tensions are equal. | ||
| Line 31: | Line 32: | ||
</gallery> | </gallery> | ||
| − | The simplest theory of operation for a pulley system assumes that the pulleys and lines are weightless, and that there is no energy loss due to friction. It is also assumed that the lines do not stretch. With this assumption, it follows that, in equilibrium, the total force on the pulley must be zero. This means that the force on the axle of the pulley is shared equally by the two lines looping through the pulley. The situation is schematically illustrated in | + | The simplest theory of operation for a pulley system assumes that the pulleys and lines are weightless, and that there is no [[energy]] loss due to [[friction]]. It is also assumed that the lines do not stretch. With this assumption, it follows that, in equilibrium, the total [[force]] on the pulley must be zero. This means that the force on the axle of the pulley is shared equally by the two lines looping through the pulley. The situation is schematically illustrated in Diagram 1. For the case where the lines are not parallel, the tensions in each line are still equal, but now the vector sum of all forces is zero. |
| − | + | ||
| + | A second basic equation for the pulley follows from the [[conservation of energy]]: The product of the weight lifted times the distance it is moved is equal to the product of the lifting force (the tension in the lifting line) times the distance the lifting line is moved. The weight lifted divided by the lifting force is defined as the '''advantage''' of the pulley system. | ||
| − | + | It is important to note that the amount of [[Mechanical work|work]] done in an ideal pulley is always the same. The work is given by the effort times the distance moved. The pulley simply allows trading effort for distance. | |
| − | A second pulley may be added as in | + | In Diagram 2, a single movable pulley allows a unit weight to be lifted with only half the force needed to lift the weight without assistance. The total force needed is divided between the lifting force (red arrow) and the "ceiling" which is some immovable object (such as the earth). In this simple system, the lifting force is directed in the same direction as the movement of the weight. The advantage of this system is two. Although the force needed to lift the unit weight is only half of the unit weight, we will need to draw a length of rope that is twice the distance that the weight is lifted, so that the total amount of work done (force x distance) remains the same. |
| + | |||
| + | A second pulley may be added as in Diagram 2a, which simply serves to redirect the lifting force downward, it does not change the advantage of the system. | ||
<br style="clear: left"/> | <br style="clear: left"/> | ||
<gallery> | <gallery> | ||
| − | Image:Pulley2.png|Diagram 3 - A simple compound pulley system - a | + | Image:Pulley2.png|Diagram 3 - A simple compound pulley system - a movable pulley and a fixed pulley lifting a unit weight. The tension in each line is one third the unit weight, yielding an advantage of three. |
| − | Image:Pulley2a.png|Diagram 3a - A simple compound pulley system - a | + | Image:Pulley2a.png|Diagram 3a - A simple compound pulley system - a movable pulley and a fixed pulley lifting a unit weight, with an additional pulley redirecting the lifting force downward. The tension in each line is one third the unit weight, yielding an advantage of three. |
| − | Image:Pulley3a.png|Diagram 4a - A more complicated compound pulley system. | + | Image:Pulley3a.png|Diagram 4a - A more complicated compound pulley system. The tension in each line is one quarter of the unit weight, yielding an advantage of four. An additional pulley redirecting the lifting force has been added. |
Image:Polispasto4.jpg|Figure 4b - A practical block and tackle pulley system corresponding to diagram 4a. Note that the axles of the fixed and movable pulleys have been combined. | Image:Polispasto4.jpg|Figure 4b - A practical block and tackle pulley system corresponding to diagram 4a. Note that the axles of the fixed and movable pulleys have been combined. | ||
</gallery> | </gallery> | ||
| − | The addition of a fixed pulley to the single pulley system can yield an increase of advantage. In | + | The addition of a fixed pulley to the single pulley system can yield an increase of advantage. In Diagram 3, the addition of a fixed pulley yields a lifting advantage of three. The tension in each line is one-third the unit weight, and the force on the axles of each pulley is two-thirds of a unit weight. As in the case of Diagram 2a, another pulley may be added to reverse the direction of the lifting force, but with no increase in advantage. This situation is shown in Diagram 3a. |
<br style="clear: left"/> | <br style="clear: left"/> | ||
| − | This process can be continued indefinitely for ideal pulleys with each additional pulley yielding a unit increase in advantage. For real pulleys friction | + | This process can be continued indefinitely for ideal pulleys with each additional pulley yielding a unit increase in advantage. For real pulleys, however, friction between the rope and pulleys will increase as more pulleys are added, to the point that no advantage is possible. It puts a limit for the number of pulleys we can use in practice. The above pulley systems are known collectively as [[block and tackle]] pulley systems. In diagram 4a, a block and tackle system with advantage four is shown. A practical implementation in which the connection to the ceiling is combined and the fixed and movable pulleys are encased in single housings is shown in Figure 4b. |
| − | |||
| − | |||
| − | + | Other pulley systems are possible, and some can deliver an increased advantage with fewer pulleys than the block and tackle system. The advantage of the block and tackle system is that each pulley and line is subjected to equal tensions and forces. Efficient design dictates that each line and pulley be capable of handling its load, and no more. Other pulley designs will require different strengths of lines and pulleys depending on their position in the system. However, a block and tackle system can use the same line size throughout, and can mount the fixed and movable pulleys on a common axle. | |
| − | |||
| − | + | == Uses of Pulleys == | |
| + | Pulleys have been used for lifting for thousands of years. The most prevalent and oldest example are their uses on [[ship]]s and [[boat]]s. The [[block and tackle]] have been a key tool for raising sails and cargo. Another major use for pulleys is with [[crane (machine)|cranes]]. | ||
| − | + | Pulleys continue to be used in modern times with various machines and systems. Even in the [[space age]], pulleys play an important role in the construction and operations of spacecraft and aircraft. It is with a pulley system that [[rudder]]s for an aircraft are controlled. In fact, pulleys are commonly used in everyday life, from vehicles to moving equipment. | |
| − | + | ==Notes== | |
| − | + | <references/> | |
| − | |||
| − | |||
== References == | == References == | ||
| − | + | * Arnold, Dieter. ''Building in Egypt: Pharaonic Stone Masonry''. Oxford University Press, 1991. ISBN 978-0195063509 | |
| + | * Delta Education. ''Levers and Pulleys.'' Nashua, NH: Delta Education, 2000. ISBN 0875048110 | ||
| + | * Hellman, Harold, Hal Hellman, and Lynn Sweat. ''The Lever And Pulley.'' New York, NY: M. Evans and Company, Inc., 1971. ISBN 0871310724 | ||
| + | * Moorey, P.R.S. ''Ancient Mesopotamian Materials and Industries''. Eisenbrauns, 1999. ISBN 978-1575060422 | ||
| + | * Seller, Mick. ''Wheels, Pulleys, and Levers.'' New York: Gloucester Press, 1993. ISBN 0531174204 | ||
== External links == | == External links == | ||
| − | + | All links retrieved December 2, 2022. | |
| + | * [https://science.howstuffworks.com/transport/engines-equipment/pulley.htm How a Block and Tackle Works] – ''How Stuff Works''. | ||
| + | * [https://www.explainthatstuff.com/pulleys.html Pulleys] - ''Explain That Stuff!'' | ||
[[Category:Physical sciences]] | [[Category:Physical sciences]] | ||
Latest revision as of 23:46, 2 December 2022
A pulley is a wheel with a groove along its edge for holding a rope or cable. It is a simple machine that helps change the direction and point of application of a pulling force. Pulleys are usually used in sets designed to reduce the amount of force needed to lift a load. The magnitude of the force is reduced, but it must act through a longer distance. Consequently, the amount of work necessary for the load to reach a particular height is the same as the amount of work needed without the pulleys.
Pulleys can be found in many different applications around us. Not only are they used for the obvious lifting of objects, such as by cranes, but they are also used in modern automobiles and airplanes. Pulleys are also essential for most machines in some form or other.
History
As is the case with all the simple machines, the origin of the pulley is unknown. When early peoples lifted heavy objects by throwing vines or other crude ropes over tree limbs, they used the idea of a single fixed pulley to change the direction of a force. But since there was no wheel to turn, this use resulted in considerable friction.
The earliest evidence of pulleys dates back to Ancient Egypt in the Twelfth Dynasty (1991-1802 B.C.E.), although these were probably not used to gain mechanical advantage but rather to change the direction of the pull.[1] There is also evidence of their use in Mesopotamia in the early second millennium B.C.E.[2]
It is not recorded when or by whom the pulley was first developed. It is believed however that Archimedes developed the first documented block and tackle pulley system, as recorded by Plutarch. Plutarch reported that Archimedes moved an entire warship, laden with men, using compound pulleys and his own strength.
Types of Pulleys
- Fixed A fixed or class 1 pulley has a fixed axle. That is, the axle is "fixed" or anchored in place. A fixed pulley is used to redirect the force in a rope (called a belt when it goes in a full circle. A fixed pulley has a mechanical advantage of one.
- Movable A movable or class 2 pulley has a free axle. That is, the axle is "free" to move in space. A movable pulley is used to transform forces. A movable pulley has a mechanical advantage of two. That is, if one end of the rope is anchored, pulling on the other end of the rope will apply a doubled force to the object attached to the pulley.
- Compound A compound pulley is a combination fixed and movable pulley system.
- Block and tackle - A block and tackle is a compound pulley where several pulleys are mounted on each axle, further increasing the mechanical advantage.
Pulleys are able to change the direction of the force.
Theory of Operation
Diagram 1 - A basic equation for a pulley: In equilibrium, the force F on the pulley axle is equal and opposite to the sum of the tensions in each line leaving the pulley, and these tensions are equal.
Diagram 2 - A simple pulley system - a single movable pulley lifting a unit weight. The tension in each line is half the unit weight, yielding an advantage of 2.
Diagram 2a - Another simple pulley system similar to diagram 2, but in which the lifting force is redirected downward.
A practical compound pulley corresponding to diagram 2a.
The simplest theory of operation for a pulley system assumes that the pulleys and lines are weightless, and that there is no energy loss due to friction. It is also assumed that the lines do not stretch. With this assumption, it follows that, in equilibrium, the total force on the pulley must be zero. This means that the force on the axle of the pulley is shared equally by the two lines looping through the pulley. The situation is schematically illustrated in Diagram 1. For the case where the lines are not parallel, the tensions in each line are still equal, but now the vector sum of all forces is zero.
A second basic equation for the pulley follows from the conservation of energy: The product of the weight lifted times the distance it is moved is equal to the product of the lifting force (the tension in the lifting line) times the distance the lifting line is moved. The weight lifted divided by the lifting force is defined as the advantage of the pulley system.
It is important to note that the amount of work done in an ideal pulley is always the same. The work is given by the effort times the distance moved. The pulley simply allows trading effort for distance.
In Diagram 2, a single movable pulley allows a unit weight to be lifted with only half the force needed to lift the weight without assistance. The total force needed is divided between the lifting force (red arrow) and the "ceiling" which is some immovable object (such as the earth). In this simple system, the lifting force is directed in the same direction as the movement of the weight. The advantage of this system is two. Although the force needed to lift the unit weight is only half of the unit weight, we will need to draw a length of rope that is twice the distance that the weight is lifted, so that the total amount of work done (force x distance) remains the same.
A second pulley may be added as in Diagram 2a, which simply serves to redirect the lifting force downward, it does not change the advantage of the system.
Diagram 3 - A simple compound pulley system - a movable pulley and a fixed pulley lifting a unit weight. The tension in each line is one third the unit weight, yielding an advantage of three.
Diagram 3a - A simple compound pulley system - a movable pulley and a fixed pulley lifting a unit weight, with an additional pulley redirecting the lifting force downward. The tension in each line is one third the unit weight, yielding an advantage of three.
Diagram 4a - A more complicated compound pulley system. The tension in each line is one quarter of the unit weight, yielding an advantage of four. An additional pulley redirecting the lifting force has been added.
Figure 4b - A practical block and tackle pulley system corresponding to diagram 4a. Note that the axles of the fixed and movable pulleys have been combined.
The addition of a fixed pulley to the single pulley system can yield an increase of advantage. In Diagram 3, the addition of a fixed pulley yields a lifting advantage of three. The tension in each line is one-third the unit weight, and the force on the axles of each pulley is two-thirds of a unit weight. As in the case of Diagram 2a, another pulley may be added to reverse the direction of the lifting force, but with no increase in advantage. This situation is shown in Diagram 3a.
This process can be continued indefinitely for ideal pulleys with each additional pulley yielding a unit increase in advantage. For real pulleys, however, friction between the rope and pulleys will increase as more pulleys are added, to the point that no advantage is possible. It puts a limit for the number of pulleys we can use in practice. The above pulley systems are known collectively as block and tackle pulley systems. In diagram 4a, a block and tackle system with advantage four is shown. A practical implementation in which the connection to the ceiling is combined and the fixed and movable pulleys are encased in single housings is shown in Figure 4b.
Other pulley systems are possible, and some can deliver an increased advantage with fewer pulleys than the block and tackle system. The advantage of the block and tackle system is that each pulley and line is subjected to equal tensions and forces. Efficient design dictates that each line and pulley be capable of handling its load, and no more. Other pulley designs will require different strengths of lines and pulleys depending on their position in the system. However, a block and tackle system can use the same line size throughout, and can mount the fixed and movable pulleys on a common axle.
Uses of Pulleys
Pulleys have been used for lifting for thousands of years. The most prevalent and oldest example are their uses on ships and boats. The block and tackle have been a key tool for raising sails and cargo. Another major use for pulleys is with cranes.
Pulleys continue to be used in modern times with various machines and systems. Even in the space age, pulleys play an important role in the construction and operations of spacecraft and aircraft. It is with a pulley system that rudders for an aircraft are controlled. In fact, pulleys are commonly used in everyday life, from vehicles to moving equipment.
Notes
- ↑ Dieter Arnold, Building in Egypt: Pharaonic Stone Masonry (Oxford University Press, 1991, ISBN 978-0195063509).
- ↑ P.R.S. Moorey, Ancient Mesopotamian Materials and Industries (Eisenbrauns, 1999, ISBN 978-1575060422).
ReferencesISBN links support NWE through referral fees
- Arnold, Dieter. Building in Egypt: Pharaonic Stone Masonry. Oxford University Press, 1991. ISBN 978-0195063509
- Delta Education. Levers and Pulleys. Nashua, NH: Delta Education, 2000. ISBN 0875048110
- Hellman, Harold, Hal Hellman, and Lynn Sweat. The Lever And Pulley. New York, NY: M. Evans and Company, Inc., 1971. ISBN 0871310724
- Moorey, P.R.S. Ancient Mesopotamian Materials and Industries. Eisenbrauns, 1999. ISBN 978-1575060422
- Seller, Mick. Wheels, Pulleys, and Levers. New York: Gloucester Press, 1993. ISBN 0531174204
External links
All links retrieved December 2, 2022.
- How a Block and Tackle Works – How Stuff Works.
- Pulleys - Explain That Stuff!
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