Compression vs Wave Springs - Revision history

Designing Buildings at 07:06, 2 February 2021

2021-02-02T07:06:34Z

← Older revision		Revision as of 07:06, 2 February 2021
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	* Types of spring.		* Types of spring.

−	[[Category:~~Products_/_components~~]] [[Category:DCN_Product_Knowledge]]	+	[[Category:DCN_Commentary]] [[Category:DCN_Guidance]] [[Category:DCN_Product_Knowledge]] [[Category:Products_/_components]]

Designing Buildings at 16:16, 26 November 2018

2018-11-26T16:16:04Z

Designing Buildings at 16:05, 26 November 2018

2018-11-26T16:05:30Z

← Older revision		Revision as of 16:05, 26 November 2018
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	Out of all the springs to ever be invented, the compression spring was one of the first, and because of its wide use, it is also one of the most studied.		Out of all the springs to ever be invented, the compression spring was one of the first, and because of its wide use, it is also one of the most studied.

−	Compression springs are named after the problem they were created to solve – compression. When the spring is put under pressure, it ‘compresses’ or becomes temporarily shorter. On ~~the~~ removal of the pressure, the compression spring regains its previous height. Springs are made to ‘spring back’ to their original forms, and as a result, they push back against ~~pressures~~. The ability to push back against pressure is very useful, and so compression springs have been used in door locks and mechanical clocks.	+	Compression springs are named after the problem they were created to solve – compression. When the spring is put under pressure, it ‘compresses’ or becomes temporarily shorter. On removal of the pressure, the compression spring regains its previous height. Springs are made to ‘spring back’ to their original forms, and as a result, they push back against pressure. The ability to push back against pressure is very useful, and so compression springs have been used, for example, in door locks and mechanical clocks.

	= Use of compression springs =		= Use of compression springs =
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	* The Difference Between Tension and Torsion Springs		* The Difference Between Tension and Torsion Springs
	* The Multiple Uses of Compression Springs		* The Multiple Uses of Compression Springs
		+	* Types of spring.

	[[Category:Products_/_components]]		[[Category:Products_/_components]]

Designing Buildings at 16:03, 26 November 2018

2018-11-26T16:03:56Z

← Older revision		Revision as of 16:03, 26 November 2018
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−	Springs are at work in almost every aspect of our modern-day life, right down to the trainers we run in. Both compression and wave springs are two of the most useful springs ~~to be invented~~, which makes them worthy of comparison.	+	Springs are at work in almost every aspect of our modern-day life, right down to the trainers we run in. Both compression and wave springs are two of the most useful springs, which makes them worthy of comparison.

	= Hooke’s Law =		= Hooke’s Law =

Editor at 16:21, 7 November 2018

2018-11-07T16:21:00Z

← Older revision		Revision as of 16:21, 7 November 2018
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	* Compression springs.		* Compression springs.
		+	* Force.
	* Key qualities of springs.		* Key qualities of springs.
	* Spring materials.		* Spring materials.

Editor at 16:20, 7 November 2018

2018-11-07T16:20:40Z

← Older revision		Revision as of 16:20, 7 November 2018
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	Springs are at work in almost every aspect of our modern-day life, right down to the trainers we run in. Both compression and wave springs are two of the most useful springs to be invented, which makes them worthy of comparison.		Springs are at work in almost every aspect of our modern-day life, right down to the trainers we run in. Both compression and wave springs are two of the most useful springs to be invented, which makes them worthy of comparison.

−	== Hooke’s Law ==	+	= Hooke’s Law =

	The force needed to extend or compress a spring is linear with the distance by which the spring is made to compress or extend.		The force needed to extend or compress a spring is linear with the distance by which the spring is made to compress or extend.

−	F=kx	+	F = kx

−	F: Force applied to spring	+	* F: Force applied to spring.
−		+	* K: Stiffness of spring.
−	K: Stiffness of spring	+	* X: Difference between spring’s original height and height after Force is applied.
−		+
−	X: Difference between spring’s original height and height after Force is applied.	+

	This law can be used to calculate the potential of springs (and some other elastic bodies), which has led to springs being applied more in inventions and everyday life since this law’s publication in 1678. Hooke’s law can be applied to both compression and wave springs, so the two springs are the same in this regard.		This law can be used to calculate the potential of springs (and some other elastic bodies), which has led to springs being applied more in inventions and everyday life since this law’s publication in 1678. Hooke’s law can be applied to both compression and wave springs, so the two springs are the same in this regard.

−	== Introduction to ~~Compression Springs =~~=	+	= Introduction to compression springs =

	Out of all the springs to ever be invented, the compression spring was one of the first, and because of its wide use, it is also one of the most studied.		Out of all the springs to ever be invented, the compression spring was one of the first, and because of its wide use, it is also one of the most studied.
Line 21:		Line 19:
	Compression springs are named after the problem they were created to solve – compression. When the spring is put under pressure, it ‘compresses’ or becomes temporarily shorter. On the removal of the pressure, the compression spring regains its previous height. Springs are made to ‘spring back’ to their original forms, and as a result, they push back against pressures. The ability to push back against pressure is very useful, and so compression springs have been used in door locks and mechanical clocks.		Compression springs are named after the problem they were created to solve – compression. When the spring is put under pressure, it ‘compresses’ or becomes temporarily shorter. On the removal of the pressure, the compression spring regains its previous height. Springs are made to ‘spring back’ to their original forms, and as a result, they push back against pressures. The ability to push back against pressure is very useful, and so compression springs have been used in door locks and mechanical clocks.

−	== Use of ~~Compression Springs =~~=	+	= Use of compression springs =

	Some popular devices that utilise compression springs are in pens, pacemakers, oil rigs and suspension systems. Compression springs have a wide range of uses, and their size will depend on their application. Pacemakers require very small springs, whereas oil rigs use much larger springs.		Some popular devices that utilise compression springs are in pens, pacemakers, oil rigs and suspension systems. Compression springs have a wide range of uses, and their size will depend on their application. Pacemakers require very small springs, whereas oil rigs use much larger springs.

−	== Types of ~~Compression Springs =~~=	+	= Types of compression springs =

	Compression springs come in a variety of shapes, including conical, hourglass and barrel-shapes. Each different type of compression spring is used for a different purpose. Conical springs, for example, can collapse their coils into their centre so they take up less room when compressed. Hourglass and barrel springs offer more stability than regular compression springs. The type of compression spring you require will depend on the type of project you are looking to undertake.		Compression springs come in a variety of shapes, including conical, hourglass and barrel-shapes. Each different type of compression spring is used for a different purpose. Conical springs, for example, can collapse their coils into their centre so they take up less room when compressed. Hourglass and barrel springs offer more stability than regular compression springs. The type of compression spring you require will depend on the type of project you are looking to undertake.

−	[[File:~~Tiny little spring~~.jpg]]	+	[[File:Tiny_little_spring.jpg\|link=File:Tiny_little_spring.jpg]]

−	== Introduction to ~~Wave Springs =~~=	+	= Introduction to wave springs =

	Wave springs are a relatively new invention compared to the 600-year-old compression spring. The first pseudo-wave-spring was stamped around fifty years ago as a flat washer. Since then, wave springs have been in the process of being perfected and can currently be substituted for most uses of compression springs, with cost-savings to be made in the long run, as they use less space than compression springs.		Wave springs are a relatively new invention compared to the 600-year-old compression spring. The first pseudo-wave-spring was stamped around fifty years ago as a flat washer. Since then, wave springs have been in the process of being perfected and can currently be substituted for most uses of compression springs, with cost-savings to be made in the long run, as they use less space than compression springs.

−	== Types of ~~Wave Springs =~~=	+	= Types of wave springs =

	There are two types of wave spring: tension wave springs, made for loads to be attached, and compression wave springs, which are the most common type. The spring potential of a wave spring can be adjusted through a variety of factors, including wire thickness, number of waves per rotation, and gap size. The thicker the wire and the higher the number of waves, the stronger the spring will be.		There are two types of wave spring: tension wave springs, made for loads to be attached, and compression wave springs, which are the most common type. The spring potential of a wave spring can be adjusted through a variety of factors, including wire thickness, number of waves per rotation, and gap size. The thicker the wire and the higher the number of waves, the stronger the spring will be.

−	[[File:~~Wave spring~~.png]]	+	[[File:Wave_spring.png\|link=File:Wave_spring.png]]

−	== Wave ~~Spring Vs Compression Spring =~~=	+	= Wave spring vs. compression spring =

	The wave spring is set to overtake the compression spring in the near future. Both types of spring achieve the same effects, but wave springs can manage this with a lot less space. Wave springs are often more expensive per spring than the standard compression spring, but their space-saving benefits should recompense the individual expenditure and could even result in higher profits for the end product.		The wave spring is set to overtake the compression spring in the near future. Both types of spring achieve the same effects, but wave springs can manage this with a lot less space. Wave springs are often more expensive per spring than the standard compression spring, but their space-saving benefits should recompense the individual expenditure and could even result in higher profits for the end product.

−	[[Category:~~Design~~]]	+	--[[User:European_Springs_and_Pressings_Ltd\|European Springs and Pressings Ltd]]
		+
		+	= Related articles on Designing Buildings Wiki =
		+
		+	* Compression springs.
		+	* Key qualities of springs.
		+	* Spring materials.
		+	* Tension springs v torsion springs.
		+	* The Difference Between Tension and Torsion Springs
		+	* The Multiple Uses of Compression Springs
		+
		+	[[Category:Products_/_components]]

European Springs and Pressings Ltd: Created page with "Springs are at work in almost every aspect of our modern-day life, right down to the trainers we run in. Both compression and wave springs are two of the most useful springs to b..."

2018-10-24T14:30:18Z

Created page with "Springs are at work in almost every aspect of our modern-day life, right down to the trainers we run in. Both compression and wave springs are two of the most useful springs to b..."

New page

Springs are at work in almost every aspect of our modern-day life, right down to the trainers we run in. Both compression and wave springs are two of the most useful springs to be invented, which makes them worthy of comparison.

== Hooke’s Law ==

The force needed to extend or compress a spring is linear with the distance by which the spring is made to compress or extend.

F=kx

F: Force applied to spring

K: Stiffness of spring

X: Difference between spring’s original height and height after Force is applied.

This law can be used to calculate the potential of springs (and some other elastic bodies), which has led to springs being applied more in inventions and everyday life since this law’s publication in 1678. Hooke’s law can be applied to both compression and wave springs, so the two springs are the same in this regard.

== Introduction to Compression Springs ==

Out of all the springs to ever be invented, the compression spring was one of the first, and because of its wide use, it is also one of the most studied.

Compression springs are named after the problem they were created to solve – compression. When the spring is put under pressure, it ‘compresses’ or becomes temporarily shorter. On the removal of the pressure, the compression spring regains its previous height. Springs are made to ‘spring back’ to their original forms, and as a result, they push back against pressures. The ability to push back against pressure is very useful, and so compression springs have been used in door locks and mechanical clocks.

== Use of Compression Springs ==

Some popular devices that utilise compression springs are in pens, pacemakers, oil rigs and suspension systems. Compression springs have a wide range of uses, and their size will depend on their application. Pacemakers require very small springs, whereas oil rigs use much larger springs.

== Types of Compression Springs ==

Compression springs come in a variety of shapes, including conical, hourglass and barrel-shapes. Each different type of compression spring is used for a different purpose. Conical springs, for example, can collapse their coils into their centre so they take up less room when compressed. Hourglass and barrel springs offer more stability than regular compression springs. The type of compression spring you require will depend on the type of project you are looking to undertake.

[[File:Tiny little spring.jpg]]

== Introduction to Wave Springs ==

Wave springs are a relatively new invention compared to the 600-year-old compression spring. The first pseudo-wave-spring was stamped around fifty years ago as a flat washer. Since then, wave springs have been in the process of being perfected and can currently be substituted for most uses of compression springs, with cost-savings to be made in the long run, as they use less space than compression springs.

== Types of Wave Springs ==

There are two types of wave spring: tension wave springs, made for loads to be attached, and compression wave springs, which are the most common type. The spring potential of a wave spring can be adjusted through a variety of factors, including wire thickness, number of waves per rotation, and gap size. The thicker the wire and the higher the number of waves, the stronger the spring will be.

[[File:Wave spring.png]]

== Wave Spring Vs Compression Spring ==

The wave spring is set to overtake the compression spring in the near future. Both types of spring achieve the same effects, but wave springs can manage this with a lot less space. Wave springs are often more expensive per spring than the standard compression spring, but their space-saving benefits should recompense the individual expenditure and could even result in higher profits for the end product.

[[Category:Design]]

← Older revision		Revision as of 16:16, 26 November 2018
Line 15:		Line 15:
	= Introduction to compression springs =		= Introduction to compression springs =

−	Out of all the springs ~~to ever be~~ invented, the compression spring was one of the first, and because of its wide use, it is also one of the most studied.	+	Out of all the springs invented, the compression spring was one of the first, and because of its wide use, it is also one of the most studied.

−	Compression springs are named after the problem they were created to solve – compression. When the spring is put under pressure, it ‘compresses’ or becomes temporarily shorter. On removal of the pressure, the compression spring regains its previous height. Springs are made to ‘spring back’ to their original forms, and as a result, they push back against pressure~~. The ability to push back against pressure is very useful, and so compression springs have been used, for example, in door locks and mechanical clocks~~.	+	Compression springs are named after the problem they were created to solve – compression. When the spring is put under pressure, it ‘compresses’ or becomes temporarily shorter. On removal of the pressure, the compression spring regains its previous height. Springs are made to ‘spring back’ to their original forms, and as a result, they push back against pressure.

	= Use of compression springs =		= Use of compression springs =

−	Some popular devices that utilise compression springs are in pens, pacemakers, oil rigs and suspension systems. Compression springs have a wide range of uses, and their size will depend on their application. Pacemakers require very small springs, whereas oil rigs use much larger springs.	+	Some popular devices that utilise compression springs are; pens, pacemakers, oil rigs and suspension systems. Compression springs have a wide range of uses, and their size will depend on their application. Pacemakers require very small springs, whereas oil rigs use much larger springs.

	= Types of compression springs =		= Types of compression springs =

−	Compression springs come in a variety of shapes, including conical, hourglass and barrel-shapes. Each different type of compression spring is used for a different purpose. Conical springs, for example, can collapse their coils into their centre so they take up less room when compressed. Hourglass and barrel springs offer more stability than regular compression springs. The type of compression spring ~~you require~~ will depend on the type of project ~~you are looking to undertake~~.	+	Compression springs come in a variety of shapes, including conical, hourglass and barrel-shapes. Each different type of compression spring is used for a different purpose. Conical springs, for example, can collapse their coils into their centre so they take up less room when compressed. Hourglass and barrel springs offer more stability than regular compression springs. The type of compression spring required will depend on the type of project being undertaken.

	[[File:Tiny_little_spring.jpg\|link=File:Tiny_little_spring.jpg]]		[[File:Tiny_little_spring.jpg\|link=File:Tiny_little_spring.jpg]]
Line 31:		Line 31:
	= Introduction to wave springs =		= Introduction to wave springs =

−	Wave springs are a relatively new invention compared to the 600-year-old compression spring. The first pseudo-wave-spring was stamped around fifty years ago as a flat washer. Since then, wave springs have been in the process of being perfected and can ~~currently~~ be substituted for most uses of compression springs, with cost-savings to be made in the long run, as they use less space than compression springs.	+	Wave springs are a relatively new invention compared to the 600-year-old compression spring. The first pseudo-wave-spring was stamped around fifty years ago as a flat washer. Since then, wave springs have been in the process of being perfected and they can now be substituted for most uses of compression springs, with cost-savings to be made in the long run, as they use less space than compression springs.

	= Types of wave springs =		= Types of wave springs =
Line 56:		Line 56:
	* Types of spring.		* Types of spring.

−	[[Category:Products_/_components]]	+	[[Category:Products_/_components]] [[Category:DCN_Product_Knowledge]]