Single Phase Mass Balance

Solve Mass Balance Problems involving Ideal and Real Gases in a very practical way!

What you'll learn

Apply Mass Balances to Single-Phase Systems

Solve Mass Balance Problems involving Real Gases

Solve Mass Balance Problems involving Ideal Gases

Solve Mass Balance Problems involving either Solids or Liquids

Learn the different ways a Real Gas may be modeled

Understand the Compressibility Factor "Z" and the Law of Corresponding States

Use the Ideal Gas Law for Mass Balances

Understand the difference between Vapor and Gas

Identify the Critical Point in a Phase-Diagram

Apply the Virial Equation to a Gas

Understand the concept of Standard Conditions of Temperature and Pressure

Requirements

It is HIGHLY recommended you take the "Introduction to Mass Balance" Course

Understand the basic concepts of mass balance

It's also recommended that the student has already worked with Ideal Gases

Basic Math Operations

Description

Welcome to the Single Phase Mass Balance Course! I designed this course is for general engineering fields. Chemical and Process Engineers will find it very relevant for their study curriculum but even Mechanical or Industrial Engineers will find it very interesting! By the end of this course you will learn: The importance of Phases when Solving Mass Balance Problems Application of constant densities of Solid and Liquids in Chemical Proceses How to model Ideal Gases with the Ideal Gas Law Why are Standard Conditions of Temperature and Pressure used in the industry How to model Real Gases with the Virial Equation How to model Real Gases with the Z-Compressibility Factor Chart How to model Real Gas Mixtures with the Kay Rule By the end of the Course you will be able to: Solve Mass Balance Problems of many real-life Chemical Processes involving Single-Phase Systems Model Ideal Gases vs. Real Gases The course is structured as follow: 6 Sections of Theory and Applied Examples (Video-Based!) 22 Mass Balance Solved Exercises! 3 Quizes for Learning Review Support on the Discussion Board! This is a very important Subject in Engineering and is the basis of further courses such as: Energy Balance and Thermodynamic Heat and Mass Transfer Operations and Unit Operations Reactor Engineering and Plant Design I teach this course for about $400 per semester. You will get it as low as $25 for a LIFETIME! Take the course and you will have a greater advantage than your classmates to get a better grade on your university courses! NOTE: This is the continuation of my other course MB1: Introduction to Mass Balance. I highly recommend you take first the other course in order to get the best of this course! The Course Curriculum may be seen below!

Overview

Section 1: Course Overview

Lecture 1 Course Overview and Introduction

Section 2: Solids and Liquids

Lecture 2 Phases Theory

Lecture 3 Solid and Liquids in Mass Balance

Lecture 4 Solid and Liquids - Example #1

Lecture 5 Solid and Liquids - Example #2

Lecture 6 Solid and Liquids - Example #3

Lecture 7 Estimating Densities

Lecture 8 EXERCISES#01 - Bulk and Absolute Densities in Solid and Liquids

Lecture 9 EXERCISES#02 - Density of a Slurry (Part 1)

Lecture 10 EXERCISES#02 - Density of a Slurry (Part 2)

Section 3: Ideal Gases and Mass Balances

Lecture 11 Gases

Lecture 12 Ideal Gas Model

Lecture 13 Ideal Gas Limitants

Lecture 14 Why Ideal Gas in Mass Balance?

Lecture 15 Ideal Gas: Example

Lecture 16 Standard Conditions: Temperature and Pressure

Lecture 17 Standard Cubic Meter per Hour (SCMH)

Lecture 18 Standard Conditions: Example #1

Lecture 19 Standard Conditions: Example #2

Lecture 20 Standard Conditions: Example #3

Lecture 21 Ideal Gas Mixture: Partial Pressures

Lecture 22 Example of Ideal Gases in Mass Balance

Lecture 23 EXERCISES#03 - Basic Ideal Gas Calculation

Lecture 24 EXERCISES#04 - Ideal Gas Constant (R) Exercises

Lecture 25 EXERCISES#05 - Flow Rate of a Gas (Density Exercise)

Lecture 26 EXERCISES#06 - Specific Gravity of Gases

Lecture 27 EXERCISES#07 - Gas theft. Applying the Ideal Gas law to identify the theft.

Lecture 28 EXERCISES#08 - Combustion of a Gas

Lecture 29 EXERCISES#09 - Calculating de Volume Expansion of Hydrazine

Lecture 30 EXERCISES#10 - Vaporization of Acetone by Nitrogen

Lecture 31 EXERCISES#11 - Chlorine Tank Storage

Lecture 32 EXERCISES#12 - Production of Sulfuric Acid in Equilibrium (Part 1)

Lecture 33 EXERCISES#12 - Production of Sulfuric Acid in Equilibrium (Part 2)

Lecture 34 EXERCISES#12 - Production of Sulfuric Acid in Equilibrium (Part 3)

Lecture 35 EXERCISES#13 - Ideal Gases in Multiple Equilibria

Section 4: Real Gases (Theory)

Lecture 36 Real Gases

Lecture 37 Critical Point

Lecture 38 Reduced Conditions

Lecture 39 Gas vs. Vapor

Section 5: Mass Balance with Real Gases

Lecture 40 Virial Equation Introduction

Lecture 41 Virial Equation: Example

Lecture 42 Other Equations

Lecture 43 Compressibility Factor (Z)

Lecture 44 Example: Compressibility Factor

Lecture 45 Newton's Corrections

Lecture 46 Compressibility Chart

Lecture 47 Law of Corresponding States

Lecture 48 Factor Z Example

Lecture 49 Mixture of Real Gases: Kay Rule

Lecture 50 Kay Rule Example

Lecture 51 EXERCISES#14 - Volume of a Gas Modeled by the Virial Equation

Lecture 52 EXERCISES#15 - Compressibility Factor "Z" for Real Gases

Lecture 53 EXERCISES#16 - Compressibility of Oxygen and Newton Correction

Lecture 54 EXERCISES#17 - Nitrogen Purge System

Lecture 55 EXERCISES#18 - Liquid Nitrogen Flashing to Real Gas

Lecture 56 EXERCISES#19 - Mixture of Gases and the Kay Rule

Lecture 57 EXERCISES#20 - Compression of a Mixture of Gases

Lecture 58 EXERCISES#21 - Production of Methanol in Gaseous Phase

Lecture 59 EXERCISES#22 - Mixture of Gases flowing in a Pipeline

Section 6: Course Conlusion

Lecture 60 Conclusion and Final Notes

Lecture 61 Please leave a Review!

This course is recommended for process engineers, chemical engineers, and even mechanical or industrial engineers,Any engineering field within the study of Gas Modelation (Ideal and Real Gases)