Aug 18, 2022
 HELP 2020-2021 Undergraduate Academic Catalog [ARCHIVED CATALOG] Print-Friendly Page (opens a new window)

# BE 3500 - Bio-thermal-fluid Transport I

4 lecture hours 0 lab hours 4 credits
Course Description
This is the first of a two-part course sequence in bio-thermal-fluid transport. Specific topics that are covered include thermodynamics, including property determination, phase diagrams, first and second law applications, and efficiency calculations; psychrometrics; and introductory topics in fluid mechanics. (prereq: none)
Course Learning Outcomes
Upon successful completion of this course, the student will be able to:
• Define thermodynamics and give examples of problems that can be solved using thermodynamic principles
• Determine the properties of pure substances using property tables, property diagrams and software
• Use the phase rule to determine the number of degrees of freedom for a non-reacting mixture at equilibrium
• Use phase diagrams, property tables, and software to determine the phases present in a mixture, their relative abundances and the properties of the mixture
• Determine whether the ideal gas equation of state is appropriate for a given system
• Determine the properties of pure ideal gases and mixtures of ideal gases
• State the First Law of thermodynamics and apply it to solve closed system engineering problems and analyze and design steady flow devices relevant to biomedical engineering
• State the Second Law of thermodynamics and use it to determine limits for thermodynamic cycles and assess performance of steady flow devices
• Use psychrometric analysis to define the vapor content of atmospheric air and apply this to air conditioning processes
• Describe basic fluid behavior.
• Define viscosity and describe Newtonian fluid behavior
• Solve basic fluid statics problems

Prerequisites by Topic
• Performing single variable integration
• Evaluating and interpreting first partial derivatives

Course Topics
• Thermodynamic definitions; pressure definition and manometry; energy definition and modes of energy transfer
• Properties of pure substances; phases and property diagrams; using property tables and software to determine properties; determination of phase; applying the ideal-gas equation of state
• Boundary work, closed system energy balance, specific heats
• Conservation of mass, flow energy, energy balance application to control volumes and steady flow devices
• Thermodynamic cycles and the second law of thermodynamics; irreversibilities; Carnot cycles and Carnot efficiency
• Entropy; isentropic efficiency for steady flow devices
• Gas mixtures; psychrometrics and analysis of air conditioning processes
• Introduction to fluid phenomena and fluid statics
• Exams

Coordinator
Dr. Charles Tritt