Jmdonev: 1 revision imported

2018-07-21T01:13:06Z

1 revision imported

← Older revision	Revision as of 01:13, 21 July 2018
(No difference)

Jmdonev at 20:04, 19 July 2018

2018-07-19T20:04:27Z

← Older revision		Revision as of 20:04, 19 July 2018
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	[[Category:Done ~~2015~~-06-01]] [[~~Category~~: ~~Needs citations~~]][[~~category~~:~~check images~~]]		[[Category:Done 2018-07-20]]
	<onlyinclude>The '''normal force''' is an [[everyday force]] that is felt ~~every time two surfaces push~~ against ~~each other~~. For example, when a book is placed on a table, the normal force keeps the book from falling through the table.</onlyinclude> [[Gravity]] is pulling the book downward, but since the book isn't actually falling, something must be pushing it up. This [[force]] is called the normal force. The name 'normal' means perpendicular to the surface.		[[File:normal force tabe dot .png\|thumb\|right\|450px\|Figure 1. The force arrow for either direction ''begins at the surface(the black dot).'' Due to Newton's third law, the normal forces will be equal in magnitude and in opposite direction. The normal force always makes a 90 degree angle with the surface (perpendicular).]]

			[[File:normal force incline dot.png\|thumb\|right\|450px\|Figure 2. The normal forces that act on an object that is placed on an inclined plane. All the conditions in Figure 1 apply.]]

			<onlyinclude>The '''normal force''' is an [[everyday force]] that is felt when a surface pushes against an object that is placed on that surface.<ref name = Knight>R. Knight, Physics for scientists and engineers. Addison Wesley, 2012, p. 120</ref> For example, when a book is placed on a table, the normal force keeps the book from falling through the table.</onlyinclude> [[Gravity]] is pulling the book downward, but since the book isn't actually falling, something must be pushing it up. This [[force]] is called the normal force. The name 'normal' means perpendicular to the surface. Figure 1 and Figure 2 show how the the normal force acts on the object. Contrast to the gravitational force (whose force starts at the centre of the object)—the normal force begins at the surface.


	The normal force arises from the [[electromagnetic force]]; specifically, the [[electron]]s in the book push against the electrons in the table. Since the electrons don't want to get any closer to each other, the book stays on top of the table.		The normal force arises from the [[electromagnetic force]]; specifically, the [[electron]]s in the book push against the electrons in the table. Since the electrons don't want to get any closer to each other, the book stays on top of the table.

	The normal force is closely related to the [[friction]] force. Both are [[non-conservative force]]s, which can be seen when a ball bounces. The ball falls; gravity pulls it down, so it speeds up, while [[air drag]] slows the fall ~~somewhat~~. When the ball hits the ground a huge normal force pushes upwards, making the ball bounce not quite as high as when it started. There is [[energy]] lost to changing the shape of the ball, which becomes [[thermal energy]] (warming the ball) and [[sound]]. The normal force can also be seen as non-conservative in the case of [[rolling resistance]]. The deformation of the tire (or wheel) means that energy is being lost to that change of shape.
			The normal force is closely related to the [[friction]] force.<ref name = Knight/> Both are [[non-conservative force]]s, which can be seen when a ball bounces. The ball falls; gravity pulls it down, so it speeds up, while [[air drag]] somewhat slows the fall. When the ball hits the ground a huge normal force pushes upwards, making the ball bounce not quite as high as when it started. There is [[energy]] lost to changing the shape of the ball, which becomes [[thermal energy]] (warming the ball) and [[sound]]. The normal force can also be seen as non-conservative in the case of [[rolling resistance]]. The deformation of the tire (or wheel) means that energy is being lost to that change of shape.

	See Florian Knorn's video below for an example of how the normal force deforms a tennis ball while bouncing:		See Florian Knorn's video below for an example of how the normal force deforms a tennis ball while bouncing:
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	Please see UC Davis's [http://physwiki.ucdavis.edu/Fundamentals/03._Conservation_of_Momentum/3.2_Force_In_One_Dimension Phys wiki] or [http://hyperphysics.phy-astr.gsu.edu/hbase/frict.html#nor hyperphysics] for more information about the normal force.		Please see UC Davis's [http://physwiki.ucdavis.edu/Fundamentals/03._Conservation_of_Momentum/3.2_Force_In_One_Dimension Phys wiki] or [http://hyperphysics.phy-astr.gsu.edu/hbase/frict.html#nor hyperphysics] for more information about the normal force.

			==For Further Reading==
			*[[Force]]
			*[[Non-conservative force]]
			*[[Gravitational force]]
			*[[Electromagnetic force]]
			*[[Friction]]
			*Or explore a [[Special:Random\|random page]]

			==References==
			{{reflist}}
	[[Category:Uploaded]]		[[Category:Uploaded]]

J.williams: 1 revision imported

2015-08-26T21:31:25Z

1 revision imported

← Older revision	Revision as of 21:31, 26 August 2015
(No difference)

J.williams at 16:57, 12 August 2015

2015-08-12T16:57:08Z

New page

[[Category:Done 2015-06-01]] [[Category: Needs citations]][[category:check images]]
<onlyinclude>The '''normal force''' is an [[everyday force]] that is felt every time two surfaces push against each other. For example, when a book is placed on a table, the normal force keeps the book from falling through the table.</onlyinclude> [[Gravity]] is pulling the book downward, but since the book isn't actually falling, something must be pushing it up. This [[force]] is called the normal force. The name 'normal' means perpendicular to the surface.

The normal force arises from the [[electromagnetic force]]; specifically, the [[electron]]s in the book push against the electrons in the table. Since the electrons don't want to get any closer to each other, the book stays on top of the table.

The normal force is closely related to the [[friction]] force. Both are [[non-conservative force]]s, which can be seen when a ball bounces. The ball falls; gravity pulls it down, so it speeds up, while [[air drag]] slows the fall somewhat. When the ball hits the ground a huge normal force pushes upwards, making the ball bounce not quite as high as when it started. There is [[energy]] lost to changing the shape of the ball, which becomes [[thermal energy]] (warming the ball) and [[sound]]. The normal force can also be seen as non-conservative in the case of [[rolling resistance]]. The deformation of the tire (or wheel) means that energy is being lost to that change of shape.

See Florian Knorn's video below for an example of how the normal force deforms a tennis ball while bouncing:

<html>
<iframe width="800" height="580" src="//www.youtube.com/embed/zd2V4_FNMls" frameborder="0" allowfullscreen></iframe>
</html>

Please see UC Davis's [http://physwiki.ucdavis.edu/Fundamentals/03._Conservation_of_Momentum/3.2_Force_In_One_Dimension Phys wiki] or [http://hyperphysics.phy-astr.gsu.edu/hbase/frict.html#nor hyperphysics] for more information about the normal force.
[[Category:Uploaded]]

Normal force - Revision history

Jmdonev: 1 revision imported

Jmdonev at 20:04, 19 July 2018

J.williams: 1 revision imported

J.williams at 16:57, 12 August 2015