Use Spreadsheet and Adjust tools in Aspen HYSYS - Lecture # 14
Learn to use spreadsheet and adjust tools to meet specifications of your under-study separation process in Aspen HYSYS. This tutorial is focused on removal of hydrogen stream from the mixture, and the required specifications are met using these two tools.
Please do watch, like, and share the video, and subscribe the channel "AspenTech Channel".
Problem Statement:
The feed stream contains 55 mol % hydrogen, 25 mol % ethylene, 10 mol % methane and 10 mol % ethane. The flowrate of feedstream is 1000 kgmole/h. The feed is entering the cooler at -50C and 20 bar. The objective of the simulation is to remove hydrogen from the mixture (using cooler and separator) under two conditions:
1. Ethylene present in hydrogen stream should be less than 2%.
2. The mole fraction of hydrogen in the separated stream should be less than 0.02.
#Spreadsheet
#Adjust
#AspenHYSYS
#Tools
Видео Use Spreadsheet and Adjust tools in Aspen HYSYS - Lecture # 14 канала Chem Engg & Aspen Channel - Dr. M. Haris Hamayun
Please do watch, like, and share the video, and subscribe the channel "AspenTech Channel".
Problem Statement:
The feed stream contains 55 mol % hydrogen, 25 mol % ethylene, 10 mol % methane and 10 mol % ethane. The flowrate of feedstream is 1000 kgmole/h. The feed is entering the cooler at -50C and 20 bar. The objective of the simulation is to remove hydrogen from the mixture (using cooler and separator) under two conditions:
1. Ethylene present in hydrogen stream should be less than 2%.
2. The mole fraction of hydrogen in the separated stream should be less than 0.02.
#Spreadsheet
#Adjust
#AspenHYSYS
#Tools
Видео Use Spreadsheet and Adjust tools in Aspen HYSYS - Lecture # 14 канала Chem Engg & Aspen Channel - Dr. M. Haris Hamayun
Показать
Комментарии отсутствуют
Информация о видео
5 июля 2020 г. 14:00:38
00:08:01
Другие видео канала
Chemical Reaction Engineering - Lecture # 8: Reactors in Series & Space Time-Space Velocity Examples
CRE Lecture - Combining method of excess & integral method - Rate constant and Order of reaction
Comparison of CSTR and PFR using Aspen HYSYS - Lecture # 65
Chemical Reaction Engineering Lectures - Lecture # 40(a) - Numerical Method for Data Analysis #cre
How to calculate mole fraction, if you are given the % recovery in a short-cut distillation column?
Strategies for the successful simulation in Aspen - Lecture # 92
Isothermal CSTR Design - Example # 5.2 - Chemical Reaction Engineering Lectures - Lecture # 23(a)
Chemical Reaction Engineering Lectures - Selectivity, Yield, Conversion and their Importance #cre
Chemical Reaction Engineering - Building Block # 3 (Stoichiometry) - Example # 4.5 - Lecture 17
Chemical Reaction Engineering Lectures - Lecture 45 - Selectivity for Parallel Reactions #cre
Simulation of DSTWU in Aspen Plus for the separation of binary mixture - Lecture # 53
Question and Answer Session with Aspentech Channel
Chemical Reaction Engineering - Lecture # 10: Elementary & Non-Elementary Rate Law
Simulation of Stream Saturator in Aspen HYSYS - Humidity Aspect - Lecture # 93
Chemical Reaction Engineering - Lecture # 2 - General Mole Balance, Derivation for Batch Reactor
Simulation of Short-cut Distillation Column (DSTWU) in Aspen Plus - Lecture # 52
Chemical Reaction Engineering|Derivations for isothermal CSTRs in series and parallel|Lecture # 22
Eric Carlson Recommendation for the selection of Thermodynamic Property Package #chemicalsimulation
Chemical Reaction Engineering Lectures - Lecture # 40(b) - Numerical Method for Data Analysis #cre
Chemical Reaction Engineering - Method of Half Life - Collection & Analysis of Rate Data #cre
Lecture # 100 on Aspentech Channel - Retrograde Behavior - Aspen HYSYS