School: Engineering
This unit information may be updated and amended immediately prior to semester. To ensure you have the correct outline, please check it again at the beginning of semester.
Unit Title
Heat and Mass Transfer
Unit Code
ENS3110
Year
2016
Enrolment Period
1
Version
1
Credit Points
15
Full Year Unit
N
Mode of Delivery
On Campus
Description
This unit aims to establish a thorough understanding of, and analytical skills in, fundamental heat and mass transfer phenomena and their application to creative and effective design of industrial processes and equipment and problem-solving in environmental systems. The underlying principles and their applications will be illustrated by the study and analysis of selected heat and mass transfer unit operations used across a range of process industries, as well as heat and mass transfer applications in environmental systems.
Prerequisite Rule
Students must pass 1 units from ENS2160
Learning Outcomes
On completion of this unit students should be able to:
- Assess the limitations and constraints inherent in analytical methods and engineering data used to design and analyse heat and mass transfer processes and equipment.
- Correctly identify the mechanisms of heat and mass transfer occurring in a range of contexts and their relative significance.
- Demonstrate an ability to effectively communicate results of engineering analysis to other engineers, showing the logical flow of calculations and consequent conclusions by making appropriate use of mathematical, visual/graphical and text descriptions.
- Explain the fundamental principles associated with heat and mass transfer phenomena and demonstrate their application in a wide range of application areas.
- Interpret results of an engineering analysis to identify significant operating or design parameters and how they can be used to improve performance.
Unit Content
- Heat exchangers, design and analysis, including log mean and NTU methods.
- Heat transfer via natural and forced convection, internal and external.
- Mass transfer models, diffusion, diffusivity and mass transfer coefficients.
- Mass transfer operations and unit conversions.
- One-dimensional steady state conduction, resistance in series, heat transfer to and from pipes, fins and other objects.
- Operating and equilibrium lines.
- Radiative heat transfer, view factors, chemical and environmental engineering applications.
- Review of heat transfer: physical rate processes, modes of heat transfer (conduction, convection, radiation), heat equations and thermal properties.
- Stage and differential analysis in mass transfer operations, with engineering applications.
- Two and three dimensional steady state conduction and also transient heat transfer.
Additional Learning Experience Information
Lectures, tutorials, group based laboratory work and site visits.
Assessment
GS1 GRADING SCHEMA 1 Used for standard coursework units
Students please note: The marks and grades received by students on assessments may be subject to further moderation. All marks and grades are to be considered provisional until endorsed by the relevant Board of Examiners.
ON CAMPUSType | Description | Value |
---|
Report | Laboratory and site reports | 30% |
Test | Mid-semester test | 20% |
Examination | End of semester examination | 50% |
Text References
- ^ Welty, J.R., Wicks, C.E., Wilson, R.E. & Rorrer, G. (2008). Fundamentals of momentum, heat and mass transfer (5th ed.). New York: John Wiley and Sons.
- Cengel, Y., Ghajar, A., (2010). Heat and mass transfer: fundamentals and applications (4th ed.). Boston: McGraw Hill Sience/Eng/Maths.
- Middleman, S. (1997). An introduction to heat and mass transfer: principles of analysis and design. New York: John Wiley and Sons.
- Incropera, F.P., DeWitt, D.P., Bergman, T.L., & Lavine, A.S. (2011). Fundamentals of heat and mass transfer (7th ed.). New York: John Wiley and Sons.
^ Mandatory reference
Disability Standards for Education (Commonwealth 2005)
For the purposes of considering a request for Reasonable Adjustments under the Disability Standards for Education (Commonwealth 2005), inherent requirements for this subject are articulated in the Unit Description, Learning Outcomes and Assessment Requirements of this entry. The University is dedicated to provide support to those with special requirements. Further details on the support for students with disabilities or medical conditions can be found at the Access and Inclusion website.
Academic Misconduct
Edith Cowan University has firm rules governing academic misconduct and there are substantial penalties that can be applied to students who are found in breach of these rules. Academic misconduct includes, but is not limited to:
- plagiarism;
- unauthorised collaboration;
- cheating in examinations;
- theft of other students' work;
Additionally, any material submitted for assessment purposes must be work that has not been submitted previously, by any person, for any other unit at ECU or elsewhere.
The ECU rules and policies governing all academic activities, including misconduct, can be accessed through the ECU website.
ENS3110|1|1
School: Engineering
This unit information may be updated and amended immediately prior to semester. To ensure you have the correct outline, please check it again at the beginning of semester.
Unit Title
Heat and Mass Transfer
Unit Code
ENS3110
Year
2016
Enrolment Period
2
Version
1
Credit Points
15
Full Year Unit
N
Mode of Delivery
On Campus
Description
This unit aims to establish a thorough understanding of, and analytical skills in, fundamental heat and mass transfer phenomena and their application to creative and effective design of industrial processes and equipment and problem-solving in environmental systems. The underlying principles and their applications will be illustrated by the study and analysis of selected heat and mass transfer unit operations used across a range of process industries, as well as heat and mass transfer applications in environmental systems.
Prerequisite Rule
Students must pass 1 units from ENS2160
Learning Outcomes
On completion of this unit students should be able to:
- Assess the limitations and constraints inherent in analytical methods and engineering data used to design and analyse heat and mass transfer processes and equipment.
- Correctly identify the mechanisms of heat and mass transfer occurring in a range of contexts and their relative significance.
- Demonstrate an ability to effectively communicate results of engineering analysis to other engineers, showing the logical flow of calculations and consequent conclusions by making appropriate use of mathematical, visual/graphical and text descriptions.
- Explain the fundamental principles associated with heat and mass transfer phenomena and demonstrate their application in a wide range of application areas.
- Interpret results of an engineering analysis to identify significant operating or design parameters and how they can be used to improve performance.
Unit Content
- Heat exchangers, design and analysis, including log mean and NTU methods.
- Heat transfer via natural and forced convection, internal and external.
- Mass transfer models, diffusion, diffusivity and mass transfer coefficients.
- Mass transfer operations and unit conversions.
- One-dimensional steady state conduction, resistance in series, heat transfer to and from pipes, fins and other objects.
- Operating and equilibrium lines.
- Radiative heat transfer, view factors, chemical and environmental engineering applications.
- Review of heat transfer: physical rate processes, modes of heat transfer (conduction, convection, radiation), heat equations and thermal properties.
- Stage and differential analysis in mass transfer operations, with engineering applications.
- Two and three dimensional steady state conduction and also transient heat transfer.
Additional Learning Experience Information
Lectures, tutorials, group based laboratory work and site visits.
Assessment
GS1 GRADING SCHEMA 1 Used for standard coursework units
Students please note: The marks and grades received by students on assessments may be subject to further moderation. All marks and grades are to be considered provisional until endorsed by the relevant Board of Examiners.
ON CAMPUSType | Description | Value |
---|
Report | Laboratory and site reports | 30% |
Test | Mid-semester test | 20% |
Examination | End of semester examination | 50% |
Text References
- ^ Welty, J.R., Wicks, C.E., Wilson, R.E. & Rorrer, G. (2008). Fundamentals of momentum, heat and mass transfer (5th ed.). New York: John Wiley and Sons.
- Incropera, F.P., DeWitt, D.P., Bergman, T.L., & Lavine, A.S. (2011). Fundamentals of heat and mass transfer (7th ed.). New York: John Wiley and Sons.
- Middleman, S. (1997). An introduction to heat and mass transfer: principles of analysis and design. New York: John Wiley and Sons.
- Cengel, Y., Ghajar, A., (2010). Heat and mass transfer: fundamentals and applications (4th ed.). Boston: McGraw Hill Science/Eng/Maths.
^ Mandatory reference
Disability Standards for Education (Commonwealth 2005)
For the purposes of considering a request for Reasonable Adjustments under the Disability Standards for Education (Commonwealth 2005), inherent requirements for this subject are articulated in the Unit Description, Learning Outcomes and Assessment Requirements of this entry. The University is dedicated to provide support to those with special requirements. Further details on the support for students with disabilities or medical conditions can be found at the Access and Inclusion website.
Academic Misconduct
Edith Cowan University has firm rules governing academic misconduct and there are substantial penalties that can be applied to students who are found in breach of these rules. Academic misconduct includes, but is not limited to:
- plagiarism;
- unauthorised collaboration;
- cheating in examinations;
- theft of other students' work;
Additionally, any material submitted for assessment purposes must be work that has not been submitted previously, by any person, for any other unit at ECU or elsewhere.
The ECU rules and policies governing all academic activities, including misconduct, can be accessed through the ECU website.
ENS3110|1|2