Dew Point Calculate Spreatseet
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Temperature = -20 °FPressure = 600 psia
What is the ratio of moles of liquid to the moles of the total mixture under these conditions?
Solution Steps
Component
Column1 2 3 4 5 6 7 8
Trial values of L (note: V + L = 1) = 0.030
2000 0.02 0.04 0.06 Liquid Vapor
0.9010 3.7 0.24712 0.25084 0.25466 3.61900 0.24896 0.92117
0.0106 1.23 0.00864 0.00867 0.00870 1.22472 0.00866 0.01066
0.0499 0.41 0.11830 0.11508 0.11203 0.42770 0.11667 0.04783
0.0187 0.082 0.18633 0.15751 0.13642 0.10954 0.17071 0.01400
0.0065 0.034 0.12191 0.08948 0.07068 0.06298 0.10321 0.00351
0.0045 0.023 0.10578 0.07249 0.05513 0.05231 0.08603 0.00198
0.0017 0.0085 0.06001 0.03530 0.02500 0.03825 0.04445 0.00038
0.0019 0.0058 0.07398 0.04170 0.02903 0.03563 0.05333 0.00031C6 0.0029 0.0014 0.13569 0.07014 0.04730 0.03136 0.09248 0.00013
0.0023 0.00028 0.11344 0.05712 0.03817 0.03027 0.07598 0.00002TOTALS 1.0000 1.17120 0.89833 0.77713 1.00048 0.99999
0.00042
0.00014
Example 25-2 -- Flash CalculationA typical high pressure separator gas is cooled to liquefy heavier hydrocarbons prior to cooling to a lower temperature where these components would freeze out as solids.
The feed gas composition is given in Column 1. The flash equation, 25-5, is solved for three estimated values of L as shown in Columns 3, 4, and 5. is L = 0.03. This solution is entered into Cell I17 and then whose solution is shown in columns 6 and 7. The gas composition is then calculated using yi = Kixi in Column 8. This 'correct' value is used for purposes of illustration. It is not a completely converged solution, for xi = 1.000478 and yi = 0.999985, columns 7 and 8. This error may be too large for some applications. D20 - E20 in order to have unidirectional line in the plot below. This will assist identifying the value of L where the line crosses S(xi) = 1.00.]
Feed Compositi
on
Pk = Final value of L
from plot below =
L+VKi
Ni Ki***
Ni/(L+VKi)
Ni/(L+VKi) Ni/(L+VKi)
xi = Ni/(L+VK
i) yi
C1
CO2**
C2
C3
iC4
nC4
iC5
nC5
C7*
C7*
C8
* C7+ = average of nC7 + nC8 properties
** KCO2 = sq.rt (KC1 · KC2)approximation purposes only; however, they can be very useful in such a role. The critical locus chart used in the convergence pressure method has also be retained (Fig. 25-8).
0.015 0.02 0.025 0.03 0.035 0.04 0.045 0.05 0.055 0.06 0.0650
0.2
0.4
0.6
0.8
1
1.2
1.4
Trial Values of L
Calcu
late
d To
tals
The sample calculations, equations and spreadsheets presented herein were developed using examples published in the Engineering Data Book as published by the Gas Processor Suppliers Association as a service to the gas processing industry. All information and calculation formulae has been compiled and edited in cooperation with Gas Processors Association (GPA).While every effort has been made to present accurate and reliable technical information and calculation spreadsheets based on the GPSA Engineering Data Book sample calculations, the use of such information is voluntary and the GPA and GPSA do not guarantee the accuracy, completeness, efficacy or timeliness of such information. Reference herein to any specific commercial product, calculation method, process, or service by trade-name, trademark, and service mark manufacturer or otherwise does not constitute or imply endorsement, recommendation or favoring by the GPA and/or GPSA.The Calculation Spreadsheets are provided without warranty of any kind including warranties of accuracy or reasonableness of factual or scientific assumptions, studies or conclusions, or merchantability, fitness for a particular purpose or non-infringement of intellectual property.In no event will the GPA or GPSA and their members be liable for any damages whatsoever (including without limitation, those resulting from lost profits, lost data or business interruption) arising from the use, inability to , reference to or reliance on the information in thes Publication, whether based on warranty, contract, tort or any other legal theory and whether or not advised of the possibility of such damages.These calculation spreadsheets are provided to provide an “Operational level” of accuracy calculation based on rather broad assumptions (including but not limited to; temperatures, pressures, compositions, imperial curves, site conditions etc) and do not replace detailed and accurate Design Engineering taking into account actual process conditions, fluid properties, equipment condition or fowling and actual control set-point dead-band limitations.
NOTE: The table above reverses columns 4 and 5 compared to Fig. 25-3 in the 13th Edition Data Book. This was done to ease the plotting and interpolation between the two trial values of L.
0.015 0.02 0.025 0.03 0.035 0.04 0.045 0.05 0.055 0.06 0.0650
0.2
0.4
0.6
0.8
1
1.2
1.4
Trial Values of L
Calcu
late
d To
tals
Temperature = -125 °FPressure = 600 psia
What is the ratio of moles of liquid to the moles of the total mixture under these conditions?
Solution Steps
Column1 2 3 4 5 6
Feed CompositionTrial values of L (note: V + L = 1) =
3000 0.02 0.04 0.06
0.948560 3.7 0.24712 0.25084 0.25466 3.61900
0.0020 1.23 0.00864 0.00867 0.00870 1.22472
0.0317 0.41 0.11830 0.11508 0.11203 0.42770
0.0111 0.082 0.18633 0.15751 0.13642 0.10954
0.0020 0.034 0.12191 0.08948 0.07068 0.06298
0.0028 0.023 0.10578 0.07249 0.05513 0.05231
0.0008 0.0085 0.06001 0.03530 0.02500 0.03825
0.0006 0.0058 0.07398 0.04170 0.02903 0.03563C6 0.0006 0.0014 0.13569 0.07014 0.04730 0.03136
0.0000 0.00028 0.11344 0.05712 0.03817 0.03027TOTALS 1.000000 1.17120 0.89833 0.77713
0.00042
0.00014
Application 25-2 -- Flash Calculation
The feed gas composition is given in Column 1. The flash equation, 25-5, is solved for three estimated values of L as shown in Columns 3, 4, and 5. 0.03. This solution is entered into Cell I17 and then whose solution is shown in columns 6 and 7. The gas composition is then calculated using yi = Kixi in Column 8. This 'correct' value is used for purposes of illustration. It is not a completely converged solution, for xi = 0.578868 and yi = 1.013025, columns 7 and 8. This error may be too large for some applications. to have unidirectional line in the plot below. This will assist identifying the value of L where the line crosses S(xi) = 1.00.]
Component Pk =
Final value of L from plot below =
L+VKi
Ni Ki
Ni/(L+VKi)
Ni/(L+VKi) Ni/(L+VKi)
C1
CO2**
C2
C3
iC4
nC4
iC5
nC5
C7*
C7*
C8
* C7+ = average of nC7 + nC8 properties
** KCO2 = sq.rt (KC1 · KC2)
0.015 0.02 0.025 0.03 0.035 0.04 0.045 0.05 0.055 0.06 0.0650
0.2
0.4
0.6
0.8
1
1.2
1.4
Trial Values of L
Calcu
late
d To
tals
The sample calculations, equations and spreadsheets presented herein were developed using examples published in the Engineering Data Book as published by the Gas Processor Suppliers Association as a service to the gas processing industry. All information and calculation formulae has been compiled and edited in cooperation with Gas Processors Association (GPA).While every effort has been made to present accurate and reliable technical information and calculation spreadsheets based on the GPSA Engineering Data Book sample calculations, the use of such information is voluntary and the GPA and GPSA do not guarantee the accuracy, completeness, efficacy or timeliness of such information. Reference herein to any specific commercial product, calculation method, process, or service by trade-name, trademark, and service mark manufacturer or otherwise does not constitute or imply endorsement, recommendation or favoring by the GPA and/or GPSA.The Calculation Spreadsheets are provided without warranty of any kind including warranties of accuracy or reasonableness of factual or scientific assumptions, studies or conclusions, or merchantability, fitness for a particular purpose or non-infringement of intellectual property.In no event will the GPA or GPSA and their members be liable for any damages whatsoever (including without limitation, those resulting from lost profits, lost data or business interruption) arising from the use, inability to , reference to or reliance on the information in thes Publication, whether based on warranty, contract, tort or any other legal theory and whether or not advised of the possibility of such damages.These calculation spreadsheets are provided to provide an “Operational level” of accuracy calculation based on rather broad assumptions (including but not limited to; temperatures, pressures, compositions, imperial curves, site conditions etc) and do not replace detailed and accurate Design Engineering taking into account actual process conditions, fluid properties, equipment condition or fowling and actual control set-point dead-band limitations.
0.015 0.02 0.025 0.03 0.035 0.04 0.045 0.05 0.055 0.06 0.0650
0.2
0.4
0.6
0.8
1
1.2
1.4
Trial Values of L
Calcu
late
d To
tals
What is the ratio of moles of liquid to the moles of the total mixture under these conditions?
Column7 8
0.030
Liquid Vapor
0.26211 0.96979
0.00160 0.00197
0.07405 0.03036
0.10127 0.00830
0.03222 0.00110
0.05275 0.00121
0.01970 0.00017
0.01617 0.000090.01900 0.00003
0.00000 0.000000.57887 1.01303
The feed gas composition is given in Column 1. The flash equation, 25-5, is solved for three estimated values of L 0.03. This solution is entered into Cell I17 and then whose solution is shown in columns 6 and 7. The gas This 'correct' value is used for purposes of illustration. It is not a completely converged solution, for xi = 0.578868 and yi = 1.013025, columns 7 and 8. This error may be too large for some applications. to have unidirectional line in the plot below. This will assist identifying the value of L where the line crosses
Final value of L from plot below =
xi = Ni/(L+VKi) yi
0.015 0.02 0.025 0.03 0.035 0.04 0.045 0.05 0.055 0.06 0.0650
0.2
0.4
0.6
0.8
1
1.2
1.4
Trial Values of L
Calcu
late
d To
tals
The sample calculations, equations and spreadsheets presented herein were developed using examples published in the Engineering Data Book as published by the Gas Processor Suppliers Association as a service to the gas processing industry. All information and calculation formulae has been compiled and edited in cooperation with Gas Processors Association (GPA).While every effort has been made to present accurate and reliable technical information and calculation spreadsheets based on the GPSA Engineering Data Book sample calculations, the use of such information is voluntary and the GPA and GPSA do not guarantee the accuracy, completeness, efficacy or timeliness of such information. Reference herein to any specific commercial product, calculation method, process, or service by trade-name, trademark, and service mark manufacturer or otherwise does not constitute or imply endorsement, recommendation or favoring by the GPA and/or GPSA.The Calculation Spreadsheets are provided without warranty of any kind including warranties of accuracy or reasonableness of factual or scientific assumptions, studies or conclusions, or merchantability, fitness for a particular purpose or non-infringement of intellectual property.In no event will the GPA or GPSA and their members be liable for any damages whatsoever (including without limitation, those resulting from lost profits, lost data or business interruption) arising from the use, inability to , reference to or reliance on the information in thes Publication, whether based on warranty, contract, tort or any other legal theory and whether or not advised of the possibility of such damages.These calculation spreadsheets are provided to provide an “Operational level” of accuracy calculation based on rather broad assumptions (including but not limited to; temperatures, pressures, compositions, imperial curves, site conditions etc) and do not replace detailed and accurate Design Engineering taking into account actual process conditions, fluid properties, equipment condition or fowling and actual control set-point dead-band limitations.
0.015 0.02 0.025 0.03 0.035 0.04 0.045 0.05 0.055 0.06 0.0650
0.2
0.4
0.6
0.8
1
1.2
1.4
Trial Values of L
Calcu
late
d To
tals
The sample calculations, equations and spreadsheets presented herein were developed using examples published in the Engineering Data Book as published by the Gas Processor Suppliers Association as a service to the gas processing industry. All information and calculation formulae has been compiled and edited in cooperation with Gas Processors Association (GPA).While every effort has been made to present accurate and reliable technical information and calculation spreadsheets based on the GPSA Engineering Data Book sample calculations, the use of such information is voluntary and the GPA and GPSA do not guarantee the accuracy, completeness, efficacy or timeliness of such information. Reference herein to any specific commercial product, calculation method, process, or service by trade-name, trademark, and service mark manufacturer or otherwise does not constitute or imply endorsement, recommendation or favoring by the GPA and/or GPSA.
In no event will the GPA or GPSA and their members be liable for any damages whatsoever (including without limitation, those resulting from lost profits, lost data or business interruption) arising from the use, inability to , reference to or reliance on the information in thes Publication, whether based on warranty, contract, tort or any other legal theory and whether or not advised of the possibility of such damages.These calculation spreadsheets are provided to provide an “Operational level” of accuracy calculation based on rather broad assumptions (including but not limited to; temperatures, pressures, compositions, imperial curves, site conditions etc) and do not replace detailed and accurate Design Engineering taking into account actual process conditions, fluid properties, equipment condition or fowling and actual control set-point dead-band limitations.
While every effort has been made to present accurate and reliable technical information and calculation spreadsheets based on the GPSA Engineering Data Book sample calculations, the use of such information is voluntary and the GPA and GPSA do not guarantee the accuracy, completeness, efficacy or timeliness of such information. Reference herein to any specific commercial product, calculation method, process, or service by trade-name, trademark, and service mark manufacturer or otherwise does not constitute or imply endorsement, recommendation or favoring by the GPA and/or GPSA.
These calculation spreadsheets are provided to provide an “Operational level” of accuracy calculation based on rather broad assumptions (including but not limited to; temperatures, pressures, compositions, imperial curves, site conditions etc) and do not replace detailed and accurate Design Engineering taking into account actual process conditions, fluid properties, equipment condition or fowling and actual control set-point dead-band limitations.
While every effort has been made to present accurate and reliable technical information and calculation spreadsheets based on the GPSA Engineering Data Book sample calculations, the use of such information is voluntary and the GPA and GPSA do not guarantee the accuracy, completeness, efficacy or timeliness of such information. Reference herein to any specific commercial product, calculation method, process, or service by trade-name, trademark, and service mark manufacturer or otherwise does not constitute or imply endorsement, recommendation or favoring by the GPA and/or GPSA.
Application 25-1 -- Binary System Calculation
A mixture is put under the following conditions: A mixture is put under the following conditions:
ComponentMethane = 60 lb moles ComponentMethaneComponentEthane = 40 lb moles Component EthaneTemperature = -125 °F TemperaturePressure = 50 psia Pressure
How many moles are in the vapor phase and how many in the liquid phase? How many moles are in the vapor phase and how many in the liquid phase?
= 10 Page 25-10 =
= 0.35 Page 25-10 =
= 10 =
= 0.35 =
0.35 and 10 0.35Solving the above equations simultaneously: Solving the above equations simultaneously:
= 0.0674 =
= 0.674 =
= 0.9326 =
= 0.326 =To find the amount of vapor in the mixture, let v denote the number of lb moles of vapoTo find the amount of vapor in the mixture, let v denote the number of lb moles of vapor.Summing the moles of Methane in each phase gives: Summing the moles of Methane in each phase gives:
100 lb moles
= 60 lb moles
= 60 lb molesv = 87.9 Therefore, v
The mixture consists of: The mixture consists of:Vapor = 87.9 lb moles VaporLiquid = 12.1 lb moles Liquid
The sample calculations, equations and spreadsheets presented herein were developed using examples published in the Engineering Data Book as published by the Gas Processor Suppliers Association as a service to the gas processing industry. All information and calculation formulae has been compiled and edited in cooperation with Gas Processors Association (GPA).While every effort has been made to present accurate and reliable technical information and calculation spreadsheets based on the GPSA Engineering Data Book sample calculations, the use of such information is voluntary and the GPA and GPSA do not guarantee the accuracy, completeness, efficacy or timeliness of such information. Reference herein to any specific commercial product, calculation method, process, or service by trade-name, trademark, and service mark manufacturer or otherwise does not constitute or imply endorsement, recommendation or favoring by the GPA and/or GPSA.The Calculation Spreadsheets are provided without warranty of any kind including warranties of accuracy or reasonableness of factual or scientific assumptions, studies or conclusions, or merchantability, fitness for a particular purpose or non-infringement of intellectual property.In no event will the GPA or GPSA and their members be liable for any damages whatsoever (including without limitation, those resulting from lost profits, lost data or business interruption) arising from the use, inability to , reference to or reliance on the information in thes Publication, whether based on warranty, contract, tort or any other legal theory and whether or not advised of the possibility of such damages.These calculation spreadsheets are provided to provide an “Operational level” of accuracy calculation based on rather broad assumptions (including but not limited to; temperatures, pressures, compositions, imperial curves, site conditions etc) and do not replace detailed and accurate Design Engineering taking into account actual process conditions, fluid properties, equipment condition or fowling and actual control set-point dead-band limitations.
Example 25-1 -- Binary System Calculation
K1 K1
K2 K2
From the definition of Ki-value, Eq. 25-1: From the definition of Ki-value, Eq. 25-1:
K1 = y1/x1 K1 = y1/x1
K2 = y2/x2 K2 = y2/x2
For a binary system, x1 + x2 = 1 and y1 + y2 = 1, so For a binary system, x1 + x2 = 1 and y1 + y2 = 1, so
(1-y1)/(1-x1) = (1-y2)/(1-x2) = (1-y1)/(1-x1) =
x1 x1
y1 y1
x2 x2
y2 y2
S lb moles for component 1 + 2 = S lb moles for component 1 + 2 =
x1 + y1 x1 + y1
(y1 * v) + (x1 * [100 - v]) (y1 * v) + (x1 * [100 - v])
Application 25-1 -- Binary System Calculation
A mixture is put under the following conditions:
= 60 lb moles= 40 lb moles= -125 °F= 50 psia
How many moles are in the vapor phase and how many in the liquid phase?
10 Page 25-10
0.35 Page 25-10
10
0.35
and 10Solving the above equations simultaneously:
0.0674
0.674
0.9326
0.326To find the amount of vapor in the mixture, let v denote the number of lb moles of vapor.Summing the moles of Methane in each phase gives:
100 lb moles
= 60 lb moles
= 60 lb moles= 87.9
The mixture consists of:= 87.9 lb moles= 12.1 lb moles
The sample calculations, equations and spreadsheets presented herein were developed using examples published in the Engineering Data Book as published by the Gas Processor Suppliers Association as a service to the gas processing industry. All information and calculation formulae has been compiled and edited in cooperation with Gas Processors Association (GPA).While every effort has been made to present accurate and reliable technical information and calculation spreadsheets based on the GPSA Engineering Data Book sample calculations, the use of such information is voluntary and the GPA and GPSA do not guarantee the accuracy, completeness, efficacy or timeliness of such information. Reference herein to any specific commercial product, calculation method, process, or service by trade-name, trademark, and service mark manufacturer or otherwise does not constitute or imply endorsement, recommendation or favoring by the GPA and/or GPSA.The Calculation Spreadsheets are provided without warranty of any kind including warranties of accuracy or reasonableness of factual or scientific assumptions, studies or conclusions, or merchantability, fitness for a particular purpose or non-infringement of intellectual property.In no event will the GPA or GPSA and their members be liable for any damages whatsoever (including without limitation, those resulting from lost profits, lost data or business interruption) arising from the use, inability to , reference to or reliance on the information in thes Publication, whether based on warranty, contract, tort or any other legal theory and whether or not advised of the possibility of such damages.These calculation spreadsheets are provided to provide an “Operational level” of accuracy calculation based on rather broad assumptions (including but not limited to; temperatures, pressures, compositions, imperial curves, site conditions etc) and do not replace detailed and accurate Design Engineering taking into account actual process conditions, fluid properties, equipment condition or fowling and actual control set-point dead-band limitations.
From the definition of Ki-value, Eq. 25-1:
For a binary system, x1 + x2 = 1 and y1 + y2 = 1, so
(1-y2)/(1-x2) =
lb moles for component 1 + 2 =
The sample calculations, equations and spreadsheets presented herein were developed using examples published in the Engineering Data Book as published by the Gas Processor Suppliers Association as a service to the gas processing industry. All information and calculation formulae has been compiled and edited in cooperation with Gas Processors Association (GPA).While every effort has been made to present accurate and reliable technical information and calculation spreadsheets based on the GPSA Engineering Data Book sample calculations, the use of such information is voluntary and the GPA and GPSA do not guarantee the accuracy, completeness, efficacy or timeliness of such information. Reference herein to any specific commercial product, calculation method, process, or service by trade-name, trademark, and service mark manufacturer or otherwise does not constitute or imply endorsement, recommendation or favoring by the GPA and/or GPSA.The Calculation Spreadsheets are provided without warranty of any kind including warranties of accuracy or reasonableness of factual or scientific assumptions, studies or conclusions, or merchantability, fitness for a particular purpose or non-infringement of intellectual property.In no event will the GPA or GPSA and their members be liable for any damages whatsoever (including without limitation, those resulting from lost profits, lost data or business interruption) arising from the use, inability to , reference to or reliance on the information in thes Publication, whether based on warranty, contract, tort or any other legal theory and whether or not advised of the possibility of such damages.These calculation spreadsheets are provided to provide an “Operational level” of accuracy calculation based on rather broad assumptions (including but not limited to; temperatures, pressures, compositions, imperial curves, site conditions etc) and do not replace detailed and accurate Design Engineering taking into account actual process conditions, fluid properties, equipment condition or fowling and actual control set-point dead-band limitations.
The sample calculations, equations and spreadsheets presented herein were developed using examples published in the Engineering Data Book as published by the Gas Processor Suppliers Association as a service to the gas processing industry. All information and calculation formulae has been compiled and edited in cooperation with Gas Processors Association (GPA).While every effort has been made to present accurate and reliable technical information and calculation spreadsheets based on the GPSA Engineering Data Book sample calculations, the use of such information is voluntary and the GPA and GPSA do not guarantee the accuracy, completeness, efficacy or timeliness of such information. Reference herein to any specific commercial product, calculation method, process, or service by trade-name, trademark, and service mark manufacturer or otherwise does not constitute or imply endorsement, recommendation or favoring by the GPA and/or GPSA.
In no event will the GPA or GPSA and their members be liable for any damages whatsoever (including without limitation, those resulting from lost profits, lost data or business interruption) arising from the use, inability to , reference to or reliance on the information in thes Publication, whether based on warranty, contract, tort or any other legal theory and whether or not advised of the possibility of such damages.These calculation spreadsheets are provided to provide an “Operational level” of accuracy calculation based on rather broad assumptions (including but not limited to; temperatures, pressures, compositions, imperial curves, site conditions etc) and do not replace detailed and accurate Design Engineering taking into account actual process conditions, fluid properties, equipment condition or fowling and actual control set-point dead-band limitations.
While every effort has been made to present accurate and reliable technical information and calculation spreadsheets based on the GPSA Engineering Data Book sample calculations, the use of such information is voluntary and the GPA and GPSA do not guarantee the accuracy, completeness, efficacy or timeliness of such information. Reference herein to any specific commercial product, calculation method, process, or service by trade-name, trademark, and service mark manufacturer or otherwise does not constitute or imply endorsement, recommendation or favoring by the GPA and/or GPSA.
These calculation spreadsheets are provided to provide an “Operational level” of accuracy calculation based on rather broad assumptions (including but not limited to; temperatures, pressures, compositions, imperial curves, site conditions etc) and do not replace detailed and accurate Design Engineering taking into account actual process conditions, fluid properties, equipment condition or fowling and actual control set-point dead-band limitations.
While every effort has been made to present accurate and reliable technical information and calculation spreadsheets based on the GPSA Engineering Data Book sample calculations, the use of such information is voluntary and the GPA and GPSA do not guarantee the accuracy, completeness, efficacy or timeliness of such information. Reference herein to any specific commercial product, calculation method, process, or service by trade-name, trademark, and service mark manufacturer or otherwise does not constitute or imply endorsement, recommendation or favoring by the GPA and/or GPSA.
FIG. 25-1Nomenclature
= P* =
L = R =
N = T =
ω = acentric factor V =
P = absolute pressure, psia =
= convergence pressure, psia =
Subscripts i =
KEY= Example calculation from the book= Application worksheet for user to fill out= Numbers that must be filled in according to the user's data and specific situation (also includes numbers from graphs and charts)
Ki equilibrium ratio, yi/xi
ratio of moles of liquid to moles of total mixture
mole fraction in the total mixture or system
xi
Pk yi
FIG. 25-1Nomenclature
vapor pressure, psia
temperature, °R or °F
ratio of moles of vapor to moles of total pressure
mole fraction of component I in the liquid phase
mole fraction of component I in the vapor phase
component
Numbers that must be filled in according to the user's data and specific situation (also includes numbers from graphs and charts)
universal gas constant, (psia · cu ft)/(lbmole · °R)
Temperature = 100 °F TemperaturePressure = 800 psia Pressure
Find the temperature at which the gas starts to condense. (Dew Point) Find the temperature at which the gas starts to condense. (Dew Point)
Solution Steps Solution Steps
Column1 2 3 4 5
Feed 1000 1000-50 °F -40 °F
0.854 2.25 0.380 2.3 0.371
0.051 0.787 0.065 0.844 0.060
0.063 0.275 0.229 0.31 0.203
0.032 0.092 0.348 0.105 0.305S = 1.000 1.021 0.940 S =
-47.4 °F
NOTE: Table 25-4 in the 13th edition is reproduced below:
Column1 2 3 4 5
Feed 1000 1000-50 °F -40 °F
0.854 2.25 0.313 2.3 0.311
0.051 0.787 0.059 0.844 0.056
0.063 0.275 0.229 0.31 0.210
0.032 0.092 0.457 0.105 0.400S = 1.000 1.058 0.977
-42.8 °F
Example 25-3 -- Dew Point Calculation Application 25-3 -- Dew Point CalculationA gas stream is being cooled in a heat exchanger. The initial conditions are:
A gas stream is being cooled in a heat exchanger. The initial conditions are:
estimated dew point temperatures. By interpolation, the temperature at which Ni/Ki = 1.00 is estimated below.
estimated dew point temperatures. By interpolation, the temperature at which Ni/Ki = 1.00 is estimated below. [Note: The trial values used for dew point temperature should bracket
S(Ni/Ki) = 1.00. If not, chose different values.][Note: The trial values used for dew point temperature should bracket S(Ni/Ki) = 1.00. If not, chose different values.]
Pk = Pk =
Ni Ki Ni/Ki Ki Ni/Ki
CH4 CH4
CO2* CO2*
C2H6 C2H6
C3H8 C3H8
* KCO2 = sq.rt. (KC1 · KC2) * KCO2 = sq.rt. (KC1 · KC2)
Linear interpolation: Tdew = Linear interpolation: Tdew =
heavy fraction as a pseudocomponent such as hexane or octane will have a significant effect on dew point calculations.
heavy fraction as a pseudocomponent such as hexane or octane will have a significant effect on dew point calculations.
The reason for N i/K i differences between this table and the one above is not known.
Pk = Pk =
Ni Ki Ni/Ki Ki Ni/Ki
CH4
CO2*
C2H6
C3H8
* KCO2 = sq.rt. (KC1 · KC2)
Linear interpolation: Tdew =
The sample calculations, equations and spreadsheets presented herein were developed using examples published in the Engineering Data Book as published by the Gas Processor Suppliers Association as a service to the gas processing industry. All information and calculation formulae has been compiled and edited in cooperation with Gas Processors Association (GPA).While every effort has been made to present accurate and reliable technical information and calculation spreadsheets based on the GPSA Engineering Data Book sample calculations, the use of such information is voluntary and the GPA and GPSA do not guarantee the accuracy, completeness, efficacy or timeliness of such information. Reference herein to any specific commercial product, calculation method, process, or service by trade-name, trademark, and service mark manufacturer or otherwise does not constitute or imply endorsement, recommendation or favoring by the GPA and/or GPSA.The Calculation Spreadsheets are provided without warranty of any kind including warranties of accuracy or reasonableness of factual or scientific assumptions, studies or conclusions, or merchantability, fitness for a particular purpose or non-infringement of intellectual property.In no event will the GPA or GPSA and their members be liable for any damages whatsoever (including without limitation, those resulting from lost profits, lost data or business interruption) arising from the use, inability to , reference to or reliance on the information in thes Publication, whether based on warranty, contract, tort or any other legal theory and whether or not advised of the possibility of such damages.These calculation spreadsheets are provided to provide an “Operational level” of accuracy calculation based on rather broad assumptions (including but not limited to; temperatures, pressures, compositions, imperial curves, site conditions etc) and do not replace detailed and accurate Design Engineering taking into account actual process conditions, fluid properties, equipment condition or fowling and actual control set-point dead-band limitations.
heavy fraction as a pseudocomponent such as hexane or octane will have a significant effect on dew point calculations.
= 100 °F= 800 psia
Find the temperature at which the gas starts to condense. (Dew Point)
Column1 2 3 4 5
Feed 1000 1000-50 °F -40 °F
0.854 2.25 0.380 2.3 0.371
0.051 0.787 0.065 0.844 0.060
0.063 0.275 0.229 0.31 0.203
0.032 0.092 0.348 0.105 0.3051.000 1.021 0.940
-47.4 °F
Application 25-3 -- Dew Point CalculationA gas stream is being cooled in a heat exchanger. The initial conditions
estimated dew point temperatures. By interpolation, the temperature at /Ki = 1.00 is estimated below. [Note: The trial values used for dew point temperature should bracket
(Ni/Ki) = 1.00. If not, chose different values.]
Pk = Pk =
Ni Ki Ni/Ki Ki Ni/Ki
* KCO2 = sq.rt. (KC1 · KC2)
Linear interpolation: Tdew =
heavy fraction as a pseudocomponent such as hexane or octane will have a significant effect on dew point calculations.
The sample calculations, equations and spreadsheets presented herein were developed using examples published in the Engineering Data Book as published by the Gas Processor Suppliers Association as a service to the gas processing industry. All information and calculation formulae has been compiled and edited in cooperation with Gas Processors Association (GPA).While every effort has been made to present accurate and reliable technical information and calculation spreadsheets based on the GPSA Engineering Data Book sample calculations, the use of such information is voluntary and the GPA and GPSA do not guarantee the accuracy, completeness, efficacy or timeliness of such information. Reference herein to any specific commercial product, calculation method, process, or service by trade-name, trademark, and service mark manufacturer or otherwise does not constitute or imply endorsement, recommendation or favoring by the GPA and/or GPSA.The Calculation Spreadsheets are provided without warranty of any kind including warranties of accuracy or reasonableness of factual or scientific assumptions, studies or conclusions, or merchantability, fitness for a particular purpose or non-infringement of intellectual property.In no event will the GPA or GPSA and their members be liable for any damages whatsoever (including without limitation, those resulting from lost profits, lost data or business interruption) arising from the use, inability to , reference to or reliance on the information in thes Publication, whether based on warranty, contract, tort or any other legal theory and whether or not advised of the possibility of such damages.These calculation spreadsheets are provided to provide an “Operational level” of accuracy calculation based on rather broad assumptions (including but not limited to; temperatures, pressures, compositions, imperial curves, site conditions etc) and do not replace detailed and accurate Design Engineering taking into account actual process conditions, fluid properties, equipment condition or fowling and actual control set-point dead-band limitations.
The sample calculations, equations and spreadsheets presented herein were developed using examples published in the Engineering Data Book as published by the Gas Processor Suppliers Association as a service to the gas processing industry. All information and calculation formulae has been compiled and edited in cooperation with Gas Processors Association (GPA).While every effort has been made to present accurate and reliable technical information and calculation spreadsheets based on the GPSA Engineering Data Book sample calculations, the use of such information is voluntary and the GPA and GPSA do not guarantee the accuracy, completeness, efficacy or timeliness of such information. Reference herein to any specific commercial product, calculation method, process, or service by trade-name, trademark, and service mark manufacturer or otherwise does not constitute or imply endorsement, recommendation or favoring by the GPA and/or GPSA.The Calculation Spreadsheets are provided without warranty of any kind including warranties of accuracy or reasonableness of factual or scientific assumptions, studies or conclusions, or merchantability, fitness for a particular purpose or non-infringement of intellectual property.In no event will the GPA or GPSA and their members be liable for any damages whatsoever (including without limitation, those resulting from lost profits, lost data or business interruption) arising from the use, inability to , reference to or reliance on the information in thes Publication, whether based on warranty, contract, tort or any other legal theory and whether or not advised of the possibility of such damages.These calculation spreadsheets are provided to provide an “Operational level” of accuracy calculation based on rather broad assumptions (including but not limited to; temperatures, pressures, compositions, imperial curves, site conditions etc) and do not replace detailed and accurate Design Engineering taking into account actual process conditions, fluid properties, equipment condition or fowling and actual control set-point dead-band limitations.
The sample calculations, equations and spreadsheets presented herein were developed using examples published in the Engineering Data Book as published by the Gas Processor Suppliers Association as a service to the gas processing industry. All information and calculation formulae has been compiled and edited in cooperation with Gas Processors Association (GPA).While every effort has been made to present accurate and reliable technical information and calculation spreadsheets based on the GPSA Engineering Data Book sample calculations, the use of such information is voluntary and the GPA and GPSA do not guarantee the accuracy, completeness, efficacy or timeliness of such information. Reference herein to any specific commercial product, calculation method, process, or service by trade-name, trademark, and service mark manufacturer or otherwise does not constitute or imply endorsement, recommendation or favoring by the GPA and/or GPSA.
In no event will the GPA or GPSA and their members be liable for any damages whatsoever (including without limitation, those resulting from lost profits, lost data or business interruption) arising from the use, inability to , reference to or reliance on the information in thes Publication, whether based on warranty, contract, tort or any other legal theory and whether or not advised of the possibility of such damages.These calculation spreadsheets are provided to provide an “Operational level” of accuracy calculation based on rather broad assumptions (including but not limited to; temperatures, pressures, compositions, imperial curves, site conditions etc) and do not replace detailed and accurate Design Engineering taking into account actual process conditions, fluid properties, equipment condition or fowling and actual control set-point dead-band limitations.
While every effort has been made to present accurate and reliable technical information and calculation spreadsheets based on the GPSA Engineering Data Book sample calculations, the use of such information is voluntary and the GPA and GPSA do not guarantee the accuracy, completeness, efficacy or timeliness of such information. Reference herein to any specific commercial product, calculation method, process, or service by trade-name, trademark, and service mark manufacturer or otherwise does not constitute or imply endorsement, recommendation or favoring by the GPA and/or GPSA.
These calculation spreadsheets are provided to provide an “Operational level” of accuracy calculation based on rather broad assumptions (including but not limited to; temperatures, pressures, compositions, imperial curves, site conditions etc) and do not replace detailed and accurate Design Engineering taking into account actual process conditions, fluid properties, equipment condition or fowling and actual control set-point dead-band limitations.
While every effort has been made to present accurate and reliable technical information and calculation spreadsheets based on the GPSA Engineering Data Book sample calculations, the use of such information is voluntary and the GPA and GPSA do not guarantee the accuracy, completeness, efficacy or timeliness of such information. Reference herein to any specific commercial product, calculation method, process, or service by trade-name, trademark, and service mark manufacturer or otherwise does not constitute or imply endorsement, recommendation or favoring by the GPA and/or GPSA.
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