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Critical shear deformation concentration

The primary consideration we are missing is that of crystal imperfections. Recall from Section 1.1.4 that virtually all crystals contain some concentration of defects. In particular, the presence of dislocations causes the actual critical shear stress to be much smaller than that predicted by Eq. (5.17). Recall also that there are three primary types of dislocations edge, screw, and mixed. Althongh all three types of dislocations can propagate through a crystal and result in plastic deformation, we concentrate here on the most common and conceptually most simple of the dislocations, the edge dislocation. [Pg.392]

The moment-resisting frame (MRF, a combination of slender beams and columns, was the first type of steel structural system used and which showed excellent seismic behavior (Fig. 5). In a pure moment-resisting frame (MRF, Fig. 13a), the lateral deformations are to be accommodated primarily by bending of the beams and columns, shear deformation of the panel zone, and the formation of plastic hinges, or areas of concentrated plasticity, in the beams. The yielding of the beam steel and the formation of a plastic hinge are shown by the flaking of the whitewash in the critical section of the beam in Fig. 14. All of these deformation mechanisms can... [Pg.3425]

Above a critical hller concentration, the percolation threshold, the properties of the reinforced rubber material change drastically, because a hller-hUer network is estabhshed. This results, for example, in an overproportional increase of electrical conductivity of a carbon black-hUed compound. The continuous disruption and restorahon of this hller network upon deformation is well visible in the so-called Payne effect [20,21], as represented in Figure 29.5. It illustrates the strain-dependence of the modulus and the strain-independent contributions to the complex shear or tensUe moduli for carbon black-hlled compounds and sUica-hUed compounds. [Pg.805]

In the model of Agarwal and Khakhar [57] the polymer molecules are taken to be bead-rod chains with the hydrodynamic forces concentrated at the beads. The chains may bend about a bead, and a spring force acts to restore the chain to is equilibrium conformation, which is a straight chain. The connecting rods are inextensible. The system is confined to a plane, and the chains diffuse due to Brownian forces resisted by hydrodynamic forces. Hydrodynamic forces resulting from an imposed shear flow deform and orient the molecules. Two chains may react and combine to form a longer chain if the chain ends approach to within the capture radius (a) and if the angle between the chains is less than the critical value (0 ). The reaction is assumed to be very fast (kfj k j ) so that every collision that satisfies the above criteria results in... [Pg.804]

The microrheology makes it possible to expect that (i) The drop size is influenced by the following variables viscosity and elasticity ratios, dynamic interfacial tension coefficient, critical capillarity number, composition, flow field type, and flow field intensity (ii) In Newtonian liquid systems subjected to a simple shear field, the drop breaks the easiest when the viscosity ratio falls within the range 0.3 < A- < 1.5, while drops having A- > 3.8 can not be broken in shear (iii) The droplet breakup is easier in elongational flow fields than in shear flow fields the relative efficiency of the elongational field dramatically increases for large values of A, > 1 (iv) Drop deformation and breakup in viscoelastic systems seems to be more difficult than that observed for Newtonian systems (v) When the concentration of the minor phase exceeds a critical value, ( ) >( ) = 0.005, the effect of coalescence must be taken into account (vi) Even when the theoretical predictions of droplet deformation and breakup... [Pg.498]

Some authors report the next guide principles that may be applied for blend morphology after processing, (i) Drops with viscosity ratios higher than 3.5 cannot be dispersed in shear but can be in extension flow instead, (ii) The larger the interfacial tension coefficient, the less the droplets will deform, (iii) The time necessary to break up a droplet (Tj,) and the critical capillary number (Ca ) are two important parameters describing the breakup process, (iv) The effect of coalescence must be considered even for relatively low concentrations of the dispersed phase. [Pg.515]

In rubber-toughened epoxy resin materials, the particles act in the usual way as stress concentrators which initiate shear yielding of the matrix and give rise to increases in the critical size of the deformation zone. The particles first cavitate and then dilate during further deformation of the material. There is clear experimental evidence that cavitation of the rubber occurs first and is followed by shear yielding of the epoxy matrix [84,85,102,122], this being interpreted in terms of the need to relieve local constraint in the matrix before shear yielding and plastic deformation of the matrix can occur. The necessity for particle... [Pg.354]


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Critical concentration

Critical deformation

Deformations shearing

Shear critical

Shear deformation

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