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MacroCrack

Plate Thickness. Thickness of the plate should always be specified as should the locations on the work where the thickness is to be measured. Generally, thicker deposits perform better, but there are notable exceptions. Mating parts, eg, fasteners having fine machine threads, are not usable if over plated. Machine-threads are usually plated to 10 p.m or less, depending on tolerances. Additionally, gold-plate over nickel does not solder well if too thick thus, gold is usually 1—2 pm or less. Chromium, plated for decorative purposes from the conventional chromic acid bath, tends to macrocrack above about 0.7—1.0 pm. [Pg.151]

TEG macrostructure differs from that of natural graphite it possesses abnormally high porosity and highly developed active surface (40-50 m2/g) (Figure 1). The performed thermochemical treatment leads to an essential exfoliation of graphite matrix with a formation of cellular structure. The thickness of cell s walls is equal to 20-25 nm. The surface of cell s walls contains a lot of macrocracks, outcrops of crystallites, etc. The thermochemical re-treatment was applied to enhance TEG dispersivity. [Pg.359]

We would agree that grinding should produce some macrocracks in the particles and that these macrocracks can open up previously closed-pore volume. This, in turn, will affect the kinetics of volatile matter release. [Pg.611]

If local stresses exceed the forces of cohesion between atoms or lattice molecules, the crystal cracks. Micro- and macrocracks have a pronounced influence on the course of chemical reactions. We mention three different examples of technical importance for illustration. 1) The spallation of metal oxide layers during the high temperature corrosion of metals, 2) hydrogen embrittlement of steel, and 3) transformation hardening of ceramic materials based on energy consuming phase transformations in the dilated zone of an advancing crack tip. [Pg.331]

One can state that in the case of moistened capillary-porous materials the friction between grains, moisture movement, grain reformulation and micro-and macrocrack formations all create the sources for emission of acoustic signals. The intensity of acoustic signals, their number and energy, may be used... [Pg.349]

At intermediate concentrations of fibres (10 and 20 wt%), fracture initiates first by the formation of a frontal damage zone (microvoids at fibre ends, fibre decohesion, microrupture of the matrix) and then by a stable growth of microcracks and their junction into a macrocrack which propagates catastrophically (types 2 and 2 loading curves in Table II, associated with Figures lOA and IOC, lOD respectively). [Pg.409]

The liquid glass used as a binder in SPC contains 50%-60% water. With such a high water content of silicates solutions, the shrinkage strains arising during syn-eresis and removal of capillary moisture, lead to a reduction of the volume of material and the formation of micro- and macrocracks, especially at the binder-hller contact areas. [Pg.140]

As mentioned previously, cracks start in the brittle fracture mechanism by the counter process, which includes the birth and development of cracks in the area of prefailure and its association with the macrocrack. Further development of the macrocrack, [13] further development of the microcrack is, perhaps, due to two alternative mechanisms. [Pg.142]

The second possible mechanism of cracking is based on the following ideas. After the unification of microcracks with a macrocrack, continuous dynamic development of the macrocrack occurs without noticeable plastic deformation at the tip of rapidly developing cracks (not enough time to implement relaxation processes in the top). [Pg.142]

Thus, the development of brittle fracture does not occur on a counter mechanism (as opposed to the start of brittle fracture), and is directly related to the growth of the main crack (macrocrack). By this means the possibility exists to use the concept of fracture mechanics, which reduces to the solution of the left-hand side of the formulas (3.9) and (3.10) (the parameters K, G, depending on the mode of loading design), and the right—the critical values that characterize the material s properties. [Pg.143]

Figure 5.28 Cross-sectional SEM images of vacuum-plasma sprayed (VPS) coatings type Cl (a) and C2 (b) after immersion in HBSS for 7 days, showing a network of microcracks and debonding along macrocracks parallel to the interface (Vu and Heimann, 1996). Figure 5.28 Cross-sectional SEM images of vacuum-plasma sprayed (VPS) coatings type Cl (a) and C2 (b) after immersion in HBSS for 7 days, showing a network of microcracks and debonding along macrocracks parallel to the interface (Vu and Heimann, 1996).
The creation of a stress field in a two-phase brittle matrix material can be exploited for toughening since it will induce microcracks on application of an external load. Microcracks are created at the vicinity of the tip of a macrocrack forming a process zone [130], Using this mechanism, the elastic modulus within the process zone is reduced, the stress intensity at the crack tip is lowered and the toughness is increased. [Pg.500]

See other pages where MacroCrack is mentioned: [Pg.152]    [Pg.339]    [Pg.696]    [Pg.63]    [Pg.152]    [Pg.115]    [Pg.211]    [Pg.211]    [Pg.231]    [Pg.107]    [Pg.299]    [Pg.68]    [Pg.533]    [Pg.534]    [Pg.131]    [Pg.405]    [Pg.407]    [Pg.408]    [Pg.142]    [Pg.142]    [Pg.259]    [Pg.152]    [Pg.53]    [Pg.327]    [Pg.367]    [Pg.491]    [Pg.174]    [Pg.356]    [Pg.3]    [Pg.4]    [Pg.3]    [Pg.287]   
See also in sourсe #XX -- [ Pg.696 ]

See also in sourсe #XX -- [ Pg.341 , Pg.349 , Pg.356 , Pg.373 ]



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