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Fracture change

Examination of oven-aged samples has demonstrated that substantial degradation is limited to the outer surface (34), ie, the oxidation process is diffusion limited. Consistent with this conclusion is the observation that oxidation rates are dependent on sample thickness (32). Impact property measurements by high speed puncture tests have shown that the critical thickness of the degraded layer at which surface fracture changes from ductile to brittle is about 0.2 mm. Removal of the degraded layer restores ductiHty (34). Effects of embrittled surface thickness on impact have been studied using ABS coated with styrene—acrylonitrile copolymer (35). [Pg.203]

Forced drainage Rail fracture, change in tram current supply Locate failure, speak to traffic organization... [Pg.239]

Because of the difference in form between Eqs. (2) and (3), the mechanisms of deformation and fracture change with the state of stress. For example, polystyrene yields by shear band formation under ccm ression, but crazes and frachues in a brittle matmer under tensile loading. Chants in failure nwchanian with state of stress are e cially important in particulate conqx tes, since the second phase can alter the local state of stress in the surrounding matrix. [Pg.125]

Brittle-Ductile Transition The temperature at which the mode of fracture changes from brittle to ductile fracture. [Pg.1051]

In region II the mechanism of fracture changes from the reaction-rate-limited process of region I to a transport-rate-limited process. The reason is that the stress-activated process at the crack tip has become faster than the rate at which water vapor can diffuse to the crack tip. [Pg.198]

It is very important, from one hand, to accept a hypothesis about the material fracture properties before physical model building because general view of TF is going to change depending on mechanical model (brittle, elasto-plastic, visco-elasto-plastic, ete.) of the material. From the other hand, it is necessary to keep in mind that the material response to loads or actions is different depending on the accepted mechanical model because rheological properties of the material determine type of response in time. The most remarkable difference can be observed between brittle materials and materials with explicit plastic properties. [Pg.191]

The AUGUR information on defect configuration is used to develop the three-dimensional solid model of damaged pipeline weldment by the use of geometry editor. The editor options provide by easy way creation and changing of the solid model. This model is used for fracture analysis by finite element method with appropriate cross-section stress distribution and external loads. [Pg.196]

Sample Preservation Without preservation, many solid samples are subject to changes in chemical composition due to the loss of volatile material, biodegradation, and chemical reactivity (particularly redox reactions). Samples stored at reduced temperatures are less prone to biodegradation and the loss of volatile material, but fracturing and phase separations may present problems. The loss of volatile material is minimized by ensuring that the sample completely fills its container without leaving a headspace where gases can collect. Samples collected from materials that have not been exposed to O2 are particularly susceptible to oxidation reactions. For example, the contact of air with anaerobic sediments must be prevented. [Pg.198]

Polyamides, like other macromolecules, degrade as a result of mechanical stress either in the melt phase, in solution, or in the soHd state (124). Degradation in the fluid state is usually detected via a change in viscosity or molecular weight distribution (125). However, in the soHd state it is possible to observe the free radicals formed as a result of polymer chains breaking under the appHed stress. If the polymer is protected from oxygen, then alkyl radicals can be observed (126). However, if the sample is exposed to air then the radicals react with oxygen in a manner similar to thermo- and photooxidation. These reactions lead to the formation of microcracks, embrittlement, and fracture, which can eventually result in failure of the fiber, film, or plastic article. [Pg.230]

The tetrahedral network can be considered the idealized stmcture of vitreous siUca. Disorder is present but the basic bonding scheme is still intact. An additional level of disorder occurs because the atomic arrangement can deviate from the hiUy bonded, stoichiometric form through the introduction of intrinsic (stmctural) defects and impurities. These perturbations in the stmcture have significant effects on many of the physical properties. A key concern is whether any of these defects breaks the Si—O bonds that hold the tetrahedral network together. Fracturing these links produces a less viscous stmcture which can respond more readily to thermal and mechanical changes. [Pg.498]

When a pitch is tested for ductility, the sample either suffers britde fracture without elongation or elongates to the maximum distance without breaking. When tested at increased temperatures at a particular point, ie, the ductility point, the behaviour changes from the first type to the second. [Pg.342]

See other pages where Fracture change is mentioned: [Pg.111]    [Pg.389]    [Pg.872]    [Pg.152]    [Pg.1047]    [Pg.298]    [Pg.413]    [Pg.272]    [Pg.7151]    [Pg.88]    [Pg.208]    [Pg.341]    [Pg.251]    [Pg.111]    [Pg.389]    [Pg.872]    [Pg.152]    [Pg.1047]    [Pg.298]    [Pg.413]    [Pg.272]    [Pg.7151]    [Pg.88]    [Pg.208]    [Pg.341]    [Pg.251]    [Pg.358]    [Pg.517]    [Pg.260]    [Pg.4]    [Pg.257]    [Pg.258]    [Pg.452]    [Pg.547]    [Pg.547]    [Pg.341]    [Pg.435]    [Pg.111]    [Pg.200]    [Pg.202]    [Pg.203]    [Pg.320]    [Pg.189]    [Pg.499]    [Pg.509]    [Pg.356]    [Pg.371]    [Pg.206]    [Pg.369]    [Pg.273]   
See also in sourсe #XX -- [ Pg.121 ]



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