Selective design

L. Theodore and A. J. Bwomzox., Air Pollution Control Equipment—Selection, Design, Operation and Maintenance, Prentice-Hall, Englewood CHffs, N.J., 1982. [Pg.419]

Special safety constraints apply to equipment selection, design, and operation in nuclear reprocessing (269). Equipment should be reHable and capable of remote control and operation for long periods with minimal maintenance. Pulsed columns and remotely operated mixer—settlers are commonly used (270). The control of criticaHty and extensive monitoring of contamination levels must be included in the process design. [Pg.80]

E. A. D. Saunders, Heat Exchangers Selection, Design, and Construction,]ohxi Wiley Sons, Inc., New York, 1988. [Pg.501]

DeioniZa.tlon, The removal of cations and anions from water and replacement of them with hydrogen and hydroxide ions is called deionization. The completeness of the ionic removal is dependent on resin selection, design of the system, operating conditions, and the quaUty of treated water required. In general, systems become more complex as quaUty requirements increase. [Pg.386]

G-7. Stern, Air Follution, 3d ed., vols. 3-5, Academic, Orlando, FL, 1976-77. G-8. Strauss, Industtial Gas Cleaning, 2d ed., Pergamon, New York, 1975. G-9. Theodore and Biionicore, Air Follution Control Equipment Selection, Design, Operation and Maintenance, Prentice Hall, Englewood Cliffs, NJ, 1982. [Pg.1427]

Failure of vacuum Design vessel to accommodate maximum system control vacuum (full vacuum rating) resulting in possi-. , elief system bility of vessel collapse pressure alarm and interlock to inert gas supply Select/design vacuum source to limit vacuum capability ASME VIII CCPS G-23 CCPS G-39... [Pg.79]

Theodore, L., and Buonicore, A. J, "Air Pollution Control Equipment Selection, Design, Operation and Maintenance." Prentice-Hall, Englewood Cliffs, NJ, 1982,... [Pg.487]

This chapter describes the basic principles and procedures for the evaluation of overpressure potential in plant equipment, and for the selection, design and specification of appropriate pressure relieving facilities. The design of closed safety valves and flare headers is included in this chapter, but blowdown drums and flares are covered separately. To properly discuss this subject, the reader should become familiar with the following terminology. [Pg.115]

This chapter discusses some of the criteria for selecting, designing and spacing elevated, burning-pit, and multijet flares. The design of safety valve and flare headers was covered in an earlier chapter, as well as discussions concerning associated blowdown drums, water disengaging drums, etc. [Pg.246]

Chemistry and Process Selection Design Scoping Regular Operation... [Pg.123]

System (node) Selection Design Intent Guide Words Cause Identification Consequence Identificatidn Resolution Review Record... [Pg.88]

V (separator) = Separator vapor velocity evaluated for the gas or vapor at flotving conditions, ft/sec V = Vapor velocity entering unit, lbs, per minute per square foot of inlet pipe cross section Va = Maximum allowable vapor velocity across inlet face of mesh calculated by relation, ft/sec Van Actual operating superficial gas velocity, ft/sec or ft/min, for tvire mesh pad Vu = Design vapor velocity (or selected design value), ft/sec... [Pg.285]

From the selected design hole velocity and the total rapor rate corresponding, the total number of holes can be determined for a given assumed hole diameter. [Pg.195]

The selected design Fj = 17 gives the number of holes to operate at these conditions. Note that the values of 1223 and 1410 holes for the top and bottom respectively indicated operations somewhat closer to the tower maximum than to the weep point. This usually insures as good an efficiency as is obtainable for a given system. It may limit the flexibility of the tower, since there will not be enough holes to operate down to the weep point at the given design flow rates. [Pg.199]

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