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Cooling behavior

Pomini reported that their VIC technology combines the fair raw material intake behavior of the tangential mixer with the excellent dispersion and cooling behavior of an intermeshing mixer. [Pg.994]

In order to illustrate the fractionated crystallization behavior we will present here previous results on immiscible atactic PS and isotactic polypropylene blends (iPP) [68]. The cooling behavior of PS, iPP and an 80/20 PS/iPP blend is presented in Fig. 1, as well as that of an unmixed blend , labeled... [Pg.23]

To represent the module cooling behavior, it is convenient to define the heat dissipation capability as the ratio of total heat generated to the maximum temperature difference experienced by the switch assembly. This ratio can then be plotted as a fnnction of coolant flow rate to establish the operating range and functional safety margins. Reference [31] shows the heat dissipation capability of the heat sink assembly. [Pg.100]

Figure 1 shows the cooling behavior of neutron stars during the first one year after the explosion. The total luminosity of the surface photon radiation Lph (left) and the surface temperature Ts (right), both to be observed at infinity, are plotted as a function of time, for three nuclear models PS (stiff), FP (intermediate), and BPS (soft). The temperature scale refers to the FP model. [Pg.448]

Figure 7.10 The cooling behavior of a glass fusion specimen (a) too rapidly cooled results in a highly strained fusion bead (b) very slow cooling from the melt causes crystallization to occur, (c) ideal cooling behavior which includes a short thermal arrest at 500°C producing a tough, tempered fusion bead (d) intermediate-rate continuous cooling produces a satisfactory bead if conditions are controlled properly. Figure 7.10 The cooling behavior of a glass fusion specimen (a) too rapidly cooled results in a highly strained fusion bead (b) very slow cooling from the melt causes crystallization to occur, (c) ideal cooling behavior which includes a short thermal arrest at 500°C producing a tough, tempered fusion bead (d) intermediate-rate continuous cooling produces a satisfactory bead if conditions are controlled properly.
The development of thermocouple, as an accurate temperature measuring device, was rapidly followed by Osmond (1886) who investigated the heating and cooling behavior of iron and steel with a view to elucidating the effects of carbon so that he introduced thermal analysis to then most important field of metallurgy. Roberts-Austen (1891), however, is known to construct a device to give a continuous record of the output from thermocouple ands he termed it as Thermoelectric Pyrometer , see Fig. 77. [Pg.348]

Theoretical analysis and research for AC600/1000 passive containment cooling behavior... [Pg.132]

The steady cycle-averaged tenqrerature field within the mold may well rqrresent the overall cooling behavior via cooling chaimels during the process. The govoning equation is given by... [Pg.542]

See other pages where Cooling behavior is mentioned: [Pg.378]    [Pg.394]    [Pg.675]    [Pg.88]    [Pg.3249]    [Pg.676]    [Pg.289]    [Pg.249]    [Pg.32]    [Pg.154]    [Pg.215]    [Pg.75]    [Pg.84]    [Pg.299]    [Pg.1558]    [Pg.3067]   
See also in sourсe #XX -- [ Pg.133 , Pg.530 ]



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