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EWA FO EACH FI

INITIA

LOCATIONIN CONSIDERATION

IFFERENTTHA CONFIGURATION

108

TUBE UBE

IN FORCEDCIRCULATION EVAPORATORS VAPORATOR OPERATING

CULATEDTO SELE CTTHE

WHERE

RATES ATE INSIDE TH

OTALSURFACEAREAT LARGER

FT2FT

FT2FT

SURFAC AREA

FT2FT

AVERAGETUBE WALL SURFACEFT2FT FIN THICKNESS HICKNES IN FACTO

W1

IN EQ 19

DEFINE

FACTOR USED IN TUBESIDE COEFFICIENTEVALUATION GAS SPECIFIC HEAT BTULBF CONSTANTS ONSTANT U SE D I N H EA T T RA NS FE R AN D PRESSURE DROP AL

C1 TO C6

PROCESS

CULATIONS ULATION TUBE OUTER AN

INNE

IN

ON

FIN EFFICIENCYFRACTION FRICTION FACTOR O UT SI D

CONVECTIV

TROL SYSTEMS YSTEM

TUBES UBE FT2HRFBTU

NONLUMINOUS O NL UM IN O

H0

THERMAL THERMAL

SAFETY VALVES

TRUEFAILSAFEBYDESIG

YSTEM

YSTEM THA TRIGGER WHEN AUTOMATIC SAFET SYSTEMS

CONDUCTIVITY GAS BTULFTHRF CONDUCTIVITYOF FI SUBSCRIP

REFERS EFER TOTUB

EFFECTIVE LENGTHOF TUBE FT FACTO

DEFINE

ACCURATE CONTROL OF EXTREMEL HIG

IN EQS

DEEP

ROWS OW

N UM BE R

O F TU BE S

DONT

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CONTROLS

MERCIAL

NUMBER REYNOLDS EYNOLD

R5

RADIUS

SYSTEMS

DARD

TUBES UBE BTUFT2HR

RE

RO

GAIN

PROCESSES ROCESSE

FIN DENSITY FINSIN

ND

OTHER SYSTEMS YSTE FAI ODE MULTIPLESHUTDOWN MODES

BESSEL FUNCTIONS UNCTION

RE

WITHOUTPROCESS ROCE CONTROLLER ONTROLLER

WITH

COEFFICIENTBTULFT2HRF H EA TT RA NS FE R COEFFICIENT TUFT2HRF

WALL

TO

25

OV

BESSEL FUNCTIONS UNCTIO FROMTABLE

1011

R1

ON

RELIABILIT

YSTEM IN OPERATION HUNDREDS UNDRED OF CRITICAL SAFETYSYSTEMS

HEATTRANSFER COEFFICIENT TUJFT2HRF

TUBESIDE HEATTRANSFE

HL

SPEED HIGH

VELOCITYLBFT2HR

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HEIGHT IN

FIN

VALVE CONTROLS ONTROL CALL

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FACTORS A CT O I NS ID E A N GAS

EPEND

CONTROLS ONTROL

SAFETY

ROCES

FIN SPACING IN

S1 S1

TRANSVERSE AND IN

TB

ITCH IN LONGITUDINAL

IRS

TEMPERATURE

FIN TIP TEMPERATURE GAS TEMPERATURE

TG

FLUID TEMPERATURENSIDE TUBES UBE GAS TEMPERATURE

TB

TIA LTT

AVERAGEFIN TEMPERATURE DIFFERENCE LOGMEAN TEMPERATURE

U5

OVERALLHEATTRANSFER COEFFICIENT ON

WG

GASFLOWLBHR

CIRCLE 11

EXTERNALSURFACEBASIS ASI

BTULFT2HRF

ITIT

FIN SERRATION WIDTH IN FLOW PER TUBE LBHR GAS VISCOSITY BFTHR

JI

IFI1

FIN EFFECTIVENESS FFECTIVENESFRACTION GAS DENSITYLBFT3

PG

CITED E SC O

FI

T UB EMANUAL ESCOA

GANAPATHY GANAPATHY GANAPATHY

W AS T

H EA T

CORP THISA OKLAHOM

BOILE DESKBO OK

FAIRMONT

1979

PRESS RE A TL AN T

1991

ALCULATIONNANUAL MARCEL DEKKERNEW YORK 1993 PLANTCALCULATIONS XCHAN GERAREFU LLY YDROCARBON E VA LU AT E E XT EN D E S UR FA C EXCHANGERS ROCESSING STEAM

OCTOBER1990 CTO ROCESSING GANAPATHY FOULINGTHE SILENT HEATTRANSFERHIEF HYDROCARBON BER 1992

THEAUTHOR SPECIALISTWITH

GANAPATHY

ABILENE

FHEAT RECOVERYBOLL NGAGEDI N T H ENGINEERING INCINERATION AN ERS CO GENERATION FORPROCESS ROCES

APPLICATIONS PPLICATION AND PACKAGED WATER TUBE STEA DEVELOPS EVELOP SOFTWARE FORENGI GENERATORS

NEERINGOF HEAT RECOVERY SYSTEMS YSTEM AND COMPO TECH DEGREE MECHANICAL NENTS OLD

ENGINEERINGFRO AN

INDIAN INSTITUTEOF TECHNOLOGYMADRAS

ADRA UNIVERSITYM R MSCENG IN BOILE TECHNOLOGYROM MADRAS

PATHYIS THE AUTHOROF OVER

17

ARTICLE RT IC LE SON

SJP1ULI1I

AND NA

MOYNO INDUSTRIAL

BOILERS OILER HEAT TRAN SFERAND

OOK HEA TRAN STEAM PLANTSYSTEM YSTEM N D H A WRITTENFIVE BOOKS PLANT CALCULATIONS ALCULATION FORSTEAM GEN OMOGRAM FERSTREAM MANUAL NOMOGRAMS ERATION AND UTILIZATIONBASIC

BOOK AND

DISKETTE AND

WHICH ARE AVAILABLE FROMHIM TERS O T 25 AND 26

P LA N ENGINEERS NGINEER PROGRAMS ROGRAM F O S TE A BOILER DESKBOOK COPIES HE OPIE OF HE ALSO HAS CONTRIBUTE SEVERA CHAP

OF CHEMICAL PROCESSINGAND DESIGN VOLS ENCYCLOPEDIA MARCEL DEKKER

PRODUCTS RODUCT II

UNIT OF ROBBINS OBBIN

L5I1RA5UI

96 CERTIFICATE

MYERS YER INC

SPRINGFIEL

TOI

WEBSITE

HTTPLLWWWMOYNOCOM CIRCLE 111

111