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Glasses brittleness

Glas-hafen, m. glass pot. -bahn, m. glass cook, glashart, a. hard as glass, brittle. [Pg.187]

Disadvantages of cyanoacrylate adhesives include poor thermal and moisture resistance on metals and glass, brittleness, sensitivity to surface preparation and poor cure through... [Pg.100]

In the area of moleculady designed hot-melt adhesives, the most widely used resins are the polyamides (qv), formed upon reaction of a diamine and a dimer acid. Dimer acids (qv) are obtained from the Diels-Alder reaction of unsaturated fatty acids. Linoleic acid is an example. Judicious selection of diamine and diacid leads to a wide range of adhesive properties. Typical shear characteristics are in the range of thousands of kilopascals and are dependent upon temperature. Although hot-melt adhesives normally become quite brittle below the glass-transition temperature, these materials can often attain physical properties that approach those of a stmctural adhesive. These properties severely degrade as the material becomes Hquid above the melt temperature. [Pg.235]

Fig. 13. Transition between ductile fracture and brittle fracture when Al QFe Gd metallic glass is aimealed at 170°C. Fig. 13. Transition between ductile fracture and brittle fracture when Al QFe Gd metallic glass is aimealed at 170°C.
Regaiding the glass-tiansition tempeiatuie, only the foui-iing bisphenol-PC (6) exhibits a lemarkable iaciease of T (220°C) over BPA-PC, but the high brittleness prohibits its use iu practical appHcations (195,196). [Pg.159]

In methacrylic ester polymers, the glass-transition temperature, is influenced primarily by the nature of the alcohol group as can be seen in Table 1. Below the the polymers are hard, brittle, and glass-like above the they are relatively soft, flexible, and mbbery. At even higher temperatures, depending on molecular weight, they flow and are tacky. Table 1 also contains typical values for the density, solubiHty parameter, and refractive index for various methacrylic homopolymers. [Pg.259]

Determination of the glass-transition temperature, T, for HDPE is not straightforward due to its high crystallinity (16—18). The glass point is usually associated with one of the relaxation processes in HDPE, the y-relaxation, which occurs at a temperature between —100 and —140° C. The brittle point of HDPE is also close to its y-transition. [Pg.380]

The dynamic mechanical properties of VDC—VC copolymers have been studied in detail. The incorporation of VC units in the polymer results in a drop in dynamic modulus because of the reduction in crystallinity. However, the glass-transition temperature is raised therefore, the softening effect observed at room temperature is accompanied by increased brittleness at lower temperatures. These copolymers are normally plasticized in order to avoid this. Small amounts of plasticizer (2—10 wt %) depress T significantly without loss of strength at room temperature. At higher levels of VC, the T of the copolymer is above room temperature and the modulus rises again. A minimum in modulus or maximum in softness is usually observed in copolymers in which T is above room temperature. A thermomechanical analysis of VDC—AN (acrylonitrile) and VDC—MMA (methyl methacrylate) copolymer systems shows a minimum in softening point at 79.4 and 68.1 mol % VDC, respectively (86). [Pg.434]

In cases where the copolymers have substantially lower glass-transition temperatures, the modulus decreases with increasing comonomer content. This results from a drop in crystallinity and in glass-transition temperature. The loss in modulus in these systems is therefore accompanied by an improvement in low temperature performance. However, at low acrylate levels (< 10 wt %), T increases with comonomer content. The brittle points in this range may therefore be higher than that of PVDC. [Pg.434]

Another polyolefin of interest is polystyrene, a clear, brittle plastic that, by itself, is rarely used in composites. However, several copolymers and alloys of polystyrene with acrylonitrile or butadiene have been used with fiber glass or glass spheres to form composites (7). [Pg.36]

T and are the glass-transition temperatures in K of the homopolymers and are the weight fractions of the comonomers (49). Because the glass-transition temperature is directly related to many other material properties, changes in T by copolymerization cause changes in other properties too. Polymer properties that depend on the glass-transition temperature include physical state, rate of thermal expansion, thermal properties, torsional modulus, refractive index, dissipation factor, brittle impact resistance, flow and heat distortion properties, and minimum film-forming temperature of polymer latex... [Pg.183]

One approach for ameliorating the highly brittle nature of these cements has involved the use of tougher, more ductile fillers (62,63). Another approach for improving the overall properties of traditional glass—ionomer cements involves the development of hybrid cement-composites and resin-modified cements (64—68). [Pg.473]

See other pages where Glasses brittleness is mentioned: [Pg.468]    [Pg.423]    [Pg.145]    [Pg.7]    [Pg.145]    [Pg.373]    [Pg.2226]    [Pg.215]    [Pg.468]    [Pg.423]    [Pg.145]    [Pg.7]    [Pg.145]    [Pg.373]    [Pg.2226]    [Pg.215]    [Pg.190]    [Pg.190]    [Pg.534]    [Pg.189]    [Pg.51]    [Pg.544]    [Pg.299]    [Pg.341]    [Pg.154]    [Pg.404]    [Pg.429]    [Pg.269]    [Pg.281]    [Pg.320]    [Pg.433]    [Pg.477]    [Pg.16]    [Pg.7]    [Pg.281]    [Pg.463]    [Pg.464]    [Pg.527]    [Pg.322]    [Pg.4]    [Pg.49]    [Pg.54]    [Pg.490]    [Pg.544]    [Pg.265]    [Pg.271]    [Pg.975]   
See also in sourсe #XX -- [ Pg.536 ]

See also in sourсe #XX -- [ Pg.536 ]



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