词条 | Fracture |
释义 |
A fracture is the separation of an object or material into two or more pieces under the action of stress. The fracture of a solid usually occurs due to the development of certain displacement discontinuity surfaces within the solid. If a displacement develops perpendicular to the surface of displacement, it is called a normal tensile crack or simply a crack; if a displacement develops tangentially to the surface of displacement, it is called a shear crack, slip band, or dislocation.[1] Brittle fractures occur with no apparent deformation before fracture; ductile fractures occur when visible deformation does occur before separation. Fracture strength or breaking strength is the stress when a specimen fails or fractures. A detailed understanding of how fracture occurs in materials may be assisted by the study of fracture mechanics. Fracture strengthFracture strength, also known as breaking strength, is the stress at which a specimen fails via fracture.[2] This is usually determined for a given specimen by a tensile test, which charts the stress–strain curve (see image). The final recorded point is the fracture strength. Ductile materials have a fracture strength lower than the ultimate tensile strength (UTS), whereas in brittle materials the fracture strength is equivalent to the UTS.[2] If a ductile material reaches its ultimate tensile strength in a load-controlled situation,{{#tag:ref|A simple load-controlled tensile situation would be to support a specimen from above, and hang a weight from the bottom end. The load on the specimen is then independent of its deformation.|group="Note"}} it will continue to deform, with no additional load application, until it ruptures. However, if the loading is displacement-controlled,{{#tag:ref|A simple displacement-controlled tensile situation would be to attach a very stiff jack to the ends of a specimen. As the jack extends, it controls the displacement of the specimen; the load on the specimen is dependent on the deformation.|group="Note"}} the deformation of the material may relieve the load, preventing rupture. TypesThere are two types of fractures : ===Brittle fracture=== In brittle fracture, no apparent plastic deformation takes place before fracture. Brittle fracture typically involves little energy absorption and occurs at high speeds—up to 2133.6 m/s (7000 ft/s) in steel.[4] In most cases brittle fracture will continue even when loading is discontinued.[5] In brittle crystalline materials, fracture can occur by cleavage as the result of tensile stress acting normal to crystallographic planes with low bonding (cleavage planes). In amorphous solids, by contrast, the lack of a crystalline structure results in a conchoidal fracture, with cracks proceeding normal to the applied tension. The theoretical strength of a crystalline material is (roughly) where: – is the Young's modulus of the material, is the surface energy, and is the equilibrium distance between atomic centers. On the other hand, a crack introduces a stress concentration modeled by (For sharp cracks) where: – is the loading stress, is half the length of the crack, and is the radius of curvature at the crack tip. Putting these two equations together, we get Looking closely, we can see that sharp cracks (small ) and large defects (large ) both lower the fracture strength of the material. Recently, scientists have discovered supersonic fracture, the phenomenon of crack propagation faster than the speed of sound in a material.[3] This phenomenon was recently also verified by experiment of fracture in rubber-like materials. The basic sequence in a typical brittle fracture is: introduction of a flaw either before or after the material is put in service, slow and stable crack propagation under recurring loading, and sudden rapid failure when the crack reaches critical crack length based on the conditions defined by fracture mechanics.[4] Brittle fracture may be avoided by controlling three primary factors: material fracture toughness (Kc), nominal stress level (σ), and introduced flaw size (a).[5] Residual stresses, temperature, loading rate, and stress concentrations also contribute to brittle fracture by influencing the three primary factors.[5] Under certain conditions, ductile materials can exhibit brittle behavior. Rapid loading, low temperature, and triaxial stress constraint conditions may cause ductile materials to fail without prior deformation.[5] Ductile fractureIn ductile fracture, extensive plastic deformation (necking) takes place before fracture. The terms rupture or ductile rupture describe the ultimate failure of ductile materials loaded in tension. Rather than cracking, the material "pulls apart," generally leaving a rough surface. In this case there is slow propagation and an absorption of a large amount of energy before fracture.[6] Because ductile rupture involves a high degree of plastic deformation, the fracture behavior of a propagating crack as modelled above changes fundamentally. Some of the energy from stress concentrations at the crack tips is dissipated by plastic deformation ahead of the crack as it propagates. The basic steps in ductile fracture are void formation, void coalescence (also known as crack formation), crack propagation, and failure, often resulting in a cup-and-cone shaped failure surface. Fracture modes and characteristics{{main|Fracture mechanics}}There are three standard conventions for defining relative displacements in elastic materials in order to analyze crack propagation[5] as proposed by Irwin.[7] In addition fracture can involve uniform strain or a combination of these modes.[4]
The manner in which a crack propagates through a material gives insight into the mode of fracture. With ductile fracture a crack moves slowly and is accompanied by a large amount of plastic deformation around the crack tip. A ductile crack will usually not propagate unless an increased stress is applied and generally cease propagating when loading is removed.[4] In a ductile material, a crack may progress to a section of the material where stresses are slightly lower and stop due to the blunting effect of plastic deformations at the crack tip. On the other hand, with brittle fracture, cracks spread very rapidly with little or no plastic deformation. The cracks that propagate in a brittle material will continue to grow once initiated. Crack propagation is also categorized by the crack characteristics at the microscopic level. A crack that passes through the grains within the material is undergoing transgranular fracture. A crack that propagates along the grain boundaries is termed an intergranular fracture. Typically, the bonds between material grains are stronger at room temperature than the material itself, so transgranular fracture is more likely to occur. When temperatures increase enough to weaken the grain bonds, intergranular fracture is the more common fracture mode.[4] Notable fracture failuresFailures caused by brittle fracture have not been limited to any particular category of engineered structure.[5] Though brittle fracture is less common than other types of failure, the impacts to life and property can be more severe.[5] The following notable historic failures were attributed to brittle fracture:
See also
Notes1. ^{{Citation |last= Cherepanov |first= G.P. |title= Mechanics of Brittle Fracture}} 2. ^1 {{Citation |last= Degarmo |first= E. Paul |last2= Black |first2= J T. |last3= Kohser |first3= Ronald A. |title= Materials and Processes in Manufacturing |publisher= Wiley |page= 32 |year= 2003 |edition= 9th |isbn= 0-471-65653-4 |postscript =.}} 3. ^{{cite journal |author1=C. H. Chen |author2=H. P. Zhang |author3=J. Niemczura |author4=K. Ravi-Chandar |author5=M. Marder |title=Scaling of crack propagation in rubber sheets |journal=Europhysics Letters |volume=96 |issue=3|pages=36009 |date=November 2011 |doi=10.1209/0295-5075/96/36009 |url=http://iopscience.iop.org/0295-5075/96/3/36009/|bibcode= 2011EL.....9636009C }} 4. ^1 2 3 4 5 6 7 {{cite book|last1=Campbell|first1=edited by F.C.|title=Fatigue and fracture : understanding the basics|date=2012|publisher=ASM International|location=Materials Park, Ohio|isbn=1615039767}} 5. ^1 2 3 4 5 6 7 8 9 {{cite book|last1=Rolfe|first1=John M. Barsom, Stanley T.|title=Fracture and fatigue control in structures : applications of fracture mechanics|date=1999|publisher=ASTM|location=West Conshohocken, Pa.|isbn=0803120826|edition=3.}} 6. ^{{cite book|last1=Perez|first1=Nestor|title=Fracture Mechanics|date=2016|publisher=Springer|isbn=3319249975|edition=2nd}} 7. ^{{cite book|last1=Jin|first1=C.T. Sun, Z.-H.|title=Fracture mechanics|date=2012|publisher=Academic Press|location=Waltham, MA|isbn=9780123850010}} References{{Reflist}}Further reading
External links
7 : Materials science|Building defects|Elasticity (physics)|Plasticity (physics)|Solid mechanics|Mechanics|Glass physics |
随便看 |
|
开放百科全书收录14589846条英语、德语、日语等多语种百科知识,基本涵盖了大多数领域的百科知识,是一部内容自由、开放的电子版国际百科全书。