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Work hardening, or strain hardening, is an increase in mechanical strength due to plastic deformation. In metallic solids, permanent change of shape is usually carried out on a microscopic scale by defects called dislocations which are created by stress and rearrange the material by moving through it. At low temperature, these defects do not anneal out of the material, but build up as the material is worked, interfering with one another's motion; strength is increased thereby, and ductility decreased by considerable amount. Strength of materials is materials science applied to the study of engineering materials and their mechanical behavior in general (such as stress, deformation, strain and stress-strain relations). ...
For other uses, see Plasticity. ...
In materials science, a dislocation is a crystallographic defect, or irregularity, within a crystal structure. ...
Stress is the internal distribution of force per unit area that balances and reacts to external loads applied to a body. ...
Annealing, in metallurgy and materials science, is a heat treatment wherein the microstructure of a material is altered, causing changes in its properties such as strength and hardness. ...
Any material with a reasonably high melting point can be strengthened in this fashion. It is often exploited to harden alloys that are not amenable to heat treatment, including low-carbon steel. Conversely, since the low melting point of indium makes it immune to work hardening at room temperature, it can be used as a gasket material in high-vacuum systems. The melting point of a crystalline solid is the temperature at which it changes state from solid to liquid. ...
Heat treatment is a method used to alter the physical, and sometimes chemical, properties of a material. ...
The steel cable of a colliery winding tower. ...
General Name, Symbol, Number indium, In, 49 Chemical series poor metals Group, Period, Block 13, 5, p Appearance silvery lustrous gray Standard atomic weight 114. ...
Some seals and gaskets 1. ...
Often, work hardening is carried out by the same process that shapes the metal into its final form, including cold rolling (contrast hot rolling) and cold drawing. Techniques have also been designed to maintain the general shape of the workpiece during work hardening, including shot peening and constant channel angular pressing. A material's work hardenability can be predicted by analyzing a stress-strain curve, or studied in context by performing a hardness test before and after the proposed cold work process. Rolling mill for cold rolling metal sheet like this piece of brass sheet. ...
Hot rolling is a metallurgical process in which the metal is passed through a pair of rolls and the temperature of the metal is above its recrystallization temperature, as opposed to cold rolling, which takes place below it. ...
Extrusion is a manufacturing process used to create long objects of a fixed cross-sectional profile. ...
Shot peening is a process used to produce a decorative finish and to modify mechanical properties of metals. ...
A stress-strain curve is a graph derived from measuring load (stress - σ) versus extension (strain - ε) for a sample of a material. ...
In materials science, hardness is the characteristic of a solid material expressing its resistance to permanent deformation. ...
Cold forming is a type of cold work that involves forging operations, such as extrusion, drawing or coining, that are performed at low temperatures. Cold work may also refer to the process through which a material is given this quality. Such deformation increases the concentration of dislocations which may subsequently form low-angle grain boundaries surrounding sub-grains. Cold work generally results in a higher yield strength as a result of the increased number of dislocations and the Hall-Petch effect of the sub-grains. However, there is a simultaneous decrease in the ductility. The effects of cold working may be removed by annealing the material at high temperatures where recovery and recrystallization reduce the dislocation density. A blacksmiths forge For finery forges (making iron) see finery forge. ...
Extrusion is a manufacturing process used to create long objects of a fixed cross-sectional profile. ...
Drawing is a manufacturing process for producing a wire, bar or tube by pulling on a material until it increases in length. ...
Coining is a form of precision stamping. ...
For the syntaxic operation, see Dislocation (syntax) For the medical term, see Dislocation (medicine) In materials science a dislocation is a linear crystallographic defect, or irregularity, in crystal structure. ...
Yield strength, or the yield point, is defined in engineering as the amount of strain that a material can undergo before moving from elastic deformation into plastic deformation. ...
The Hall-Petch relationship or Hall-Petch Law is a relation in materials science that deals with the connection between the grain size, or crystallite size, and the yield point of a material. ...
Ductility is the physical property of being capable of sustaining large plastic deformations without fracture (in metals, such as being drawn into a wire). ...
Annealing, in metallurgy and materials science, is a heat treatment wherein the microstructure of a material is altered, causing changes in its properties such as strength and hardness. ...
Recovery is a process by which deformed grains can reduce their stored energy by the removal or rearrangement of defects in their crystal structure. ...
Insulin crystals Recrystallization is an essentially physical process that has meanings in chemistry, metallurgy and geology. ...
Theory
Elastic and plastic deformation Work hardening occurs as a consequence of plastic deformation. A discussion of elastic deformation and plastic deformation must first be made. The discussion mostly involves metals, especially steels, which are well studied. The tensile test is a popular method to study deformation mechanisms. In physics and materials science, plasticity is a property of a material to undergo a non-reversible change of shape in response to an applied force. ...
In engineering mechanics, deformation is a change in shape due to an applied force. ...
In physics and materials science, plasticity is a property of a material to undergo a non-reversible change of shape in response to an applied force. ...
Hot metal work from a blacksmith In chemistry, a metal (Greek: Metallon) is an element that readily loses electrons to form positive ions (cations) and has metallic bonds between metal atoms. ...
The steel cable of a colliery winding tower. ...
Tensile stress (or tension) is the stress state leading to expansion (volume and/or length of a material tends to increase). ...
Elastic deformation is deforming a material only slightly with a minimum-smoothly-applied force. This only slightly stretches atomic bonds in the material away from their equilibrium radius of separation of a bond, while not applying so much energy as to break the inter-atomic bond completely. The deformation is recoverable. Plastic deformation is the act of deforming a material past its elastic limit. Atomic bonds break which, in smooth-controlled conditions, is accompanied first by permanent movement of dislocations. In engineering mechanics, deformation is a change in shape due to an applied force. ...
In physics and materials science, plasticity is a property of a material to undergo a non-reversible change of shape in response to an applied force. ...
The elastic limit is the maximum stress a material can undergo at which all strains are recoverable. ...
For the syntaxic operation, see Dislocation (syntax) For the medical term, see Dislocation (medicine) In materials science a dislocation is a linear crystallographic defect, or irregularity, in crystal structure. ...
Dislocations and lattice strain fields Dislocations are defined as irregularities in a crystal structure. They are surrounded by relatively strained bonds than in the regular crystal lattice. This is why these bonds break first in plastic deformation. The next step is the reformation of these bonds with alternate nearby atoms: to leave atoms unbonded altogether would be severely energetically unfavored. The end result is an alternate, but lower energy conformation within the applied strain. Dislocations are a "negative-entity" in that they do not exist: they are merely defects in the host medium which does exist. As such, the material itself does not move much. To a much greater extent visible "motion" is movement in a bonding pattern of largely stationary atoms. (Please see for further discussion: edge dislocation, screw dislocation) For the syntaxic operation, see Dislocation (syntax) For the medical term, see Dislocation (medicine) In materials science a dislocation is a linear crystallographic defect, or irregularity, in crystal structure. ...
Quartz crystal Synthetic bismuth hopper crystal Insulin crystals Gallium, a metal that easily forms large single crystals A huge monocrystal of potassium dihydrogen phosphate grown from solution by Saint-Gobain for the megajoule laser of CEA. In chemistry and mineralogy, a crystal is a solid in which the constituent atoms...
The ordinary meaning of lattice is the basis for several technical usages A cherry lattice pastry A mathematical lattice that is a type of partially ordered set. ...
This article is about the deformation of materials. ...
In materials science, a dislocation is a crystallographic defect, or irregularity, within a crystal structure. ...
In materials science, a dislocation is a crystallographic defect, or irregularity, within a crystal structure. ...
The strained bonds around a dislocation are described with the terminology of lattice strain fields. For example, there are compressively strained bonds directly next to an edge dislocation and tensilely strained bonds beyond the end of an edge dislocation. These form compressive strain fields and tensile strain fields respectively. Strain fields are like electric fields in some ways. Dislocations both form their own strain fields and are affected by the fields from other dislocations. In short, opposite fields attract and like fields repulse. In physics, an electric field or E-field is an effect produced by an electric charge that exerts a force on charged objects in its vicinity. ...
The visible (macroscopic) results of plastic deformation are the result of microscopic dislocation motion. Such as the stretching of a steel rod in a tensile tester. Macroscopic is commonly used to describe physical objects that are measurable and observable by the naked eye. ...
A microscope (Greek: micron = small and scopos = aim) is an instrument for viewing objects that are too small to be seen by the naked or unaided eye. ...
Increase of dislocations and work hardening Increase in the number of dislocations is a quantification of work hardening. Plastic deformation occurs as a consequence of work being done on a material; energy is added to the material. In addition, the energy is almost always applied fast enough and in large enough magnitude to not only move existing dislocations, but also to produce a great number of new dislocations by jarring or working the material sufficiently enough. In physics, mechanical work is the amount of energy transferred by a force. ...
Yield strength is increased in a cold-worked material. Using lattice strain fields, it can be shown that an environment filled with dislocations will hinder the movement of any one dislocation. Because dislocation motion is hindered, plastic deformation cannot occur at normal stresses. Upon application of stresses just beyond the yield strength of the non-cold-worked material, a cold-worked material will continue to deform using the only mechanism available: elastic deformation. The regular scheme of stretching or compressing of electrical bonds (without dislocation motion) continues to occur, and the modulus of elasticity is unchanged. Eventually the stress is great enough to overcome the strain-field interactions and plastic deformation resumes. Yield strength, or the yield point, is defined in engineering as the amount of strain that a material can undergo before moving from elastic deformation into plastic deformation. ...
Stress is the internal distribution of force per unit area that balances and reacts to external loads applied to a body. ...
In solid mechanics, Youngs modulus (also known as the modulus of elasticity or elastic modulus) is a measure of the Stiffness of a given material. ...
However, ductility of a work-hardened material is decreased. Ductility is the extent to which a material can undergo plastic deformation, that is, it is how far a material can be plastically deformed before fracture. A cold-worked material is, in effect, a normal material that has already been extended through part of its allowed plastic deformation. If dislocation motion and plastic deformation have been hindered enough by dislocation accumulation, and stretching of electronic bonds and elastic deformation have reached their limit, a third mode of deformation occurs: fracture. Ductility is the physical property of being capable of sustaining large plastic deformations without fracture (in metals, such as being drawn into a wire). ...
For fractures in geologic formations, see Rock fracture. ...
Example For an extreme example, in a tensile test a bar of steel is strained to just before the distance at which it usually fractures. The load is released smoothly and the material relieves some of its strain by decreasing in length. The decrease in length is called the elastic recovery, and the end result is a work-hardened steel bar. The fraction of length recovered (length recovered/original length) is equal to the yield-stress divided by the modulus of elasticity. (Here we discuss true stress in order to account for the drastic decrease in diameter in this tensile test.) The length recovered after removing a load from a material just before it breaks is equal to the length recovered after removing a load just before it enters plastic deformation. Tensile stress (or tension) is the stress state leading to expansion (volume and/or length of a material tends to increase). ...
Stress is the internal distribution of force per unit area that balances and reacts to external loads applied to a body. ...
The work-hardened steel bar has a large enough number of dislocations that the strain field interaction prevents all plastic deformation. Subsequent deformation requires a stress that varies linearly with the strain observed, the slope of the graph of stress vs. strain is the modulus of elasticity, as usual. Stress is the internal distribution of force per unit area that balances and reacts to external loads applied to a body. ...
This article is about the deformation of materials. ...
In solid mechanics, Youngs modulus (also known as the modulus of elasticity or elastic modulus) is a measure of the Stiffness of a given material. ...
The work-hardened steel bar fractures when the applied stress exceeds the usual fracture stress and the strain exceeds usual fracture strain. This may be considered to be the elastic limit and the yield stress is now equal to the fracture stress, which is of course, much higher than a non-work-hardened-steel yield stress. The elastic limit is the maximum stress a material can undergo at which all strains are recoverable. ...
Yield strength, or the yield point, is defined in engineering as the amount of strain that a material can undergo before moving from elastic deformation into plastic deformation. ...
The amount of plastic deformation possible is zero, which is obviously less than the amount of plastic deformation possible for a non-work-hardened material. Thus, the ductility of the cold-worked bar is drastically reduced. Ductility is the physical property of being capable of sustaining large plastic deformations without fracture (in metals, such as being drawn into a wire). ...
When a material under substantial and prolonged cavitation situation, the material also gets strain hardened.
Mathematical descriptions There are two common mathematical descriptions of the work hardening phenomenon. Hollomon's equation is a power law relationship between the stress and the amount of plastic strain εp. Ludwik's equation is similar but includes the yield stress σy  (Hollomon's)  (Ludwik's) where K is the strength index and n is the strain hardening index. The strain hardening exponent (also called strain hardening index), noted as n, is a materials constant which is used in calculations for stress-strain behaviour in work hardening. ...
If a material has been subjected to prior deformation (at low temperature) then the yield stress will be increased by a factor depending on the amount of prior plastic strain ε0
The constant K is structure dependent and is influenced by processing while n is a material property normally lying in the range 0.2-0.5. The strain hardening index can be described by:
 This equation can be evaluated from the slope of a log(σ) - log(ε) plot. Rearraging allows a determination of the rate of strain hardening at a given stress and strain 
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