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High thermal effect

The frequency correlation lowers environmental disturbances. The correlation provides an output proportional to the content of Aa at the reference signal fundamental frequency, the phase conelation gives the sign of Aa. Where the stress gradients are very steep in materials of high thermal conductivity being loaded at low frequencies, the SPATE signals are attenuated and a correction factor has to be introduced to take into account this effect. [Pg.410]

If and when these difficulties can be overcome, the way will be opened to the employment of adsorptives which have a vapour pressure high enough to enable their isotherms to be measured at temperatures close to ambient. This would substantially reduce the effect of thermal leakage and with it the distortion of the isotherm in the region near saturation. [Pg.167]

Heat/Solvent Recovery. The primary appHcation of heat pipes in the chemical industry is for combustion air preheat on various types of process furnaces which simultaneously increases furnace efficiency and throughput and conserves fuel. Advantages include modular design, isothermal tube temperature eliminating cold corner corrosion, high thermal effectiveness, high reHabiHty and options for removable tubes, alternative materials and arrangements, and replacement or add-on sections for increased performance (see Furnaces, fuel-FIREd). [Pg.514]

Many polymer films, eg, polyethylene and polyacrylonitrile, are permeable to carbon tetrachloride vapor (1). Carbon tetrachloride vapor affects the explosion limits of several gaseous mixtures, eg, air-hydrogen and air-methane. The extinctive effect that carbon tetrachloride has on a flame, mainly because of its cooling action, is derived from its high thermal capacity (2). [Pg.530]

Heat Sensitivity. The heat sensitivity or polymerization tendencies of the materials being distilled influence the economics of distillation. Many materials caimot be distilled at their atmospheric boiling points because of high thermal degradation, polymerization, or other unfavorable reaction effects that are functions of temperature. These systems are distilled under vacuum in order to lower operating temperatures. For such systems, the pressure drop per theoretical stage is frequently the controlling factor in contactor selection. An exceUent discussion of equipment requirements and characteristics of vacuum distillation may be found in Reference 90. [Pg.175]

Interrupting fault currents that are mostly inductive (Section 13.4.1) and occur at very low power factors. They are excessive in magnitude, and cause high thermal effects and electromagnetic forces on the arc chamber, the contacts and the contact mounting supports. [Pg.632]

EFFECTS OF THERMAL, PHOTOCHEMICAL AND HIGH-ENERGY RADIATION... [Pg.96]

The performance of these novel plants may be assessed in relation to two objectives— the attainment of good performance (high thermal efficiency and low cost of electricity produced) and the effectiveness of CO2 removal, although the two may be coupled if a CO-) tax is introduced. [Pg.162]

At 300°C and in the presence of KOH an increase in the molecular weight is observed, i.e., the reaction of macropolymerization is realized [38,39]. Potassium hydroxide is effectively inhibiting thermal destruction of polyethylene at temperatures from 350-375°C. The per cent change in molecular weight is half or one-third as high as that without the use of an inhibitor. At 400°C the efficiency of inhibition is insignificant. Potassium hydroxide with an ABC carrier is effective up to the temperature of 440°C due to the increased contact surface of the inhibitor with macroradicals. [Pg.84]

Many micro-channel blocks have a high thermal conductivity and conjugate effects may become important. In this chapter we considered analytical and experi-... [Pg.341]

Heat dissipation can be effectively dealt with by using substrate materials such as aluminum nitride, beryllia and, more recently, diamond which combine electrical insulation with high thermal conductivity. The relevant properties of these three materials are shown in Table 14.1. [Pg.375]

Industrial Processes with a High Thermal Effect... [Pg.194]

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See also in sourсe #XX -- [ Pg.194 ]



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Effects of Thermal, Photochemical and High-energy Radiation

Industrial Processes with a High Thermal Effect

Industrial high thermal effect

Thermal effects

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