Power Cycles and Combustion Analysis Webinar
English
30-Day Money Back Guarantee
Full Lifetime Access
Self-Paced
Finish in
60 mins!
Finish in
60 mins!
Made for for
Employees
only
Employees
only
Certificate
of Completion
of Completion
Mobile -
Friendly
Access
Friendly
Access
What you'll learn
Basic energy conversion engineering assumptions and equations
Know basic elements of Carnot Cycle, Brayton Cycle, Otto Cycle, Diesel Cycle, combustion and expansion processes and their T - s, p - V and h - T diagrams
Be familiar with Carnot Cycle, Brayton Cycle, Otto Cycle, Diesel Cycle and combustion operation
Understand general performance trends
Skills covered in this course
Description
In this webinar material, the student gets familiar with the ideal simple and basic power cycles, combustion, their T - s, p - V and h - T diagrams, operation and major performance trends when air, argon, helium and nitrogen are considered as the working fluid.
Performance Objectives:
Introduce basic energy conversion engineering assumptions and equations
Know basic elements of Carnot Cycle, Brayton Cycle, Otto Cycle, Diesel Cycle and combustion and their T - s, p - V and h - T diagrams
Be familiar with Carnot Cycle, Brayton Cycle, Otto Cycle, Diesel Cycle and combustion operation
Understand general Carnot Cycle, Brayton Cycle, Otto Cycle, Diesel Cycle and combustion performance trends
Introduce basic energy conversion engineering assumptions and equations
Know basic elements of Carnot Cycle, Brayton Cycle, Otto Cycle, Diesel Cycle and combustion and their T - s, p - V and h - T diagrams
Be familiar with Carnot Cycle, Brayton Cycle, Otto Cycle, Diesel Cycle and combustion operation
Understand general Carnot Cycle, Brayton Cycle, Otto Cycle, Diesel Cycle and combustion performance trends
Table of Contents
Carnot Cycle
Analysis
Assumptions
Governing Equations
Input Data
Results
Conclusions
Brayton Cycle (Gas Turbine) for Power Application
Analysis
Assumptions
Governing Equations
Input Data
Results
Conclusions
Otto Cycle
Analysis
Assumptions
Governing Equations
Input Data
Results
Conclusions
Diesel Cycle
Analysis
Assumptions
Governing Equations
Input Data
Results
Conclusions
Combustion
Analysis
Case Study A
Case Study B
Case Study C
Case Study D
Assumptions
Governing Equations
Input Data
Results
Case Study A
Case Study B
Case Study C
Case Study D
Figures
Conclusions
Author
His over 35 years engineering experience includes performing analytical modeling and computer modeling of physical properties, power cycles, power cycle components/processes and compressible flow. Also, conducting conceptual design, analysis and evaluation of energy conversion systems for basic and simple power and propulsion cycles.
