Fractionation and Absorption

Nomenclature used in the following examples, examples, from GPSA Chapter Chapter 19 at

tube flow area, ft2

at

total tube flow area, ft2

S S%

stripping f

A Ac

absorption factor for !" 19"2$

S-

separation

cross sectional area, ft2

%S

tra& spaci

At AA.

heat transfer area, ft2 tra& acti)e area, ft2

o)erall he specific )

A(.

tra& downcomer area, ft2

'( ) )max

A%.

tower cross sectional area, ft2

)i

specific )

b

exponent used in !s" 19"/ and 19"0

)o

specific )

*

bottoms product flowrate, mol+time

)apor rate,

C

coefficient for !" 19"11, ft+h

 1

CA-

)apor capacit& factor, corrected, ft+s

max

)olumetric

CA-3

)apor capacit& factor, uncorrected, ft+s

(dsg

downcom

C -S

)apor loading, ft#+s

(dsg

downcom

(

diameter, ft

load

)apor load

( (%

distillate product flowrate, mol+time

3

stripping

tower diameter, ft

w

weight flo

a

absorption efficienc&, !" 19"#3

x

li!uid mol

s

stripping efficienc&, !" 19"#2

li!uid rate,

f

friction factor, ft2+in2

4 4mD1

- p

feed rate, mol+time

x1

moles of a

pac5ing factor floodig factor for !" 19"16, usuall& 3"$2

43

moles of a )apor mol

--

number of

maximum

)apor rate

moles of a

--7 gc

flow path length, ft

& Ei

con)ersion factor, #2"168 ft lbm + lbf sec2

EnD1

moles of a

Gt

mass )elocit&, lb+h ft2

E3

moles of a

G p

tower )apor loading, lb+ ft2 s tower li!uid loading, gal+min enthalp&, *tu+lb height of pac5ing e!ui)alent to a theoretical plate height of a transfer unit e!uilibrium ? )alue, &+x

 : < = > @

static head relati)e )o )olatilit& f correlating surface te densit&, lb

li!uid reflux rate, mol+time



efficienc&

li!uid loading, lb+ ft2 s li!uid rate, mol+time

B

)iscocit&,

tube length, ft

Subscripts

rich oil entering stripper, mol+time number of stripping stages

a)g *

GP. ; ;%P ;%' ? 73 7 p 7 7t 7mD1 m

moles of a

a)erage bottoms

. n Nm

mass flowrate, lb+h numbe of absorber stages

*P bottom

bubble poi bottom of

minimum number of theoretical stages

c al c

calculated

NP N HP

number of passes in a tra& number of tubes pressure drop, psi

corr ( -

corrected distillate F feed

! I Ic

moles of saturated li!uid in the feed per mole of feed heat transfer dut&, *tu+h

G ;?

gas hea)& 5e&

condenser dut&, *tu+h reflux ratio, moles of reflux di)ided b& moles of net o)erhead product Ke&nolds number, dimensionless specific gra)it&

J 7 7? m n

an& comp li!uid light 5e& minimum tra& numb

top

top of the

K Ke s

. n Nm

mass flowrate, lb+h numbe of absorber stages

*P bottom

bubble poi bottom of

minimum number of theoretical stages

c al c

calculated

NP N HP

number of passes in a tra& number of tubes pressure drop, psi

corr ( -

corrected distillate F feed

! I Ic

moles of saturated li!uid in the feed per mole of feed heat transfer dut&, *tu+h

G ;?

gas hea)& 5e&

condenser dut&, *tu+h reflux ratio, moles of reflux di)ided b& moles of net o)erhead product Ke&nolds number, dimensionless specific gra)it&

J 7 7? m n

an& comp li!uid light 5e& minimum tra& numb

top

top of the

K Ke s

stages actor, !" 19"#1 factor, !" 19"1 g, in t transfer coefficient, *tu+ hr ft2 lume, ft#+lb )elocit&, ft+hr lume of inlet, ft#+lb lume of outlet, ft#+lb

mol+time lea)ing top tra&, tra&, mol+time )apor flow rate, ft#+h r )elocit&, uncorrected, gpm+ft2 r )elocit&, corrected, gpm+ft2 ing defined b& !" 19"1#, ft#+s edium rate, mol+time , lb+h e fraction

mol+time component in the rich oil entering stripper per mole of rich oil entering stripper component in the lean oil per mole of rich oil component in the li!uid in e!uilibrium with the stripping medium per mole of entering rich oil fraction

n& component in the lean gas lea)ing the absorber per mole of rich gas n& component in the entering rich gas per mole of rich gas n& component in the gas n e!uilibrium with the entering lean oil, per mole of rich gas

, ft latilit& actor define define din !" 19"/ 19"/ parameter in !" 19"6, 19"$ sion, d&ne+cm ft# p

nt feed stream the column )alue alue )erhead

nent

r

column

Example 19-1

Application of 19-1 This will calculate a material balance for the following components, given the information below.

-or the gi)en feed stream, estimate the product stream compositions for 9$M propane reco)er& in the o)erhead and with a maximum isoL butane con tent of 1M"

User-entered data is in BOLD RED.

Feed

Feed

Propane purit& in o)erhead

0.98

.aximum isoLbutane content Component C2

Moles

Component C2

2"8

C# iC8 C/

2.4

C#

102"$

nC8

0.01

Moles 162.8

#1"3

iC8

60"6

nC8

60"/

C/

31.0 76.7 76.

#89"8 moles

#89"8 moles

%o find the propane in the o)erhead with 9$M reco)er&

%o find the propane in the o)erhead with the abo)e specified reco)er&

C# in o)erhead O "9$  102"$

C# in o)erhead O

1/9"/ moles

3"9$



102"$

1/9"/ moles

*& stead& state material balance, the moles of propane in the bottoms

*& stead& state material balance, the moles of propane in the bottoms

C# in bottoms O C#,feed L C# o)erhead

C# in bottomsO

102"$

#"# moles

L

1/9"/

#"# moles

*ecause propane is the light 5e&, all the ethane in the feed will appear in the o)erhead"

*ecause propane is the light 5e&, all the ethane in the feed will appear in the o)erhead"

C2 in o)erheadO C2 in feed

C2 in o)erheadO C2 in feed

2"8 moles

2"8 moles

%o find the amount of isoLbu tane in the o)erhead with maximum 1 M

%o fin d the amount of isoLb utan e in the o)erhead with the abo)e sp ecified maximum percentage"

%he remainder of the materials in the o)erhead will be 99M of the total"

%he remainder of the materials in the o)erhead will ma5e up

C2

2"8 moles

C2

2"8 moles

C#

1/9"/ moles

C#

1/9"/ moles

C2 D C#

101"9 moles

C2 D C#

%otal moles in o)erhead O 101"9 moles + "99

2M

101"9 moles

%otal moles in o)erhead O

101"9

10#"0 moles

+

3"99

10#"0 moles

%herefore, the number of moles of isoLbutane can be found b&

%herefore, the number of moles of isoLbutane can be found b&

iC8 in o)erheadO "31  total moles in o)erhead

iC8 in o)erhead O

3"31

1"0 moles



10#"0

1"0 moles

%he rest of the isoLbutane will be in the bottoms"

%he rest of the isoLbutane will be in the bottoms"

iC8 in bottoms O iC8, feed L iC8, o)erhead

iC8 in bottoms O

#1"3

29"8 moles

Feed

!"e#$ead mole &

L

1"0

29"8 moles

%he remainder of the components FnC8, C/ will all be in the bottoms" A material balance table is show n below"

moles

of the total

moles

%he remainder of the components FnC8, C/ will all be in the bottoms" A material balance table is shown below" %ottoms

mole &

moles

Feed

mole &

moles

!"e#$ead mole &

moles

%ottoms

mole &

moles

mole &

C2

2"8

3"6

2"8

1"/

3"3

3"3

C2

2"8

3"6

2"8

1"/

C3

102"$

80"0

1/9"/

96"/

#"#

1"$

C3

102"$

80"0

1/9"/

96"/

#"#

iC4

#1"3

$"9

1"0

1"3

29"8

1/"$

iC4

#1"3

$"9

1"0

1"3

29"8

1/"$

nC4

60"6

22"3

3

3"3

60"6

81"#

nC4

60"6

22"3

3

3"3

60"6

81"#

C

60"/

21"9

3

3"3

60"/

81"2

C

60"/

21"9

3

3"3

60"/

81"2

total

#89"8

133"3

10#"0

133"3

1$/"$

133"3

total

#89"8

133"3

10#"0

133"3

1$/"$

133"3

3"3

3"3 1"$

%he sample calculations, e!uation s and spreadsheets present ed herein were de)eloped using examples published in the  ngineering (ata *oo5 as published b& the Gas Processor Suppliers Association as a ser)ice to the gas processing industr&" All information and calculation formulae has b een compiled and edited in cooperation with Gas Processors Association FGPA" hile e)er& effort has been made to present accurate and reliable technical information and calculation spread sheets based on the GPSA ngineering (ata *oo5 sample calculations, the use o f such information is )oluntar& and the GPA and GPSA do no t guarantee the accu rac&, completeness, efficac& or timeliness of such information" Keference herein to an & specific commercial product , calculation method, pro cess, or ser)ice b& tradeLname, trademar5, and ser)ice mar5 manufacturer or otherwise does n ot constitu te or impl& endo rsement, recommendation or fa)oring b& the GPA and+or GPSA" %he Calculation Spreadsheets are pro)ided without warrant& of an& 5ind including warranties of accurac& or reasonableness of factual or scientific assumptions, studies or conclusions, or merchantabilit&, fitness for a particular purpose or nonLinfringement of intellectual propert&" Jn no e)ent will the GPA or GPSA and their members be liable for an& damages whatsoe)er Fincluding without limitation, those resulting from lost profits, lost data or business interruption arising from the use, inabilit& to , reference to or reliance on the information in thes Publication, whether based on warrant&, contract, tort or an& other legal theor& and whether or not ad)ised of the possibilit& of such damages" %hese calculation spreadsheets are pro)ided to pro)ide an QRperational le)el of accurac& calculation based on rather broad assumptions Fincluding but not limited toT temperatures, pressures, compositions, imperial cur)es, site conditions etc and do not replace detailed and accurate (esign ngineering ta5ing into account actual process conditions, fluid properties, e!uipment condition or fowling and actual control setLpoint deadLband limitations"

Example 19-2

-ind the minimum number of tra&s, the minimum reflux ratio, and the actual number of tra&s at 1"# times the minimum reflux ratio gi)en the following -eed

291333 gal+da&

component C2

mol &

moles'$

2"36

21"/

C#

8$"06

/3/"0

iC8

13"11

13/"3

nC8

28"3$

2/3"1

iC/

/"81

/0"2

nC/

8"$1

/3"3

C0

8"$/

/3"8

Example 19-2

-ind the minimum number of tra&s, the minimum reflux ratio, and the actual number of tra&s at 1"# times the minimum reflux ratio gi)en the following -eed

291333 gal+da&

component C2

mol &

moles'$

2"36

21"/

C#

8$"06

/3/"0

iC8

13"11

13/"3

nC8

28"3$

2/3"1

iC/

/"81

/0"2

nC/

8"$1

/3"3

C0

8"$/

/3"8

total

133

13#$"$

Specifications

9$M C# in the o)erhead Frelati)e to feed 1M iC8 in o)erhead Air cooling a)ailable F123 - condensing temperature

Solution -irst, the product streams will be estimated using the gi)en specifications similar to xample 19"1 %he light 5e&, C#, and the hea)& 5e&, iC8, will be used to determine the compositions" C# in o)erhead O "99  C# in feed 89/"/ mol C#+h C2 in o)erhead O C2 in feed 21"/ mol C2+h %he moles in the o)erhead can be found b& the following Fsee x 19L1" moles in o)erhead O Fmoles C 2 D moles C# + "9$ /26"/ mol+h

C8 in o)erhead O "31  moles in o)erhead /"# mol+h %he bottoms stream can be found b& stead& state material balance" A material balance table is shown below" Feed mol &

!"e#$ead mol'$

mol &

%ottoms

mol'$

mol &

mol'$

C2

2"36

21"/

8"1

21"/

3"3

3"3

C3

8$"06

/3/"0

98"9

89/"/

2"3

13"1

iC4

13"11

13/"3

1"3

/"#

19"#

99"6

nC4

28"3$

2/3"1

3"3

3"3

8$"8

2/3"1

iC

/"81

/0"2

3"3

3"3

13"9

/0"2

nC

8"$1

/3"3

3"3

3"3

9"6

/3"3

C6

8"$/ 133

/3"8 13#$"$

3"3 133"3

3"3 /22"#

9"$ 133"3

/3"8 /10"/

total

%he pressure of the tower needs to be found" %his is set b& the cooling medium used" -or air, the temperature is 123 -" A bubble point calculation can be performed, and it is found that the pressure is 2$3 psia" %he ? alues below are obtained from section 2/" ?Lalue C2 2"$3 C#

3"9#

iC8

3"8/

%he relati)e )olatilit& can be found" : O ? C# + ? iC8 :O

2"306

%o find the bubble point temperature of the bottoms, ? )alues from the bubble point pressure are used F2$3 psia" %his assumes negligible pressure drop across the column" Component ?L alue C#

2"#

iC8

1"8

nC8

1"1/

iC/

3"0$

nC/

3"02

C0

3"1/


1"08#

%he arithmetic a)erage of the relati)e )olatilities is as f ollows" :AG

1"$//

%o calculate S -, !uation 19L1 is used" S- O F4( + 4*7?  F4* + 4(;? S-

920"#

-rom this and the a)erage relati)e )olatilit&, the minimum number of stages can be found using !uation 19L# Sm O log S- + log :AG Sm

11"30 tra&s

Chec5 whether a relati)e )olatilit& correction is needed" ? 7? O "9# O <  "8/ b

Fcondenser

? 7? O 2"# O <  1"8 b

Freboiler

%hese two s&stems of e!uations can be sol)ed for b and <" b

3"69$

<

1"6/9

Now, !uation 19L0 can be used to calculate the minimum number of stages" Sm

11"38 tra&s

%a5ing the relati)e )olatilit& correction into account changed the minimum number of tra&s b& a negligible a %o find the minimum reflux, !uations 19L6 and 19L$ can be used" -irst, = needs to be found" %his is done in the following table" :4-+F:L= x-

?top

?bottom

: a)erage, relati)e to C0

=O10

=O1/

=O1/"$

C2

3"3236

2"$3

#"#0

0$"## 3"32632$9 3"320/221 3"320920

C#

3"8$06

3"9#

2"#

20"08 1"21$81/0 1"11#6022 1"19/9830

iC8

3"1311

3"8/

1"8

1#"$/ L3"0/36#0 L1"21/$#9 L3"61682/

nC8

3"283$

3"#/

1"1/

11"33 L3"/29/#0 L3"001$62 L3"//1/9#

iC/

3"3/81

3"16

3"0$

/"$# L3"3#1330 L3"3#8#$6 L3"3#102$

nC/

3"38$1

3"18

3"02

/"33 L3"321$/0 L3"328381

C0

3"38$/

3"32/

3"1/

1"33 L3"33#2## L3"33#808 L3"33#266 3"3393666 L3"699#19 L3"13##1$

total

-rom the table, = is between 11 and 13" 'sing linear interpolation,= was found to be 1/"9" Now = can be used in !uation 19L$ to find K m" Km

1"##$

Now the theoretical tra&s at 1"# K m can be calculated" K O 1"#  K m K

1"6#990#$

73 + 1 O K + F K D 1 

3"0#/3#16

F 73 + 1 m O K m + F K m D 1 

3"/62#0##

'sing -igure 19"6 and the abo)e )alues Sm+S S

3"/8 20.478 tra&s

Kounding up, this is 21 tra&s"

L3"32220

%he sample calculations, e!uations and spreadsheets presented herein were de)eloped using examples publish hile e)er& effort has been made to present accurate and reliable technical information and calculation sprea %he Calculation Spreadsheets are pro)ided without warrant& of an& 5ind including warranties of accurac& or r Jn no e)ent will the GPA or GPSA and their members be liable for an& damages whatsoe)er Fincluding withou %hese calculation spreadsheets are pro)ided to pro)ide an QRperational le)el of accurac& calculation based o

Application of 19-2

%his will find the number of theoretical tra&s, the minimum reflux ratio, %his is onl& applicable with this s&stem of components, with the feed at i (se#-ente#ed data is in %!)* +E*. -eed

291000 gal+da&

K

component mol & moles'$ C2 21. 2"36 C# 8$"06 0.6 iC8 10.0 13"11

nC8

28"3$

20.1

iC/

/"81

6.2

nC/

8"$1

0.0

C0

8"$/

0.4

total

133

13#$"$

98 M C# in the o)erhead Frelati)e to fee 1 M iC8 in o)erhead

Specifications

Air cooling a)ailable F123 °- condensing tempe Solution -irst, the product streams will be estimated using the gi)en specifications %he light 5e&, C#, and the hea)& 5e&, iC8, will be used to determine the c C# in o)erhead O

3"9$



/3/"0

89/"/ mol C#+h C2 in o)erhead O C 2 in feed 21"/ mol C2+h %he moles in the o)erhead can be found b& the following Fsee x 19L1" moles in o)erhead O F

21"/

D

/22"2 mol+h

89/"/



+

iC8 in o)erhead O

3"31



/22"2

/"2 mol+h %he bottoms stream can be found b& stead& state material balance" A mat Feed mol &

!"e#$ead mol'$

mol &

%ott

mol'$

mol &

C2

2"1

21"/

8"1

21"/

3"3

C3

8$"6

/3/"0

98"9

89/"/

2"3

iC4

13"1

13/"3

1"3

/"2

19"#

nC4

28"1

2/3"1

3"3

3"3

8$"8

iC

/"8

/0"2

3"3

3"3

13"9

nC

8"$

/3"3

3"3

3"3

9"6

C6

8"9 133

/3"8 13#$"$

3"3 133"3

3"3 /22"2

9"$ 133"3

total

%he pressure of the tower needs to be found" %his is set b& the cooling m temperature is 123 -" ,e#fo#m a le point calclation sin/ 120 F to find t$e p#ess#e. ente# t$em elo.

Component ?Lalue C2 2.80 C# 0.93 iC8

0.4

nC8

0.3

iC/

0.17

nC/

0.14

C0

0.024

P

280 psi


O

3"9#

+

3"8/

2"306

(sin/ t$e p#ess#e fond f#om t$e le point calclation find t$e find  "ales f#om ection 2 and ente# t$em elo.

Component

?L alue

C2

3.36

C#

2.3

iC8

1.4

nC8

1.1

iC/

0.68

nC/

0.62

C0

0.1

20 °-

%


O

2"#

+

1"8

1"08#

%he arithmetic a)erage of the relati)e )olatilities is as follows" :AG

1"$//

%o calculate S -, !uation 19L1 is used" S- O F4( + 4*7?  F4* + 4(;? O

S-

98"9 2"3



19"# 1"3

91/"$

-rom this and the a)erage relati)e )olatilit&, the minimum number of sta Sm O log S- + log : AG Sm

O log

91/"$

+

log

11"38 tra&s

Chec5 whether a relati)e )olatilit& correction is needed" ? 7? O

3"9# O <  "8/ b Fcondenser

? 7? O

2"# O <  1"8 b Freboiler

%hese two s&stems of e!uations can be sol)ed for b and <"

1"$//

ount"

b <

3"69$ 1"6/9

Now, !uation 19L0 can be used to calculate the minimum number of sta Sm

11"30 tra&s Fwith relati)e )olatilit& correction

11"38 tra&s Fwithout relati)e )olatilit& correction C$ec5 to ma5e s#e t$at t$e #elati"e "olatilit co##ection does not m

%o find the minimum reflux, !uations 19L6 and 19L$ can be used" -irst, = needs to be found" %his is done in the following table" Ente# "ales of θ such that the& are consecti"e and there is a negati)e M,!+A: *o not ente# "ales of θ t$at a#e e;al to an of t$e a

x-

?top

: a)erage, relati)e to C0

?bottom

1

C2

3"3236

2"$3

#"#0

0$"##

3"320/

C#

3"8$06

3"9#

2"#

20"08

1"11#$

iC8

3"1311

3"8/

1"8

1#"$/

L1"21/0

nC8

3"283$

3"#/

1"1/

11"33

L3"001$

iC/

3"3/81

3"16

3"0$

/"$#

L3"3#88

nC/

3"38$1

3"18

3"02

/"33

L3"3281

C0

3"38$/

3"32/

3"1/

1"33

L3"33#/ -0.7989292

total 7inearl& interpolating intercept 1/"90 %his is the )alue of θ" Now = can be used in !uation 19L$ to find K m" K m

1"#/8

Now the theoretical tra&s at 1"# K m can be calculated" KO K

1"# 1"601



1"#/8

73 + 1 O K + F K D 1 

3"0#$

F 73 + 1 m O K m + F K m D 1 

3"/6/

(se t$e ao"e "ales in Fi/#e 19.7 to find m' and ente# it elo.

Sm+S S

0.4 20.444 tra&s

%his number needs to be rounded up to the nearest tra&" ed in the ngineering (ata *oo5 as published b& the Gas Processor Suppliers Association as a ser)ice to th sheets based on the GPSA ngineering (ata *oo5 sample calculations, the use of such information is )olu easonableness of factual or scientific assumptions, studies or conclusions, or merchantabilit&, fitness for a p t limitation, those resulting from lost profits, lost data or business interruption arising from the use, inabilit rather broad assumptions Fincluding but not limited toT temperatures, pressures, compositions, imperial cu

nd the actual number of tra&s for the below specified reflux ratio" ts bubble point, and with air cooling"

1.3 times Kmin



must not be greater than 133M must not exceed C#

ature

similar to xample 19"1 ompositions"

3"99

)alue should be between 1"2 to 1"#

erial balance table is shown below" oms mol'$

3"3 13"1 99"$ 2/3"1 /0"2 /3"3 /3"8 /10"0 dium used" -or air, the

it$ t$is tempe#at#e and p#ess#e find  "ales f#om ection 2 and

le point tempe#at#e. it$ t$is tempe#at#e and p#esse

es can be found using !uation 19L#

es"

5e a la#/e diffe#ence as t$at is $o t$e sp#eads$eet is setp.

umber in /#een and a positi)e number in le" e#a/e #elati"e "olatilities ecase t$is ill /i"e a false soltion.

:4-+F:L= alues of θ 16

1.8

3"3263

3"3209

1"21$/

1"1903

L3"0/30

L3"616#

L3"/298

L3"//1/

L3"3#13

L3"3#10

L3"3219

L3"322#

L3"33#2 0.0093

L3"33## -0.1030

gas processing industr&" All information and calculation formulae has been compiled and edited in coo tar& and the GPA and GPSA do not guarantee the accurac&, completeness, efficac& or timeliness of such articular purpose or nonLinfringement of intellectual propert&" & to , reference to or reliance on the information in thes Publication, whether based on warrant&, contrac r)es, site conditions etc and do not replace detailed and accurate (esign ngineering ta5ing into accou

peration with Gas Processors Association FGPA" information" Keference herein to an& specific commercial product, calculation method, process, or ser)ice b& tr t, tort or an& other legal theor& and whether or not ad)ised of the possibilit& of such damages" t actual process conditions, fluid properties, e!uipment condition or fowling and actual control setLpoint deadLba

deLname, trademar5, and ser)ice mar5 manufacturer or otherwise does not constitute or impl& endorsement, reco

d limitations"

mendation or fa)oring b& the GPA and+or G

Example 19-3

-ind the diameter of a depropaniUer gi)en the following 6381$ ft#+h

apor rate apor densit& 7i!uid rate

# lb+ft# 1193 gpm

7i!uid densit& 7i!uid surface tension tra& spacing

2$"$ lb+ft# #"# d&ne+cm 28 inches

19"/01 ft#+s

%here are three methods of finding tower diameter" All three will be explored" C Facto# Met$od

-rom -igure 19"1#, C was found to be approximatel& 82/ ft+h" 'sing !uation 19"11, ) max can be found" )max

1280 ft+hr

%his can be used in !uation 19"12 to find (" (

$"8$ feet 132 inches

omo/#ap$ Met$od

load needs to be found in order to use -igure 19"18"  load is found from !uation 19"1#" load

0"06 ft#+s

'sing load and the li!uid rate of 1193 gpm on -igure 19"18, tower diameters were read for one and two pass tr Rne pass tra& %wo pass tra&

9"2/ ft 111 in 6"1 ft $/"2 in

*etailed Met$od

-rom the e!uation in the bottom of -igure 19"1/, the s&stem factor for the tower was found"

S&stem factor

3"$/

'sing -igure 19"10 and the gi)en specifications, (dsg was found" (dsg

1$/ gpm+ft2

(dsg O (dsg  S&stem factor (dsg

1/6"/ gpm+ft2

-rom -igure 19"16, CA- 3 is 3"81"

CA- O CA-3  S&stem factor CA-

3"#89 ft+s

'sing (t from the nomograph method for a one pass tra& F9"2/ ft and a two pass tra& F6"1 ft -P7 O 9  ( % + NP

-P7

$#"2/ ft

one pass tra&

#1"9/ ft

two pass tra&

'sing !uation 19"16, the acti)e area can be found" AA.

89"9# ft2

one pass tra&

##"/2 ft2

two pass tra&

%he area of the downcomer can be found using !uation 19"1$" Jf it is less than 11M of AA., use either 11M of double A(., whiche)er is smaller" A(.

9"21 ft2

A(. + AA.

3"1$ one pass 3"26 two pass

Jn both cases, the downcomer areas are sufficientl& large"

Now the cross sectional area of the tower can be found using !uation 19"19 A%.

0$"#0 ft2

one pass tra&

/1"9/ ft2

two pass tra&

Another method to find the cross sectional area of the tower is !uation 19"23" A%.

29"$606#11/69 ft2

%he larger of the two A%. )alues is used" Jn this case, it will be the ones calculated from !uation 19"19" %he diameter of the column can be calculated b& !uation 19"21" (

9"## ft $"1# ft

one pass tra& two pass tra&

A comparison of the different calculated diameters follows"

Met$od

C -actor Nomograph Nomograph (etailed (etailed

Estimated *iamete#
me# of ,asses

L 1 2 1 2

132 111 $/ 112 9$

%he sample calculations, e!uations and spreadsheets presented herein were de)eloped using examples published hile e)er& effort has been made to present accurate and reliable technical information and calculation spreadsh %he Calculation Spreadsheets are pro)ided without warrant& of an& 5ind including warranties of accurac& or reas Jn no e)ent will the GPA or GPSA and their members be liable for an& damages whatsoe)er Fincluding without li %hese calculation spreadsheets are pro)ided to pro)ide an QRperational le)el of accurac& calculation based on r

Application of 19-3

%his finds the diameter of a depropaniUer with the following specifications us (se#-ente#ed data is in %!)* +E*. 70418 ft#+h

apor rate

19"/01 ft#+s

3 lb+ft#

apor densit& 7i!uid rate

1190 gpm 28.8 lb+ft#

7i!uid densit& 7i!uid surface tension tra& spacing

3.3 d&ne+cm 24 inches

%here are three methods of finding tower diameter" All three will be explored" C Facto# Met$od (sin/ t$e s#face tension and t#a spacin/ ente#ed ao"e se Fi/#e 19. 430 ft+h C 'sing !uation 19"11, ) max can be found"

)max

1201 ft+hr

%his can be used in !uation 19"12 to find (" (

$"8# feet 131 inches

omo/#ap$ Met$od

load needs to be found in order to use -igure 19"18"  load is found from !uat load &s"

0"06 ft#+s

.ust be less

(sin/ >load
Rne pass tra&

9. ft

%wo pass tra&

118 in 7. ft 93 in

Should be less Should be less Should be less Should be less

*etailed Met$od

-rom the e!uation in the bottom of -igure 19"1/, the s&stem factor for the to

S&stem factor

3"$/

(se t$e specified toe# spacin/ and
- p)= to find >*?ds/ f#om Fi/#e 1

ρLρ7

2/"$ lb+ft#

(dsg

186 gpm+ft2

(dsg O

1$0



(dsg

3"$/

1/$"8 gpm+ft2

(sin/ ρ> and t$e specified toe# spacin/ inpt CAF0 elo f#om Fi/#e

CA-3 CA- O

Rnl& applicabl

0.412

3"812



CA-

3"$/

3"#/1 ft+s

'sing (t from the nomograph method for a one pass tra& F9"2/ ft and a two -P7 O 9  -P7 O 9 

9"/ 6"/ -P7

+ +

1 2

for a one pass tra& for a two pass tra& $/"/ ft

one pass tra&

##"6/ ft

two pass tra&

'sing !uation 19"16, the acti)e area can be found" AA.

AA. or

/3"83 ft2

one pass tra&

##"9# ft2

two pass tra&

%he area of the downcomer can be found using !uation 19"1$" Jf it is less th double A(., whiche)er is smaller" A(.

9"10 ft2

A(. + AA.

3"1$ one pass 3"26 two pass

Jn both cases, the downcomer areas are sufficientl& large"

must be at least

Now the cross sectional area of the tower can be found using !uation 19"19 A%.

0$"6# ft2

one pass tra&

/2"20 ft2

two pass tra&

Another method to find the cross sectional area of the tower is !uation 19"2 A%.

29"6#109$ ft2

%he larger of the two A%. )alues is used" Jn this case, it will be the ones calc %he diameter of the column can be calculated b& !uation 19"21" (

9"#/ ft $"10 ft

one pass tra& two pass tra&

A comparison of the different calculated diameters follows"

Met$od

me# Estimated of ,asses *iamete#
C -actor L Nomograp Nomograp (etailed (etailed

1 2 1 2

131 118 93 112 9$

in the ngineering (ata *oo5 as published b& the Gas Processor Suppliers Association as a ser)ice to the gas p eets based on the GPSA ngineering (ata *oo5 sample calculations, the use of such information is )oluntar& a onableness of factual or scientific assumptions, studies or conclusions, or merchantabilit&, fitness for a particul mitation, those resulting from lost profits, lost data or business interruption arising from the use, inabilit& to , r ther broad assumptions Fincluding but not limited toT temperatures, pressures, compositions, imperial cur)es, si

ing three methods"

"

3 and inpt C.

ion 19"1#"

than #3

ft#+s

inpt t$e toe# diamete# elo

han 13 ft han 123 in han 18 ft han 10$ in

er was found"

.16 and inpt it elo.

19.17.

where

ρ) V

13 lb+ft# and should be V 3"0

ass tra& F6"1 ft

an 11M of AA., use either 11M of AA. or

11M of AA.

"

ulated from !uation 19"19"

ocessing industr&" All information and calculation formulae has been compiled and edited in cooperation with G d the GPA and GPSA do not guarantee the accurac&, completeness, efficac& or timeliness of such information" K r purpose or nonLinfringement of intellectual propert&" eference to or reliance on the information in thes Publication, whether based on warrant&, contract, tort or an& oth te conditions etc and do not replace detailed and accurate (esign ngineering ta5ing into account actual process

s Processors Association FGPA" ference herein to an& specific commercial product, calculation method, process, or ser)ice b& tradeLname, trade r legal theor& and whether or not ad)ised of the possibilit& of such damages" conditions, fluid properties, e!uipment condition or fowling and actual control setLpoint deadLband limitations"

ar5, and ser)ice mar5 manufacturer or otherwise does not constitute or impl& endorsement, recommendation or f

)oring b& the GPA and+or GPSA"

Example 19-4

-ind the tra& efficienc& of the column in xample 19L2"

-igure 19"1$ will be used to estimate a plate efficienc&" %his needs the relati)e )olatilit& and the )iscosit& of the 5e& component at a)erage column conditions" %a)g O F%top D %bottom + 2 %a)g

1$/ -

Jt is gi)en that at 1$/ -, the )iscosit& of the feed is 3"360 cp and the a)erage : is 1"$/8" B :

3"360 cp 1"$/8

%o use -igure 19"1$, the product of these two is needed" product

3"181

-rom the figure, the efficienc& was estimated to be $3M" %he number of actual tra&s can be found with this number as follows" %he method below counts the reboiler as a stage" Ntra&s O Ftheoretical tra&s L 1 + efficienc& Ntra&s

2/

%he sample calculations, e!uations and spreadsheets presented herein were de)eloped using examples published i hile e)er& effort has been made to present accurate and reliable technical information and calculation spreadshe %he Calculation Spreadsheets are pro)ided without warrant& of an& 5ind including warranties of accurac& or reas Jn no e)ent will the GPA or GPSA and their members be liable for an& damages whatsoe)er Fincluding without li %hese calculation spreadsheets are pro)ided to pro)ide an QRperational le)el of accurac& calculation based on ra

Application of 19-4

%his will find the tra& efficienc& of a column" (se#-ente#ed data is in %!)* +E* An a)erage temperature of the column is needed"

%top

120 -

% bottom

20 -

%a)g O F

123

%a)g

must be less than %bottom D

2/3



+

2

1$/ -

At t$e a"e#a/e tempe#at#e find t$e "iscosit and t$e #elati"e "olatilitof t$e 5e co

μ :

0.076 cp

Kelati)e )olatilit& must be less than 13

1.84

%o use -igure 19"1$, the product of these two is needed" product O

3"360

product

3"181



1"$/8

(se Fi/#e 19.18 it$ t$e ao"e p#odct and find t$e t#a efficienc. Ente# it elo.

ε

3"$

Should be less than 1

o! enter t"e n#m$er of t"eoretical tra%s in t"e col#mn $elo!. &"e n#m$er of act#a Ntheoretical trays

Ntra&s O F Ntra&s

'1

21

L

1 +

3"$

2

n the ngineering (ata *oo5 as published b& the Gas Processor Suppliers Association as a ser)ice to the gas proc ets based on the GPSA ngineering (ata *oo5 sample calculations, the use of such information is )oluntar& and nableness of factual or scientific assumptions, studies or conclusions, or merchantabilit&, fitness for a particular itation, those resulting from lost profits, lost data or business interruption arising from the use, inabilit& to , refe ther broad assumptions Fincluding but not limited toT temperatures, pressures, compositions, imperial cur)es, site

ponent and ente# t$em elo.

l tra%s !ill $e calc#lated.

essing industr&" All information and calculation formulae has been compiled and edited in cooperation with Gas he GPA and GPSA do not guarantee the accurac&, completeness, efficac& or timeliness of such information" Kefe urpose or nonLinfringement of intellectual propert&" rence to or reliance on the information in thes Publication, whether based on warrant&, contract, tort or an& other l conditions etc and do not replace detailed and accurate (esign ngineering ta5ing into account actual process co

rocessors Association FGPA" rence herein to an& specific commercial product, calculation method, process, or ser)ice b& tradeLname, trademar egal theor& and whether or not ad)ised of the possibilit& of such damages" ditions, fluid properties, e!uipment condition or fowling and actual control setLpoint deadLband limitations"

, and ser)ice mar5 manufacturer or otherwise does not constitute or impl& endorsement, recommendation or fa)o

ring b& the GPA and+o

Example 19-

-ind the diameter for a pac5ed tower using 2W plastic Pall rings for the column in xample 19L#" %he g for that problem are copied below" 6381$ ft#+h

apor rate

19"/01 ft#+s

apor densit& 7i!uid rate

# lb+ft# 1193 gpm

7i!uid densit& 7i!uid surface tension

2$"$ lb+ft# #"# d&ne+cm

tra& spacing

28 inches

Also gi)en B

3"360 cp 3"/ in ;2R+ft pac5ing

HP

-rom -igure 19"2/, the pac5ing factor F- p for the specified pac5ing is 20" - p

20

-igure 19"20 can now be used" %he bottom axis is defined b& F 7 p + G p   s!rt F @ ) + @7" 7 p+ G p can be .7 OF 1193 gpm  1$"$ lb+ft #  03 min+h + F6"8$ gal+ft # .7

268939 lb+h

.G O 6381$ ft #+h  # lb+ft # .G

bottom axis of -igure 19"20

2112/8 lb+h

3"823

'sing 3"823 on the bottom axis, following the graph up to the specified pressure drop, the left axis can %he left axis is e!ual to a large e!uation that includes Gp, which can be sol)ed for" left axis

3"32/

Gp

1"09# lb+ft2s

%he cross sectional area of the column can be found b& ta5ing the mass of the gas flowrate and di)iding b& Gp and the con)ersion between seconds and hours" Ac

#8"0/8331 ft2

%he diameter of the tower can be found using the e!uation for area of a circle" (%

0"08 ft

%his would li5el& be rounded to 6 ft

%he sample calculations, e!uations and spreadsheets presented herein were de)eloped using examples hile e)er& effort has been made to present accurate and reliable technical information and calculatio %he Calculation Spreadsheets are pro)ided without warrant& of an& 5ind including warranties of accur Jn no e)ent will the GPA or GPSA and their members be liable for an& damages whatsoe)er Fincluding %hese calculation spreadsheets are pro)ided to pro)ide an QRperational le)el of accurac& calculation

i)en data

Application of 19- %his will find the diameter of a pac5ed tower" (se#-ente#ed data is in %!)* +E*. 70418 ft#+h

apor rate apor densit& 7i!uid rate

3 lb+ft# 1190 gpm

7i!uid densit& 7i!uid surface tension

28.8 lb+ft# 3.3 d&ne+cm

tra& spacing

24 inches

Also gi)en B

0.076 cp 0. in ;2R+ft p

HP

(sin/ Fi/#e 19.2 find t$e pac5in/ facto#

- p ubstituted with . 7 + .G"

-igure 19"20 can now be used" %he bottom axi .7 OF .7 .G O .G

horiUontal axis of -igure 19"20 be found"

26

1193 268939 6381$ 2112/8

3"823

(sin/ t$e ao"e "ale on t$e $o#i@ontal axi left axis is e!ual to a large e!uation that inclu

left axis

0.024

G p

1"0/9

%he cross sectional area of the column can be di)iding b& Gp and the con)ersion between se Ac O Ac

2112/8 #/"#0$/92

%he diameter of the tower can be found using (%

6.71

Kound this up to the nearest foot" ublished in the ngineering (ata *oo5 as published b& the Gas Processor Suppliers Association as a s spreadsheets based on the GPSA ngineering (ata *oo5 sample calculations, the use of such informat c& or reasonableness of factual or scientific assumptions, studies or conclusions, or merchantabilit&, fit without limitation, those resulting from lost profits, lost data or business interruption arising from the ased on rather broad assumptions Fincluding but not limited toT temperatures, pressures, compositions,

19"/01 ft#+s

ac5ing

should be between 3"23 to 3"03 in" ;2R+ft pac5ing

s is defined b& F 7 p + G p   s!rt F @ ) + @7" 7 p+ G p can be substituted with . 7 + .G" gpm  1$"$ lb+ft #  03 min+h + F6"8$ gal+ft # lb+h ft#+h



#

lb+ft #

lb+h

.ust be less than 13

 /o to Fi/#e 19.26 and ente# t$e "e#tical axis "ale elo. %he es Gp, which can be sol)ed for"

lb+ft2s

ound b& ta5ing the mass of the gas flowrate and conds and hours" +

1"0/9

ft2 he e!uation for area of a circle" ft

r)ice to the gas processing industr&" All information and calculation formulae has been compiled and edited in c ion is )oluntar& and the GPA and GPSA do not guarantee the accurac&, completeness, efficac& or timeliness of su ness for a particular purpose or nonLinfringement of intellectual propert&" se, inabilit& to , reference to or reliance on the information in thes Publication, whether based on warrant&, contr imperial cur)es, site conditions etc and do not replace detailed and accurate (esign ngineering ta5ing into acco

operation with Gas Processors Association FGPA" h information" Keference herein to an& specific commercial product, calculation method, process, or ser)ice b& t ct, tort or an& other legal theor& and whether or not ad)ised of the possibilit& of such damages" nt actual process conditions, fluid properties, e!uipment condition or fowling and actual control setLpoint deadLb

radeLname, trademar5, and ser)ice mar5 manufacturer or otherwise does not constitute or impl& endorsement, rec

and limitations"

mmendation or fa)oring b& the GPA and+or

Example 19-6

-ind the optimum heat exchanger for a )ertical thermos&phon application gi)en it must produce 83,$33 lb %he pressure of the column is 26/ psig, has an isothermal boiling point of 22$ -" %he energ& for the reboil steam at 12/ psig" %he recirculation ratio should be at least 81" %ube (ata Jnner (iameter Surface Area

3"02 in 3"190# ft2+ft 3"#32 in2

Jnternal %ube Area apor (ensit&

2"26 lb+ft#

7i!uid iscosit& 7i!uid Specific Gra)it&

3"1 cp 3"8#

An energ& balance should be calculated" 'sing thermod&namic data

nthalp& of li!uid butane F22$ -, 293 psia

281 *tu+lb

nthalp& of )apor butane F22$ -, 293 psia

##$ *tu+lb

%he energ& needed to ma5e 83,$33 lb+ )apor I O m  H; I

#9/6033 *tu+h

%o find how much steam is needed nthalp& of steam at gi)en conditions mO I+ ; m H%

$0$ *tu+lb

8//9 lb+h steam 12/ -

%he maximum energ& flux is 12333 *tu+ft 2 A O I + flux A

#29"$ ft2

%his is the area that the heat exchanger must pro)ide" 'sing the specification for the surface area and assu length, the number of tubes can be found" Jll start using 10 ft, 12 ft, and 13 ft long tubes"

10 ft

7ength of %ube 12 ft

N O re!uired surface area + Flength of tube  surface area of tube  N 13/ tubes 183 tubes

13 ft

10$ tubes

'sing !uation 19"26, the static pressure of the reboiler leg can be found" )) O 1 + @) ))

3"883/ ft#+lb

3"883/ ft#+lb

3"883/ ft#+lb

3"3#6# ft#+lb

3"3#6# ft#+lb

3"3#6# ft#+lb

)7 O 1 + @7 )7

%he weight of the recirculated li!uid can be found b& multipl&ing the )apor mass b& 8 Fthe minimum reci .7

10#233lb li!uid+hr

10#233 lb li!uid+hr

10#233 lb li!uid+hr

ith this, the total )olume of the reboiler outlet can be found" 7 O .7  )7 7

03$2 ft#

03$2 ft#

03$2 ft#

)

16968 ft#

16968 ft#

16968 ft#

%otal )olume

283/0 ft#

283/0 ft#

283/0 ft#

) O .)  ))

%he specific )olume of the outlet can now be found using the total )olume and the total mass" )o O o + .o )o

3"1169 ft#+lb

3"1169 ft#+lb

3"1169 ft#+lb

Now that )o has been obtained, the static pressure of the reboiler leg can be found using !" 19"26"

P

1"/9 psi

1"19 psi

3"99 psi

Now the frictional resistance can be found" hen added to the static pressure, this will gi)e the total resist the frictional resistance to flow, the area of flow must be found" %his is a t O Nt  at + 188 at

3"223 ft2

3"298 ft2

3"#/2 ft2

%he mass )elocit&, Gt, can be found b& di)iding the mass flowrate b& the area of the tube" Gt

920#/1 lb+hr  ft 2

09860# lb+hr  ft 2

/6$909 lb+hr  ft 2

3"282 fth+lb

3"282 fth+lb

3"282 fth+lb

3"3/2 ft

3"3/2 ft

3"3/2 ft

Con)erting the )iscosit& units B Con)erting the diameter of the pipe (

Now the Ke&nolds number can be found" Ke O (  G t + B Ke

19666/

18$##1

12#039

'sing a .ood& plot, the friction factor can be found" f

3"333126 ft2+in2

3"3331#/ ft2+in2

3"33318$#

%he a)erage specific gra)it& can be found" sa)g

3"2##

3"2##

3"2##

'sing *ernoullis e!uation the pressure drop can be found" HP

2"66 psi

1"28 psi

3"69 psi

%he total resistance to flow can be calculated b& adding the frictional resistance and static resistance" %otal HP %he dri)ing force can be calculated

8"#0 psi

2"8# psi

1"6$ psi

2"9$ psi

2"28 psi

1"$0 psi

%he difference in the dri)ing force and resistance to flow determines whether or not the flow will go into t L1"#$ psi

L3"23 psi

3"3$ psi

NR% %he example solution has that a 12 ft long tube will ha)e a positi)e difference" J thin5 this is due t solution, while J did not round in xcel, rather J referenced the cells that J needed" %o determine what tube difference, J created a rough .ood& plot using the other two Ke&nolds numbers and friction factors" J fit t that is what the .ood& plot loo5s li5e" J then extrapolated a friction factor based on the trendline, and fini positi)e dri)ing force with 13 ft long tubes" ;owe)er, note that this has uncertaint& associated with the ge resulting friction factor"

2ery 0ough 3oo4y 5lot !.!!!1(# r o t c a )

!.!!!1(

f)*+  -'.$%!%$"&$'"$$-!" ln)*+ / !.!!!##1'11 0  1

n o i t c i r )

!.!!!1('

!.!!!1(

!.!!!1'%

!.!!!1'#

!.!!!1'

!.!!!1'' 1!!!!

1"!!!!

1#!!!!

1$!!!!

1%!!!!

Re%nold(s #m$er

1&!!!!

'!!!!!

'1!!!!

Application of 19-*

+h )apor Fassume pure butane" er will be supplied b& saturated

%his will find the optimum heat exchanger t (se#-ente#ed data is in %!)* +E*. 40800 lb )apor produced+h

%ube (ata Jnner (iameter

0.62

Surface Area

0.1963

Jnternal %ube Area apor (ensit&

0.302 2.27

7i!uid iscosit& 7i!uid Specific Gra

0.1 0.43

An energ& balance should be calculated" (si

6sothermal 7oiling 5oint8

''+

9olumn 5ressure8

'9,

%he energ& needed to ma5e specified mass fl IO I

83$33 #9/6033

%o find how much steam is needed nthalp& of steam at gi)en conditions mO m H%

$0$ #9/6033 8//9 12/

%he maximum energ& flux is 12333 *tu+ft 2 AO

#9/6033

A

#29"$

ming a Ente# a len/t$ of te sc$ t$at t$e p#ess

16

N O re!uired surface area + Flen N 13/ 'sing !uation 19"26, the static pressure of )) O 1 + @ ) O

1+

2"26

))

3"883/

)7 O 1 + @7 O 1 +

20"$#2

)7 culation ratio"

3"3#6#

%he weight of the recirculated li!uid can be .7

10#233

ith this, the total )olume of the reboiler ou 7 O

10#233

 7

) O

03$2 

!%!!

)

16968

%otal )olume

283/0

%he specific )olume of the outlet can now b )o O

283/0 )o

+ 3"1169

Now that )o has been obtained, the static pre

P ance to flow" %o find

1"/9

Now the frictional resistance can be found" resistance to flow, the area of flow must be at O

13/



at

3"223

%he mass )elocit&, Gt, can be found b& di)id Gt O

238333

+

Gt

920#/1

Con)erting the )iscosit& units B

3"282

Con)erting the diameter of the pipe (

3"3/2

Now the Ke&nolds number can be found" Ke

Ke O

3"3/2 Ke

 19666/

it$ t$e +enolds me# ao"e t$e f#i

f

0.000127

%he a)erage specific gra)it& can be found" sa)g O F

3"8# sa)g

D 3"2##

'sing *ernoullis e!uation the pressure drop

HP he reboiler"

2"66

%he total resistance to flow can be calculate %otal HP O

o the rounding done in the length pro)ided a positi)e hem to a log plot because J 5now shed the calculations" J got a eration of the .ood& plot and

2"66

D

%otal HP

8"#0

%he dri)ing force can be calculated O

10

 2"9$

%he difference in the dri)ing force and resist difference O

2"9$ difference

L L1"#$

%he sample calculations, e!uations and spreadsheets presented herein were de hile e)er& effort has been made to present accurate and reliable technical inf %he Calculation Spreadsheets are pro)ided without warrant& of an& 5ind inclu Jn no e)ent will the GPA or GPSA and their members be liable for an& damage %hese calculation spreadsheets are pro)ided to pro)ide an QRperational le)el

be length for a )ertical thermos&phon that uses saturated steam at 12/ psi as an energ& source"

4 1 recirculation ratio

recirculation ration must be greater than or e!ual to 81

in ft2+ft in2 lb+ft# cp

/ t$e#modnamic data ente# t$e "ales elo.

°-

nthalp& of bottoms li!uid at specified %, P

241 *tu+lb

psi

nthalp& of bottoms )apor at specified %, P

338 *tu+lb

owrate of )apor 

96

*tu+h

*tu+lb + lb+h steam -

+ 12333 ft2

$0$

#e diffe#ence is positi"e.

ft

7ength of %ube 12 ft

th of tube  surface area of tube  tubes

10 ft

183 tubes

10$ tubes

ft#+lb

3"883/ ft#+lb

3"883/ ft#+lb

ft#+lb

3"3#6# ft#+lb

3"3#6# ft#+lb

he reboiler leg can be found"

ound b& multipl&ing the )apor mass b& 8 Fthe minimum recirculation ratio" lb li!uid+hr

10#233 lb li!uid+hr

10#233 lb li!uid+hr

tlet can be found" !.!($(

ft#

03$2 ft#

03$2 ft#

ft#

16968 ft#

16968 ft#

ft#

283/0 ft#

283/0 ft#

3"883/

found using the total )olume and the total mass" 238333 ft#+lb

3"1169 ft#+lb

ssure of the reboiler leg can be found using !" 19"26"

3"1169 ft#+lb

psi

1"19 psi

3"99 psi

hen added to the static pressure, this will gi)e the total resistance to flow" %o find the frictional ound" %his is a t O Nt  at + 188 !.!!'1

ft2

3"298 ft2

3"#/2 ft2

ing the mass flowrate b& the area of the tube" 3"223 lb+hr  ft 2

09860# lb+hr  ft 2

/6$909 lb+hr  ft 2

fth+lb

3"282 fth+lb

3"282 fth+lb

ft

3"3/2 ft

3"3/2 ft

O (  Gt + B 920#/1

+

3"282 18$##1

12#039

ction facto# can e fond f#om a Mood ,lot. Ente# it elo.

ft2+in2

3"3#0

0.00013 ft2+in2



+

2 3"2##

can be found"

0.00014824 ft2+in2

3"2##

psi

1"28 psi

3"69 psi

b& adding the frictional resistance and static resistance" 1"/9 psi

3"8# psi



02"8

+

2"8# psi

1"6$ psi

2"28 psi

1"$0 psi

188 must be greater than the total resi

ance to flow determines whether or not the flow will go into the reboiler" 8"#0 psi

L3"23 psi

3"3$ psi

must be a positi)e )alue

eloped using examples published in the ngineering (ata *oo5 as published b& the Gas Processor Suppliers Ass ormation and calculation spreadsheets based on the GPSA ngineering (ata *oo5 sample calculations, the use of ing warranties of accurac& or reasonableness of factual or scientific assumptions, studies or conclusions, or merc s whatsoe)er Fincluding without limitation, those resulting from lost profits, lost data or business interruption ari of accurac& calculation based on rather broad assumptions Fincluding but not limited toT temperatures, pressures,

tance

ciation as a ser)i ciation ser)ice ce to the gas proce processing ssing indu industr& str&"" All infor information mation and calcu calculatio lation n formul formulae ae has been compi compiled led a such su ch inf infor ormat matio ion n is )ol )olun unta tar& r& and and the the GP GPA an and d GPSA GPSA do not not gua guara rant ntee ee the the acc accur urac ac& &, comp comple lete tene ness ss,, effi effica cac& c& or or ti hantabilit&,, fitness for a particular purpose or nonLinfringement of intellectual propert&" hantabilit& sing from the use, inabilit& inabilit& to , reference to or reliance on the information in thes Publication, Publication, whether based on omposition ompos itions, s, imperial imperial cur)e cur)es, s, site site conditi conditions ons etc and do do not repla replace ce detailed detailed and accura accurate te (esign (esign ngi ngineerin neering g ta

nd edited in cooperation with Gas Processors Association FGP FGPA" A" eliness of such information" Keference herein to an& specific commercial product, calculation method, process, arrant&, contract, tort or an& other legal theor& and whether or not ad)ised of the possibilit& of such damages" arrant&, ing int into o acc accoun ountt act actual ual pro proces cesss con condit dition ions, s, flu fluid id pro proper pertie ties, s, e!u e!uipm ipment ent con condit dition ion or fow fowlin ling g and act actual ual con contro troll se

or se ser) r)ic icee b& tr trad adeL eLna name me,, tr trad adem emar ar5, 5, an and d se ser) r)ic icee ma mar5 r5 ma manu nufa fact ctur urer er or ot othe herw rwis isee do does es no nott co cons nsti titu tute te or im impl pl& & en

tLpoint deadLband limitations"

orsement, recommendation or fa)oring b& the GPA and+

Example 19.17

-ind the oil circulation rate and the composition of the residue gas gi)en the following information" 6/ p from 133 mol of the rich gas stream" %he absorber will ha)e six theoretical plates, the a)erage temperatu and 1333 psig" Assume the lean oil is completel& stripped of rich gas components" %he feed composition Component C1

.ol M 93"0

C2

8"#

C#

#"2

iC8

3"/

nC8

1"3

C0

3"8

? )alues can be found from the e!uilibrium data in Chapter 2/, using the a)erage absorber conditions" Component C1

? #"2/3

C2

3"933

C#

3"#63

iC8

3"133

nC8

3"163

C0

3"3#/

-rom -igure 19"/1, A can be found using a as "6/ Fspecified efficienc& for propane absorption and nO0 A

3"$

!uation 19"29 can now be used" 73

29"0 mol+h

Now, A can be calculated for the remaining components" Component C1

A 3"391

C2

3"#29

C#

3"$33

iC8

2"903

nC8

1"681

C0

$"8/6

Now the absorption efficiencies can be determined for each component, using -igure 19"/1" Component C1

a 3"391

C2

3"#29

C#

3"6/

iC8

3"90

nC8

3"9$

C0

1

Now, the a )alue can be used to sol)e ! 19"#3 for the outlet composition of the lean gas" Component C1

E1 $2"#0

C2

2"$9

C#

3"$3

iC8

3"32

nC8

3"32

C0

3"33

Now the moles of each component in the rich oil, J, can be calculated b& stead& state material balance" Component C1

J $"28

C2

1"81

C#

2"83

iC8

3"8$

nC8

3"9$

C0

3"83

All the calculated properties are summariUed in a table below" Component C1

Mol &



A

Ea

B1



93"0

#"2/3

3"391

3"391

$2"#0

$"28

C2

8"#

3"933

3"#29

3"#29

2"$9

1"81

C#

#"2

3"#63

3"$33

3"6/

3"$3

2"83

iC8

3"/

3"133

2"903

3"90

3"32

3"8$

nC8

1"3

3"163

1"681

3"9$

3"32

3"9$

C0

3"8

3"3#/

$"8/6

1

3"33

3"83

%he sample calculations, e!uations and spreadsheets presented herein were de)eloped using examples pu hile e)er& effort has been made to present accurate and reliable technical information and calculation s %he Calculation Spreadsheets are pro)ided without warrant& of an& 5ind including warranties of accurac Jn no e)ent will the GPA or GPSA and their members be liable for an& damages whatsoe)er Fincluding w %hese calculation spreadsheets are pro)ided to pro)ide an QRperational le)el of accurac& calculation ba

Application of 19.17

rcent of the propane needs to be remo)ed re and pressure of the absorber are 138 is gi)en below"

%his will find the oil recirculation r completel& stripped" (se#-ente#ed data is in %!)* +E

Component C1

.ol M 90.6

C2

4.3

C#

3.2

iC8

0.

nC8

1.0

C0

0.4

 "ales can e fond f#om t$e e;

Component C1

Fspecified tra&s"

? 3.20

C2

0.900

C#

0.370

iC8

0.210

nC8

0.170

C0

0.03

(sin/ Fi/#e 19.1 A can e fon

A

0.8

!uation 19"29 can now be used" 73

29"0

Now, A can be calculated for the re Component C1

A 3"391

C2

3"#29

C#

3"$33

iC8

1"813

nC8

1"681

C0

$"8/6

(sin/ Fi/#e 19.1 amd t$e ao"

Component C1

a 0.091

C2

0.329

C#

0.7

iC8

0.96

nC8

0.98

C0

1

Now, the a )alue can be used to so Component C1

E1 $2"#0

C2

2"$9

C#

3"$3

iC8

3"32

nC8

3"31

C0

3"33

Now the moles of each component i Component C1

J $"28

C2

1"81

C#

2"83

iC8

3"8$

nC8

3"99

C0

3"83

All the calculated properties are su Component C1

Mol &

93"0

C2

8"#

C#

#"2

iC8

3"/

nC8

1"3

C0

3"8

blished in the ngineering (ata *oo5 as published b& the Gas Processor Suppliers Association as a ser)i preadsheets based on the GPSA ngineering (ata *oo5 sample calculations, the use of such information or reasonableness of factual or scientific assumptions, studies or conclusions, or merchantabilit&, fitnes ithout limitation, those resulting from lost profits, lost data or business interruption arising from the use sed on rather broad assumptions Fincluding but not limited toT temperatures, pressures, compositions, im

te and the composition of the residue gas for an absorber, assuming the lean oil comes in . 7 M of propane remo)ed 6 theoretical plates 104 -, a)erage temperature 1000 psig, a)erage pressure ili#im data in C$apte# 2 sin/ t$e a"e#a/e aso#e# conditions. Ente# t$em elo.

sin/ t$e specified efficienc fo# p#opane aso#ption and t$e specified t#as.Ente# A elo.

mol+h aining components"

A "ales t$e aso#ption efficiencies can e dete#mined fo# eac$ component. Ente# t$em elo.

)e ! 19"#3 for the outlet composition of the lean gas"

n the rich oil, J, can be calculated b& stead& state material balance"

mariUed in a table below" 

A

Ea

B1



#"2/3

3"391

3"391

$2"#0

$"28

3"933

3"#29

3"#29

2"$9

1"81

3"#63

3"$33

3"6/

3"$3

2"83

3"213

1"813

3"90

3"32

3"8$

3"163

1"681

3"9$/

3"31

3"99

3"3#/

$"8/6

1

3"33

3"83

ce to the gas processing industr&" All information and calculation formulae has been compiled and edited in coop is )oluntar& and the GPA and GPSA do not guarantee the accurac&, completeness, efficac& or timeliness of such i s for a particular purpose or nonLinfringement of intellectual propert&" , inabilit& to , reference to or reliance on the information in thes Publication, whether based on warrant&, contract, erial cur)es, site conditions etc and do not replace detailed and accurate (esign ngineering ta5ing into account

eration with Gas Processors Association FGPA" nformation" Keference herein to an& specific commercial product, calculation method, process, or ser)ice b& trad tort or an& other legal theor& and whether or not ad)ised of the possibilit& of such damages" actual process conditions, fluid properties, e!uipment condition or fowling and actual control setLpoint deadLban

eLname, trademar5, and ser)ice mar5 manufacturer or otherwise does not constitute or impl& endorsement, recom

limitations"

endation or fa)oring b& the GPA and+or GP

Example 19-8

(etermine the number of theoretical stages gi)en the following information" Sour water containing 2/33 ppmw n 1"/ ppmw" nough energ& is pro)ided b& the reboiler to produce "6/ lb steam per gallon feed" %he feed rate is 13 the tower operates at 21 psia" -irst, an o)erall material balance will be performed using the gi)en specifications" %he feed will be con)erted to mass flowrate" -eed

13 gpm 899$ lb+h

Now the mass of o)erhead steam can be calculted using the gi)en specification" R)erhead

8/3 lb+h

Now the o)erall stead& state material balance can be done, using the specifications gi)en" -eed Flb+h ;2S

12"/20

;2R

899$ /313"/20#

total

R)erhead Flb+h 12"/19

*ottoms Flb+h 3"336

8/3 8/8$ 802"/19 8/8$"330$

%he fraction of ; 2S stripped can be found b& di)iding the ; 2S in the o)erhead b& the ; 2S in the feed" -raction ;2S Stripped 3"999/ Jn order to estimate the top temperature, the fraction of water in the o)erhead and the partial pressure of water in the o)erhead need to be found" -raction of ; 2R in o)erhead 3"96# Partial pressure of ; 2R O fraction of ;2R  pressure 23"8#2 psi 'sing the steam tables from Chapter 28, the temperature of the top was estimated to be 229 -" Now that the temperature is 5nown, the ? )alue for ; 2S can be obtained" ? O ; + P where ; is ;enr&s 7aw Con -rom -igure 19"/2

;, ;2S Fpsia

% F- 133 233

11333 1$233

#33

20333

At 229 -, the ;enr&s constant was interpolated and found to be 2"3/ 13 8" ?

960"19

Now the moles of )apor lea)ing the top tra& can be found using the masses from the material balance and the mol 

2/"#6 mol

%he same can be done for the moles of li!uid lea)ing the bottom tra&" 7

2/2"06 mol

Now the stripping factor can be found" S% O ?   + 7 S%

9$"311#2$

Now )arious )alues of s, the efficienc&, can be calculated assuming multiple )alues of m" m

s 1 2

3"9$993 3"99993

#

1"33333

Jn order to get the re!uired ; 2S remo)al fraction, 2 theoretical tra&s are needed"

%he sample calculations, e!uations and spreadsheets presented herein were de)eloped using examples published i hile e)er& effort has been made to present accurate and reliable technical information and calculation spreadshe

%he Calculation Spreadsheets are pro)ided without warrant& of an& 5ind including warranties of accurac& or reas Jn no e)ent will the GPA or GPSA and their members be liable for an& damages whatsoe)er Fincluding without li %hese calculation spreadsheets are pro)ided to pro)ide an QRperational le)el of accurac& calculation based on ra

eeds to be stripped to pm and the top of

Application of 19-8 s w ca cu ate t e num er o t eoret ca (se#-ente#ed data is in %!)* +E*.

-eed

10 gpm

899$ lb+h ,. lb steam pr

Now the mass of o)erhead steam can be calc R)erhead

8/3 lb+h

Now the o)erall stead& state material balance -eed Flb+h

R)erhead Flb+h

;2S

12"/20

12"/19

;2R

899$ /313"/20#

8/3 802"/19

total

%he fraction of ; 2S stripped can be found b& -raction ;2S Stripped O 3"999/ Jn order to estimate the top temperature, the of water in the o)erhead need to be found" -raction of ; 2R in o)erhead O 3"96# Partial pressure of ; 2R O 23"8#2 psi (sin/ t$e steam tales f#om C$

stant and P is the pressure" %top

229 °-

Now that the temperature is 5nown, the ? )al -rom -igure 19"/2 ;, ;2S Fpsia

% F- 133

11333

233 #33

1$233 20333

C$ec5 to ma5e s#e t$at top is it$in t$e

ecular weights of each component" :

?

23/6/

+

969"$

Now the moles of )apor lea)ing the top tra& 

2/"#6 mol

%he same can be done for the moles of li!uid 7

2/2"06 mol

Now the stripping factor can be found" S% O S%

969"$



9$"#63

Now )arious )alues of s, the efficienc&, can m 1 2 # 8 /

s 3"9$993 3"99993 1"33333 1"33333 1"33333

/ompare t"e re0#ired fraction of '2 stri

n the ngineering (ata *oo5 as published b& the Gas Processor Suppliers Association as a ser)ice to the gas proc ets based on the GPSA ngineering (ata *oo5 sample calculations, the use of such information is )oluntar& and

nableness of factual or scientific assumptions, studies or conclusions, or merchantabilit&, fitness for a particular itation, those resulting from lost profits, lost data or business interruption arising from the use, inabilit& to , refe ther broad assumptions Fincluding but not limited toT temperatures, pressures, compositions, imperial cur)es, site

tages nee e to str p

;2S Concentration

2

rom sour water"

inlet outlet

200 ppmw

operating pressure

1. ppmw

o4uce4 per gallon fee4

lted using the gi)en specification"

can be done, using the specifications gi)en" *ottoms Flb+h 3"336 8/8$ 8/8$"330$ di)iding the ; 2S in the o)erhead b& the ; 2S in the feed" 12"/19 + must not exceed 1

12"/20

raction of water in the o)erhead and the partial pressure

8/3

+

802"/19

3"96#



21

must not exceed operating pressure pte# 24 estimate t$e tempe#at#e of t$e top and ente# it elo.

21 psia typically between '.$ to '&.$ psi

ue for ; 2S can be obtained"

slope intercept ;

6/ #833 23/6/ psia

an/e of t$e ao"e tale. f it is not t$e  "ale is ext#apolated and ma not e acc#ate.

21

an be found using the masses from the material balance and the molecular weights of each component"

lea)ing the bottom tra&" tra&"

2/"#6

+

2/2"06

be calculated assuming multiple )alues of m"

Ke!uired fraction 3"999/

ped to t"e Es in t"e a$o3e ta$le to find "o! man% t"eoretical tra%s are needed.

essing industr& industr&"" All information and calculation formulae has been compiled and edited in cooperation with Gas he GP GPA A and GPSA do not guara guarantee ntee the accur accurac& ac&,, complet completeness eness,, efficac& efficac& or timeli timeliness ness of such infor information mation"" Kefe

urpose or nonLinfringement of intellectual propert& propert&"" rence to or relia reliance nce on the infor informatio mation n in thes Publi Publicatio cation, n, wheth whether er based on warran warrant& t&,, cont contract, ract, tort or an& other l cond co ndit itio ions ns etc etc and and do not not rep repla lace ce det detai aile led d and and accu accura rate te (es (esig ign n ngi ngine neer erin ing g ta5i ta5ing ng int into o acco accoun untt actu actual al pro proce cess ss co co

rocessors Association FGPA" rence herein to an& specific commercial product, calculation method, process, or ser)ice b& tradeLname, trademar

egal theor& and whether or not ad)ised of the possibilit& of such damages" ditions, fluid properties, e!uipment condition or fowling and actual control setLpoint deadLband limitations"

, and ser)ice mar5 manufacturer or otherwise does not constitute or impl& endorsement, recommendation or fa)o

ring b& the GPA and+o

LIMITS

*ampel 1&-' ;ptimum operating reflu* ratio are 1.' to 1.( times the minimum reflu* ratio *ample 1&-( e4 columns shoul4 be !.'! to !.#! inches of water per foot of pac> 4epth? 1 inch m *ample 1&-#
1!-1" psig '!!-'(! oA '!-'"! oA 1!!!-'!!! 7tuCgal !."-'.! ppmmw

Fractionation and Absorption

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