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Water drops

Facilities for the treatment and compression of gas have already been described in earlier sections. However, there are a number of differences in the specifications for injected gas that differ from those of export gas. Generally there are no technical reasons for specifications on hydrocarbon dew point control (injected gas will get hotter not cooler) although it may be attractive to remove heavy hydrocarbons for economic reasons. Basic liquid separation will normally be performed, and due to the high pressures involved it will nearly always be necessary to dehydrate the gas to avoid water drop out. [Pg.259]

For the latter purpose, dissolve the crystals in hot ethanol, and then add water drop by drop to the well-stirred solution until a line emulsion just appears then add more ethanol, also drop by drop, until the emulsion just redissolves. ow allow the solution to cool spontaneousK if the emulsion reappears, add a few drops of ethanol from time to time in order to keep the solution clear. Finally the o-nitrophenol separates in crystals, and the well-stirred mixture may now be cooled in ieewvater until crystallisation is complete. Filter, drain and diy either in an atmospheric desiccator, or by pressing between drying-paper. [Pg.172]

Aminoazobenzene is freely soluble in methylated spirit, although insoluble in water. For recrystallisation, therefore, dissolve the crude substance in boiling methylated spirit, remove from the water-bath, and then add water drop by drop until the solution becomes just cloudy owing to the separation of the solute replace the solution momentarily on the water-bath until the cloudiness disappears, and then at once remove the solution, and allow it to cool slowly. (Alternatively, the crude dry material can be reciystallised from carbon tetrachloride in the usual way.) Aminoazobenzene is thus obtained as yellowish-brown crystals, m.p. 126° yield, 5 g. [Pg.209]

Formation of bromostyrene. Dissolve 0-2 g. of cinnamic acid (or a cinnamate) in about 5 ml. of NagCOg solution. Add bromine-water drop by drop and note the rapid separation of bromostyrene, CjHjCHiCHBr, as a colourless oil, having a pleasant characteristic odour. [Pg.353]

If the m.p. is not quite satisfactory, dissolve the o-nitroplienol in hot alcohol (or methylated spirit) under reflux, add hot water drop by drop until a cloudiness just appears, and allow to cool spontaneously. Filter off the bright yellow crystals and diy between filter paper. [Pg.678]

Water drops condensed in the atmosphere have much larger dimensions than gas molecules hence they are subject to the interference phenomena mentioned at the end of the last section. This alters the color of the scattered light. Smoke and dust particles are also larger and may absorb as well. [Pg.677]

Verification of the microbial retention efficiency of the membrane filters may be undertaken using either Hquid or aerosol challenge tests. A Hquid challenge test is more stringent. Furthermore, this test can provide retention information for process conditions such as extreme moisture after sterilization or air entrained with water drops. A Hquid challenge is performed using a protocol similar to that described for Hquid filtration. [Pg.142]

U. Single water drop in air, liquid side coefficient / jy l/2 ki = 2 ), short contact times / J 1 lcontact times dp [T] Use arithmetic concentration difference. Penetration theory, t = contact time of drop. Gives plot for k a also. Air-water system. [lll]p.. 389... [Pg.615]

FIG. 6-60 Drag coefficient for water drops in air and air hiihhles in water. Standard drag curve is for rigid spheres. (From Clift, Grace, and Weher, Biih-hles. Drops and Particles, Academic, New York, 1978. )... [Pg.679]

Terminal velocities for water drops in air have been correlated by Berry and Pruager (J. Appl. Meteoml., 13, 108-113 [1974]) as... [Pg.680]

Theoretical possible heat removal per pound of air circulated in a cooling tower depends on the temperature and moisture content of air. An indication of the moisture content of the air is its wet-bulb temperature. Ideally, then, the wet-bulb temperature is the lowest theoretical temperature to which the water can be cooled. Practically, the cold-water temperature approaches but does not equal the air wet-bulb temperature in a coohng tower this is so because it is impossible to contact all the water with fresh air as the water drops through the wetted fill surface to the basin. The magnitude of approach to the wet-bulb temperature is dependent on tower design. Important factors are air-to-water contact time, amount of fill surface, and breakup of water into droplets. In actual practice, cooling towers are seldom designed for approaches closer than 2.8°C (5°F). [Pg.1162]

FIG. 17-56 Effect of drop diameter on time for complete evaporation of water drops. [Pg.1599]

The flux equation assumes constant temperature. As T rises, H rises slowly, but around 25°C the viscosity of water drops enough to produce about a 3 percent rise in flux per °C. [Pg.2035]

This heating prior to distillation obviates the necessity of intermediate isolation of the carbinol. The dehydration is evidenced by small explosions when the water drops on the hot reaction mixture. [Pg.33]

The condensing steam turbine has a relatively low thermal efficiency because about two-thirds of the steam enthalpy is lost to cooling water in the condenser. Expensive boiler feedwater treatment is required to remove chlorides, salts, and silicates, which can be deposited on the blades causing premature failure. The blades are already under erosion conditions because of water drops present in the condensing steam. Even with these disadvantages, the condensing turbine is still selected, especially in a process that requires very large compressor drivers and relatively low amounts of process steam. [Pg.283]

Another type of crossflow cooling tower is the wet-dry tower, which consists of a normal crossflow tower over which a few air coils are placed. The hot water is first cooled by an air cooled heat exchanger and then drops to the wet cooling tower where more cooling is obtained by the evaporative mechanism. Figures 5 and 6 provide examples. In contrast, deck-filled towers contain tiers of splash bars or decks to aid in the breakup of water drops to increase the total water surface and, subsequently, the evaporation rate. [Pg.72]

Cooling towers are commonly used for water cooling, but they can also be used for heat recovery from outlet air. If the water temperature is higher than the dewpoint of the air, water will cool in the tower. Cooling is caused by vaporization on the surface of the water drops. The vaporization energy comes from the inner energy of the water and in a certain phase, when the water temperature is lower than the dry bulb temperature of the air, also from the airflow. When the water temperature drops to near the air wet bulb temperature at the observation point,... [Pg.95]

FIGURE 4.1 8 W ter drop cooling in the air flow. Point (I) represents the air state surrounding the water drop (2). [Pg.97]

Vertical free fall of water drops, ft Gas phase Schmidt Number Absolute temperature, °R = °F + 460 Bulk water temperature, °F or tL, if specified Entering or inlet -water temperature, or at bottom of tower, °F... [Pg.410]

Note the resistivity of sea-water drops as the chlorinity and temperature rise and in open sea-water (chlorinity l9 /o) it varies from about 160 cm in the tropics to 350 cm in the Arctic. [Pg.1350]

A type of wind erosion analysis that has been extensively studied is the effect of water drop erosion on rapidly moving missile parts. [Pg.97]

The sensible heat recovered in the heat exchanger (assuming 100% efficiency in heat transfer and based on the residual BD water dropping from 220 °F down to 104 °F) is 116 Btu/lb. [Pg.97]

Surfactants have a hydrophilic side of the molecule that attaches to water, and a hydrophobic side of the molecule that avoids water. In the absence of oils, the hydrophobic side sticks out of the surface of the water drop. There is no longer any water at the surface to form a strong surface tension, so the water no longer beads up, but spreads. The hydrophobic end of the molecule is also free to attach to grease, fat, or oil on the surface, which aids in the spreading. [Pg.212]

Detection and result The chromatogram was dried in a stream of warm air and im-1 mersed in the dipping solution for 2 s. The excess water drops were then removed from the surface of the layer in a stream of cold air. The chromatogram was then intensively irradiated with UV light (mercury lamp St 41, distance from layer 5 cm). [Pg.195]

Figure 15.4 PLIF measurement of rhodamine in hanging water drops in octanol. (a) is unmatched and (b) and (c) are refractor-index-matched liquids using thin and thick laser sheets, respectively (From [10]). Figure 15.4 PLIF measurement of rhodamine in hanging water drops in octanol. (a) is unmatched and (b) and (c) are refractor-index-matched liquids using thin and thick laser sheets, respectively (From [10]).
The amount of calcium carbonate precipitating from any particular drop is imperceptibly small. Nevertheless, over the years, these deposits grow into translucent hollow tubes of CaC03 called soda straws (see photo inset). Soda straws lengthen as water drops fall from their tips. These delicate structures can reach lengths of several feet. In time, water flowing over the outside of the tube adds width to the growing formation, and the soda straw matures into the familiar stalactite. [Pg.1192]

See other pages where Water drops is mentioned: [Pg.250]    [Pg.337]    [Pg.356]    [Pg.268]    [Pg.263]    [Pg.97]    [Pg.679]    [Pg.680]    [Pg.1169]    [Pg.78]    [Pg.119]    [Pg.456]    [Pg.185]    [Pg.70]    [Pg.251]    [Pg.409]    [Pg.294]    [Pg.389]    [Pg.251]    [Pg.201]    [Pg.874]    [Pg.141]    [Pg.214]   
See also in sourсe #XX -- [ Pg.335 ]

See also in sourсe #XX -- [ Pg.233 , Pg.242 ]



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