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Introduction to Energy

Open and Closed Systems

Problem Solving Approach

What is Enthalpy?

Adiabatic Compression of an Ideal Gas

Enthalpy Change for an Ideal Gas

Energy Balance on a Human

Gas Expansion From a Tank

Energy Balance on Open System (PAV Device) (BIO)

Material & Energy Balances in a Reactor with Heat Exchange (Interactive Simulation)

How to Use Steam Tables

Introduction to Steam Tables

Introduction to Steam Tables 2

Steam Tables: Interpolation

Steam Table Examples

Compare Steam Tables to Ideal Gas Law

Water Properties from Steam Tables

Steam Tables: Constant Volume Process

Quality of Steam

Quality of Steam: Mass and Volume Fractions

Steam Tables: Calculating Quality

Energy Balance on a Heat Exchanger

Throttle Example: High-Pressure Liquid

Bernoulli Equation Example

Reference States for Enthalpy Calculations

Choosing a Reference State (Example)

Sensible Heat from Specific Enthalpy

How to Use a Psychrometric (Humidity) Chart

Psychrometric Chart Examples

Psychrometric Chart (Interactive Simulation)

Calculate Physical Properties using Humidity Charts

Humidity Chart: Adiabatic Humidification

Humidity Chart Example

Including a Phase Change in an Energy Balance

Latent Heat

Energy Balance on a Condenser

Adiabatic Mixing

Heat of Mixing

Isothermal Mixing

Heat of Reaction (from Heat of Formation)

Calculating Enthalpy Changes Using Heat of Reaction Method

Heat Removal from a Chemical Reactor

Heat of Combustion

Heats of Formation

Calculating Enthalpy Changes Using Heats of Formation Method

Thermochemistry of Solutions

Energy Balances with Unknown Outlet Conditions

Steam Reformer Material and Energy Balance

Unsteady-State Energy Balance (Steam Tables)

Properties of Liquid Water in Steam Tables

Throttle High-Pressure Liquid Water

Hess's Law

Heat of Combustion

Introduction to Energy

Open and Closed Systems

Changes in Pressure at Constant Temperature

Energy Balance on a Single-Phase System

Energy Balance on a Two-Component System with Phase Change

Hypothetical Process Paths

Adiabatic Flame Temperature Spreadsheet

Use Heat Capacity to Calculate Outlet Temperature

Calculate Heat Added Example

Calculate Heat of Reaction at an Elevated Temperature

How to Determine Heat of Reaction from Heat of Formation

Heat Capacity Introduction

Calculate Adiabatic Flame Temperature

Adiabatic Flame Temperature Introduction

Heat of Mixing and Deviations from Raoult's Law

Calculating Enthalpy and Entropy Using the NIST WebBook

Energy Balance on Reaction System Using Heat of Reaction

Energy Balance on Reaction System Using Heat of Formation

Introduction to the Mechanical Energy Balance Equation

Determine Height of Water Using Bernoulli Equation

Calculate Flow Rate Using Bernoulli Equation

Bernoulli Equation and Pipe Flow (Interactive Simulation)

Measuring Flow Rates with a Pitot Tube (Interactive Simulation)

Why a Solute Raises Boiling Point and Lowers Freezing Point

Adiabatic Flame Temperature Interactive Simulation

Ideal Gas - Pressure and Volume Dependence on Temperature

Heat of Reaction Temperature Dependence (Interactive Simulation)

Description:

Explore a comprehensive series of screencasts covering energy concepts, nonreactive energy balances, and reactive energy balances in Material and Energy Balances. Delve into topics such as open and closed systems, enthalpy, adiabatic compression, steam tables, psychrometric charts, heat of reaction, combustion, and more. Learn problem-solving approaches, how to use various tools and charts, and apply energy balance principles to real-world scenarios. Gain insights into thermochemistry, unsteady-state energy balances, and mechanical energy balance equations. Practice with interactive simulations on gas expansion, reactors with heat exchange, and adiabatic flame temperature. Benefit from corrected closed captioning throughout the 8-hour playlist, designed to enhance understanding of fundamental concepts in chemical engineering.

MEB - Energy Balances

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#Engineering #Chemical Engineering #Science #Chemistry #Physical Chemistry #Thermochemistry

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