fbpx
Wikipedia

Leaf spring

February 15, 2024

A leaf spring is a simple form of spring commonly used for suspension in wheeled vehicles. Originally called a laminated or carriage spring, and sometimes referred to as a semi-elliptical spring, elliptical spring, or cart spring, it is one of the oldest forms of vehicle suspension. A leaf spring is one or more narrow, arc-shaped, thin plates that are attached to the axle and chassis in a way that allows the leaf spring to flex vertically in response to irregularities in the road surface. Lateral leaf springs are the most commonly used arrangement, running the length of the vehicle and mounted perpendicular to the wheel axle, but numerous examples of transverse leaf springs exist as well.

A traditional semi-elliptical Hotchkiss leaf spring arrangement. On the left, the spring is connected to the frame through a shackle.

Leaf springs can serve multiple suspension functions: location, springing, and to some extent damping as well, through interleaf friction. However, this friction is not well controlled, resulting in stiction and irregular suspension motions. For this reason, some manufacturers have used mono-leaf springs.

Operation and basic design edit

 
Generic diagram of a leaf spring pack, without eyes; leaves are fastened together by the center bolt, midway along the length of the spring, and lateral alignment is enforced by multiple clips

A leaf spring takes the form of a slender arc-shaped length of spring steel of a rectangular cross-section. In the most common configuration, the center of the arc provides the location for the axle, while loops formed at either end provide for attaching to the vehicle chassis. For very heavy vehicles, a leaf spring can be made from several leaves stacked on top of each other in several layers, often with progressively shorter leaves. The longest leaf is also known as the main, master, or No. 1 leaf, with leaves numbered in descending order of length.[1]: 1–3  The eyes at the end of the leaf spring are formed into the master leaf.[2]: 6  In general, aside from the main leaf, the other leaves are tapered at each end.[2]: 8  Sometimes auxiliary or rebound leaves are part of the main spring pack, in which case the auxiliary leaf closest to the main leaf is No. 1, the next closest is No. 2, etc.[1]: 3  The leaves are attached to each other through the center bolt, which is at or near the mid-point along the length of the leaf spring.[2]: 8  To ensure that leaves remain aligned laterally, several methods can be used, including notches and grooves between leaves or external clips.[2]: 9–12 

Spring steels were discovered to be most efficient at approximately 1% carbon content.[2]: 13–15  Individual leaf thickness is specified by the Stubbs or Birmingham gauge, with typical thicknesses ranging between 0.203 to 0.375 in (5.2 to 9.5 mm) (6 to 3/8 or 00 gauge).[2]: 16  The material and dimensions should be selected such that each leaf is capable of being hardened to have a fully martensitic structure throughout the entire section. Suitable spring steel alloys include 55Si7, 60Si7, 65Si7, 50Cr4V2, and 60Cr4V2.[1]: 6 

Characteristics edit

 
Hotchkiss drive; each side of the rear axle is suspended by a leaf spring. The front eye of each leaf spring is attached to a bracket welded to the frame and the rear eye is attached to the frame using a shackle, which allows the spring to lengthen as it flexes.

The two ends of a leaf spring usually are formed into round eyes or eyelets, through which a fastener connects each end of the spring to the vehicle frame or body. Some springs terminated in a concave end, called a spoon end (seldom used now), to carry a swiveling member instead. One eye is usually fixed translationally but allowed to pivot with the motion of the spring, whereas the other eye is fastened to a hinge mechanism that allows that end to pivot as well as undergo limited translational movement. A leaf spring can either be attached directly to the frame at both eyes or attached directly at one end, usually the front, with the other end attached through a shackle, a short swinging arm. The shackle takes up the tendency of the leaf spring to elongate when compressed and thus makes the suspension softer. The shackle provides some degree of flexibility to the leaf spring so that it does not fail when subjected to heavy loads. The axle is usually fastened to the middle of the spring by U-bolts.[3]

The leaf spring acts as a linkage to hold the axle in position and thus separate linkages are not necessary. The result is a suspension that is simple and strong. Inter-leaf friction dampens the spring's motion and reduces rebound, which, until shock absorbers were widely adopted, was a very significant advantage over helical springs.[4] However, because the leaf spring is also serving to hold the axle in position, soft springs—i.e. springs with low spring constant—are not suitable. The consequent stiffness, in addition to inter-leaf friction, makes this type of suspension not particularly comfortable for the riders.[citation needed]

Types edit

 
Three-quarter-elliptic leaf spring on a carriage.

There are a variety of leaf springs, usually employing the word "elliptical". "Elliptical" or "full elliptical" leaf springs, patented in 1804 by the British inventor Obadiah Elliott, referred to two circular arcs linked at their tips. This was joined to the frame at the top center of the upper arc, the bottom center was joined to the "live" suspension components, such as a solid front axle. Additional suspension components, such as trailing arms, would usually be needed for this design, but not for "semi-elliptical" leaf springs as used in the Hotchkiss drive. That employed the lower arc, hence its name.

"Quarter-elliptic" springs often had the thickest part of the stack of leaves stuck into the rear end of the side pieces of a short ladder frame, with the free end attached to the differential, as in the Austin Seven of the 1920s. As an example of non-elliptic leaf springs, the Ford Model T had multiple leaf springs over its differential that were curved in the shape of a yoke. As a substitute for dampers (shock absorbers), some manufacturers laid non-metallic sheets in between the metal leaves, such as wood.

Elliot's invention revolutionized carriage design and construction, removing the need for a heavy perch and making transportation over rough roadways faster, easier, and less expensive.[5]

  • Examples of leaf springs
  •  
    Elliptic
  •  
    Semi-elliptic
  •  
    Three quarter-elliptic
  •  
    Quarter-elliptic
  •  
    Transverse
 
Tapered or parabolic leaf spring diagram

A more modern implementation is the parabolic leaf spring. This design is characterized by fewer leaves whose thickness varies from centre to ends following a parabolic curve. The intention of this design is to reduce inter-leaf friction, and therefore there is only contact between the leaves at the ends and at the centre, where the axle is connected. Spacers prevent contact at other points. Aside from weight-saving, the main advantage of parabolic springs is their greater flexibility, which translates into improved ride quality, which approaches that of coil springs; the trade-off is reduced load carrying capability. They are widely used on buses for improved comfort.

A further development by the British GKN company and by Chevrolet, with the Corvette, among others, is the move to composite plastic leaf springs. Nevertheless, due to the lack of inter-leaf friction and other internal dampening effects, this type of spring requires more powerful dampers/shock absorbers.

Typically when used in automobile suspension the leaf both supports an axle and locates/partially locates the axle. This can lead to handling issues (such as "axle tramp"), as the flexible nature of the spring makes precise control of the unsprung mass of the axle difficult. Some suspension designs use a Watts link (or a Panhard rod) and radius arms to locate the axle and do not have this drawback. Such designs can use softer springs, resulting in a better ride. Examples include the various rear suspensions of Austin-Healey 3000s and Fiat 128s.

History edit

 
17th-century coach spring in Lisbon Carriage Museum

The earliest known leaf springs began appearing on carriages in France in the mid-17th century in the form of the two-part elbow spring (as the illustrated example from Lisbon), and later migrated to England and Germany,[6] appearing on the carriages of the wealthy in those countries around 1750.[2]: 1  Dr. Richard Lovell Edgeworth was awarded three gold medals by the Society of English Arts and Manufacturers in 1768 for demonstrating the superiority of sprung carriages. By 1796, William Felton's A Treatise on Carriages and Harness[7] showed that leaf springs were being marketed regularly by the late 18th century carriage industry.[2]: 1 

Obadiah Elliot is credited with inventing the modern leaf spring with his 1804 patent on elliptical leaf springs, which brought him significant recognition and revenue, and engineers began studying leaf springs to develop improved designs and manufacturing processes. The mechanics and deflection of leaf springs were developed by Clark (1855), Franz Reuleaux (1861),[8] and G.R. Henderson (1894).[2]: 1 [9][10] Improved steel rolling processes, process instruments, and spring steel alloys were developed during the latter half of the 19th century as well, making the manufacture of leaf springs more consistent and less expensive.[2]: 2 

 
Leaf spring on a German locomotive built by Orenstein-Koppel and Lübecker Maschinenbau

Leaf springs were very common on automobiles until the 1970s when automobile manufacturers shifted primarily to front-wheel drive, and more sophisticated suspension designs were developed using coil springs instead. Today leaf springs are still used in heavy commercial vehicles such as vans and trucks, SUVs, and railway carriages. For heavy vehicles, they have the advantage of spreading the load more widely over the vehicle's chassis, whereas coil springs transfer it to a single point. Unlike coil springs, leaf springs also locate the rear axle, eliminating the need for trailing arms and a Panhard rod, thereby saving cost and weight in a simple live axle rear suspension. A further advantage of a leaf spring over a helical spring is that the end of the leaf spring may be guided along a definite path. In many late 1990s and early 2000s trucks, the leaf spring is connected to a Hinkle Beam ball joint.

  • Leaf springs used in independent suspensions
  •  
    Leaf-spring front independent suspension. Front-wheel-drive Alvis, 1928
  •  
    Independent front suspension by transverse leaf spring. Humber, 1935
  •  
    Independent front suspension by semi-elliptical springs. Mercedes Benz 230 W153, 1938

The leaf spring also has seen modern applications in cars. For example, the 1963 Chevrolet Corvette Sting Ray uses a transverse leaf spring for its independent rear suspension. Similarly, 2016 Volvo XC90 has a transverse leaf spring using composite materials for its rear suspension, similar in concept to the front suspension of the 1983 Corvette. This arrangement uses a straight leaf spring that is tightly secured to the chassis at the center; the ends of the spring are bolted to the wheel suspension, allowing the spring to work independently on each wheel. This suspension is smaller, flatter and lighter than a traditional setup.

Manufacturing process edit

Multi-leaf springs are made as follows

  1. Pre heat treatment process:
    1. Shearing
    2. Taper Rolling
    3. Trimming
    4. End cutting & pressing
    5. Second Warping
    6. Scarfing and Eye rolling
    7. Nipping
    8. C’SKG punching
    9. Center hole drilling.
  2. Heat treatment processes:
    1. Heating for hardening
    2. Cambering
    3. Quenching
    4. Tempering
  3. Post- heat treatment processes:
    1. Rectification
    2. Side bend removing
    3. Bushing
    4. Reaming
    5. Clamp riveting
  4. Assembly and surface finishes:
    1. Shot peening
    2. Painting
    3. Assembling
    4. Scragging
    5. Marking and packing

Heat treatment edit

  1. Heating for Hardening: Any metal, or alloy which can be hard drawn, or rolled to fairly high strength and retains sufficient ductility to form, may be used for springs, or any alloy which can be heat treated to high strength and good ductility before, or after forming may be used. For special spring properties such as good fatigue life, nonmagnetic characteristics, resistance to corrosion, elevated temperatures and drift require special considerations. leaves are heated to critical temperature in an Oil-fired hardening furnace. Usually temperature maintained is between 850°C and 950°C.
  2. Cambering: The top leaf is known as the master leaf. The eye is provided for attaching the spring with another machine member. The amount of bend that is given to the spring from the central line, passing through the eyes, is known as camber. The camber is provided so that even at the maximum load the deflected spring should not touch the machine member to which it is attached. The camber shown in the figure is known as positive camber. The central clamp is required to hold the leaves of the spring. Machine used for this operation is Hydraulic press. Leaves are bent to required radius using a press. All the leaves are tested for required radius using cambering gauges.
  3. Quenching : Hot bent leaves kept in tray and quenched in oil bath to get martensite structure. Martensite is the hardest form of steel crystalline structure. Martensite is formed in carbon steels by rapid cooling that is quenching of austenite form of iron. Machine used is conveyorized quench oil bath. Fire point of quenching oil is around 200°C and it is seen to that  temperature of oil does not exceed 80°C. After quenching the structure of leaf spring becomes very hard and this property is not required. But this process is required to set the leaves to correct radius after cambering. To remove hardness tempering is done.
  4. Tempering: Tempering is a process of heat treating, which is used to increase the toughness. Quenched leaves are reheated to drop hardness to required level. Electric heated temperature furnace is used for this process. Hardness of the leaves is found out using Brinell hardness testing. This process is also done to relieve stresses. Temperature inside the machine is maintained between 540 and 680°C. Tempering process involves heating of leaves below their re-crystallization temperature and then cooling them using water or air.

Other uses edit

By blacksmiths edit

Because leaf springs are made of relatively high quality steel, they are a favorite material for blacksmiths. In countries such as India, Nepal, Bangladesh, Philippines, Myanmar and Pakistan, where traditional blacksmiths still produce a large amount of the country's tools, leaf springs from scrapped cars are frequently used to make knives, kukris, and other tools.[11] They are also commonly used by amateur and hobbyist blacksmiths.

In trampolines edit

Leaf springs have also replaced traditional coil springs in some trampolines (known as soft-edge trampolines), which improves safety for users and reduces risk of concussion.[12] The leaf springs are spaced around the frame as 'legs' that branch from the base frame to suspend the jumping mat, providing flexibility and resilience.[13]

Clutches edit

The "diaphragm" common in automotive clutches is a type of leaf spring.

See also edit

References edit

  1. ^ a b c "IS 1135(1995): Leaf Springs Assembly for Automobiles". Bureau of Indian Standards. 1995. Retrieved 13 October 2022.
  2. ^ a b c d e f g h i j Leaf Springs: Their Characteristics and Methods of Specification. Wilkesbarre, PA: Sheldon Axle Company. 1912.
  3. ^ Stockel, Martin W.; Stockel, Martin T.; Johanson, Chris (1996). Auto Fundamentals. Tinley Park: The Goodheart-Willcox Company, Inc. p. 455. ISBN 1566371384.
  4. ^ "Springs – A simple study of car suspension". The Automotor Journal: 936–937. August 10, 1912.
  5. ^ "Carriages and Coaches". p. 205.
  6. ^ Terrier, Max (1986). "L'invention des ressorts de voiture". Revue d'Histoire des Sciences. 39 (1): 17–30. doi:10.3406/rhs.1986.4016.
  7. ^ Felton, William (1796). A treatise on carriages; comprehending coaches, chariots, phaetons, curricles, whiskies, &c. : together with their proper harness, in which the fair prices of every article are accurately stated.
  8. ^ Reuleaux, Franz (1861). Der Konstrukteur. Braunschweig: F. Vieweg. Retrieved 13 October 2022.
  9. ^ Rowland, E.K. (1911). "Leaf Springs". Transactions. Society of Automobile Engineers. 6: 156–191. JSTOR 44579553.
  10. ^ Henderson, G.R. (1894). "A Graphical Method of Designing Springs". Transactions. American Society of Mechanical Engineers. XVI: 92–105. Retrieved 13 October 2022.
  11. ^ "Kamis, Khukuri makers of Nepal". Himalayan-imports.com. Retrieved 2011-11-06.
  12. ^ "Joe Andon's leap of faith". The Australian. Retrieved 2013-07-04.
  13. ^ "Trampolines WO 2012167300 A1". Retrieved 2013-07-04.

External links edit

 
Wikimedia Commons has media related to Leaf springs.

February 15, 2024
leaf, spring, leaf, spring, simple, form, spring, commonly, used, suspension, wheeled, vehicles, originally, called, laminated, carriage, spring, sometimes, referred, semi, elliptical, spring, elliptical, spring, cart, spring, oldest, forms, vehicle, suspensio. A leaf spring is a simple form of spring commonly used for suspension in wheeled vehicles Originally called a laminated or carriage spring and sometimes referred to as a semi elliptical spring elliptical spring or cart spring it is one of the oldest forms of vehicle suspension A leaf spring is one or more narrow arc shaped thin plates that are attached to the axle and chassis in a way that allows the leaf spring to flex vertically in response to irregularities in the road surface Lateral leaf springs are the most commonly used arrangement running the length of the vehicle and mounted perpendicular to the wheel axle but numerous examples of transverse leaf springs exist as well A traditional semi elliptical Hotchkiss leaf spring arrangement On the left the spring is connected to the frame through a shackle Leaf springs can serve multiple suspension functions location springing and to some extent damping as well through interleaf friction However this friction is not well controlled resulting in stiction and irregular suspension motions For this reason some manufacturers have used mono leaf springs Contents 1 Operation and basic design 1 1 Characteristics 1 2 Types 2 History 3 Manufacturing process 3 1 Heat treatment 4 Other uses 4 1 By blacksmiths 4 2 In trampolines 4 3 Clutches 5 See also 6 References 7 External linksOperation and basic design edit nbsp Generic diagram of a leaf spring pack without eyes leaves are fastened together by the center bolt midway along the length of the spring and lateral alignment is enforced by multiple clipsA leaf spring takes the form of a slender arc shaped length of spring steel of a rectangular cross section In the most common configuration the center of the arc provides the location for the axle while loops formed at either end provide for attaching to the vehicle chassis For very heavy vehicles a leaf spring can be made from several leaves stacked on top of each other in several layers often with progressively shorter leaves The longest leaf is also known as the main master or No 1 leaf with leaves numbered in descending order of length 1 1 3 The eyes at the end of the leaf spring are formed into the master leaf 2 6 In general aside from the main leaf the other leaves are tapered at each end 2 8 Sometimes auxiliary or rebound leaves are part of the main spring pack in which case the auxiliary leaf closest to the main leaf is No 1 the next closest is No 2 etc 1 3 The leaves are attached to each other through the center bolt which is at or near the mid point along the length of the leaf spring 2 8 To ensure that leaves remain aligned laterally several methods can be used including notches and grooves between leaves or external clips 2 9 12 Spring steels were discovered to be most efficient at approximately 1 carbon content 2 13 15 Individual leaf thickness is specified by the Stubbs or Birmingham gauge with typical thicknesses ranging between 0 203 to 0 375 in 5 2 to 9 5 mm 6 to 3 8 or 00 gauge 2 16 The material and dimensions should be selected such that each leaf is capable of being hardened to have a fully martensitic structure throughout the entire section Suitable spring steel alloys include 55Si7 60Si7 65Si7 50Cr4V2 and 60Cr4V2 1 6 Characteristics edit nbsp Hotchkiss drive each side of the rear axle is suspended by a leaf spring The front eye of each leaf spring is attached to a bracket welded to the frame and the rear eye is attached to the frame using a shackle which allows the spring to lengthen as it flexes The two ends of a leaf spring usually are formed into round eyes or eyelets through which a fastener connects each end of the spring to the vehicle frame or body Some springs terminated in a concave end called a spoon end seldom used now to carry a swiveling member instead One eye is usually fixed translationally but allowed to pivot with the motion of the spring whereas the other eye is fastened to a hinge mechanism that allows that end to pivot as well as undergo limited translational movement A leaf spring can either be attached directly to the frame at both eyes or attached directly at one end usually the front with the other end attached through a shackle a short swinging arm The shackle takes up the tendency of the leaf spring to elongate when compressed and thus makes the suspension softer The shackle provides some degree of flexibility to the leaf spring so that it does not fail when subjected to heavy loads The axle is usually fastened to the middle of the spring by U bolts 3 The leaf spring acts as a linkage to hold the axle in position and thus separate linkages are not necessary The result is a suspension that is simple and strong Inter leaf friction dampens the spring s motion and reduces rebound which until shock absorbers were widely adopted was a very significant advantage over helical springs 4 However because the leaf spring is also serving to hold the axle in position soft springs i e springs with low spring constant are not suitable The consequent stiffness in addition to inter leaf friction makes this type of suspension not particularly comfortable for the riders citation needed Types edit nbsp Three quarter elliptic leaf spring on a carriage There are a variety of leaf springs usually employing the word elliptical Elliptical or full elliptical leaf springs patented in 1804 by the British inventor Obadiah Elliott referred to two circular arcs linked at their tips This was joined to the frame at the top center of the upper arc the bottom center was joined to the live suspension components such as a solid front axle Additional suspension components such as trailing arms would usually be needed for this design but not for semi elliptical leaf springs as used in the Hotchkiss drive That employed the lower arc hence its name Quarter elliptic springs often had the thickest part of the stack of leaves stuck into the rear end of the side pieces of a short ladder frame with the free end attached to the differential as in the Austin Seven of the 1920s As an example of non elliptic leaf springs the Ford Model T had multiple leaf springs over its differential that were curved in the shape of a yoke As a substitute for dampers shock absorbers some manufacturers laid non metallic sheets in between the metal leaves such as wood Elliot s invention revolutionized carriage design and construction removing the need for a heavy perch and making transportation over rough roadways faster easier and less expensive 5 Examples of leaf springs nbsp Elliptic nbsp Semi elliptic nbsp Three quarter elliptic nbsp Quarter elliptic nbsp Transverse nbsp Tapered or parabolic leaf spring diagramA more modern implementation is the parabolic leaf spring This design is characterized by fewer leaves whose thickness varies from centre to ends following a parabolic curve The intention of this design is to reduce inter leaf friction and therefore there is only contact between the leaves at the ends and at the centre where the axle is connected Spacers prevent contact at other points Aside from weight saving the main advantage of parabolic springs is their greater flexibility which translates into improved ride quality which approaches that of coil springs the trade off is reduced load carrying capability They are widely used on buses for improved comfort A further development by the British GKN company and by Chevrolet with the Corvette among others is the move to composite plastic leaf springs Nevertheless due to the lack of inter leaf friction and other internal dampening effects this type of spring requires more powerful dampers shock absorbers Typically when used in automobile suspension the leaf both supports an axle and locates partially locates the axle This can lead to handling issues such as axle tramp as the flexible nature of the spring makes precise control of the unsprung mass of the axle difficult Some suspension designs use a Watts link or a Panhard rod and radius arms to locate the axle and do not have this drawback Such designs can use softer springs resulting in a better ride Examples include the various rear suspensions of Austin Healey 3000s and Fiat 128s History edit nbsp 17th century coach spring in Lisbon Carriage MuseumThe earliest known leaf springs began appearing on carriages in France in the mid 17th century in the form of the two part elbow spring as the illustrated example from Lisbon and later migrated to England and Germany 6 appearing on the carriages of the wealthy in those countries around 1750 2 1 Dr Richard Lovell Edgeworth was awarded three gold medals by the Society of English Arts and Manufacturers in 1768 for demonstrating the superiority of sprung carriages By 1796 William Felton s A Treatise on Carriages and Harness 7 showed that leaf springs were being marketed regularly by the late 18th century carriage industry 2 1 Obadiah Elliot is credited with inventing the modern leaf spring with his 1804 patent on elliptical leaf springs which brought him significant recognition and revenue and engineers began studying leaf springs to develop improved designs and manufacturing processes The mechanics and deflection of leaf springs were developed by Clark 1855 Franz Reuleaux 1861 8 and G R Henderson 1894 2 1 9 10 Improved steel rolling processes process instruments and spring steel alloys were developed during the latter half of the 19th century as well making the manufacture of leaf springs more consistent and less expensive 2 2 nbsp Leaf spring on a German locomotive built by Orenstein Koppel and Lubecker MaschinenbauLeaf springs were very common on automobiles until the 1970s when automobile manufacturers shifted primarily to front wheel drive and more sophisticated suspension designs were developed using coil springs instead Today leaf springs are still used in heavy commercial vehicles such as vans and trucks SUVs and railway carriages For heavy vehicles they have the advantage of spreading the load more widely over the vehicle s chassis whereas coil springs transfer it to a single point Unlike coil springs leaf springs also locate the rear axle eliminating the need for trailing arms and a Panhard rod thereby saving cost and weight in a simple live axle rear suspension A further advantage of a leaf spring over a helical spring is that the end of the leaf spring may be guided along a definite path In many late 1990s and early 2000s trucks the leaf spring is connected to a Hinkle Beam ball joint Leaf springs used in independent suspensions nbsp Leaf spring front independent suspension Front wheel drive Alvis 1928 nbsp Independent front suspension by transverse leaf spring Humber 1935 nbsp Independent front suspension by semi elliptical springs Mercedes Benz 230 W153 1938The leaf spring also has seen modern applications in cars For example the 1963 Chevrolet Corvette Sting Ray uses a transverse leaf spring for its independent rear suspension Similarly 2016 Volvo XC90 has a transverse leaf spring using composite materials for its rear suspension similar in concept to the front suspension of the 1983 Corvette This arrangement uses a straight leaf spring that is tightly secured to the chassis at the center the ends of the spring are bolted to the wheel suspension allowing the spring to work independently on each wheel This suspension is smaller flatter and lighter than a traditional setup Manufacturing process editMulti leaf springs are made as follows Pre heat treatment process Shearing Taper Rolling Trimming End cutting amp pressing Second Warping Scarfing and Eye rolling Nipping C SKG punching Center hole drilling Heat treatment processes Heating for hardening Cambering Quenching Tempering Post heat treatment processes Rectification Side bend removing Bushing Reaming Clamp riveting Assembly and surface finishes Shot peening Painting Assembling Scragging Marking and packingHeat treatment edit Heating for Hardening Any metal or alloy which can be hard drawn or rolled to fairly high strength and retains sufficient ductility to form may be used for springs or any alloy which can be heat treated to high strength and good ductility before or after forming may be used For special spring properties such as good fatigue life nonmagnetic characteristics resistance to corrosion elevated temperatures and drift require special considerations leaves are heated to critical temperature in an Oil fired hardening furnace Usually temperature maintained is between 850 C and 950 C Cambering The top leaf is known as the master leaf The eye is provided for attaching the spring with another machine member The amount of bend that is given to the spring from the central line passing through the eyes is known as camber The camber is provided so that even at the maximum load the deflected spring should not touch the machine member to which it is attached The camber shown in the figure is known as positive camber The central clamp is required to hold the leaves of the spring Machine used for this operation is Hydraulic press Leaves are bent to required radius using a press All the leaves are tested for required radius using cambering gauges Quenching Hot bent leaves kept in tray and quenched in oil bath to get martensite structure Martensite is the hardest form of steel crystalline structure Martensite is formed in carbon steels by rapid cooling that is quenching of austenite form of iron Machine used is conveyorized quench oil bath Fire point of quenching oil is around 200 C and it is seen to that temperature of oil does not exceed 80 C After quenching the structure of leaf spring becomes very hard and this property is not required But this process is required to set the leaves to correct radius after cambering To remove hardness tempering is done Tempering Tempering is a process of heat treating which is used to increase the toughness Quenched leaves are reheated to drop hardness to required level Electric heated temperature furnace is used for this process Hardness of the leaves is found out using Brinell hardness testing This process is also done to relieve stresses Temperature inside the machine is maintained between 540 and 680 C Tempering process involves heating of leaves below their re crystallization temperature and then cooling them using water or air Other uses editBy blacksmiths edit Because leaf springs are made of relatively high quality steel they are a favorite material for blacksmiths In countries such as India Nepal Bangladesh Philippines Myanmar and Pakistan where traditional blacksmiths still produce a large amount of the country s tools leaf springs from scrapped cars are frequently used to make knives kukris and other tools 11 They are also commonly used by amateur and hobbyist blacksmiths In trampolines edit Leaf springs have also replaced traditional coil springs in some trampolines known as soft edge trampolines which improves safety for users and reduces risk of concussion 12 The leaf springs are spaced around the frame as legs that branch from the base frame to suspend the jumping mat providing flexibility and resilience 13 Clutches edit The diaphragm common in automotive clutches is a type of leaf spring See also editBogie Carriage Car suspension Coil spring Corvette leaf spring Spring device Suspension lift Transverse leaf spring front suspensionReferences edit a b c IS 1135 1995 Leaf Springs Assembly for Automobiles Bureau of Indian Standards 1995 Retrieved 13 October 2022 a b c d e f g h i j Leaf Springs Their Characteristics and Methods of Specification Wilkesbarre PA Sheldon Axle Company 1912 Stockel Martin W Stockel Martin T Johanson Chris 1996 Auto Fundamentals Tinley Park The Goodheart Willcox Company Inc p 455 ISBN 1566371384 Springs A simple study of car suspension The Automotor Journal 936 937 August 10 1912 Carriages and Coaches p 205 Terrier Max 1986 L invention des ressorts de voiture Revue d Histoire des Sciences 39 1 17 30 doi 10 3406 rhs 1986 4016 Felton William 1796 A treatise on carriages comprehending coaches chariots phaetons curricles whiskies amp c together with their proper harness in which the fair prices of every article are accurately stated Reuleaux Franz 1861 Der Konstrukteur Braunschweig F Vieweg Retrieved 13 October 2022 Rowland E K 1911 Leaf Springs Transactions Society of Automobile Engineers 6 156 191 JSTOR 44579553 Henderson G R 1894 A Graphical Method of Designing Springs Transactions American Society of Mechanical Engineers XVI 92 105 Retrieved 13 October 2022 Kamis Khukuri makers of Nepal Himalayan imports com Retrieved 2011 11 06 Joe Andon s leap of faith The Australian Retrieved 2013 07 04 Trampolines WO 2012167300 A1 Retrieved 2013 07 04 External links edit nbsp Wikimedia Commons has media related to Leaf springs Retrieved from https en wikipedia org w index php title Leaf spring amp oldid 1191988810, wikipedia, wiki, book, books, library,

article

, read, download, free, free download, mp3, video, mp4, 3gp, jpg, jpeg, gif, png, picture, music, song, movie, book, game, games.