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Project Based Learning of the Engineering Method V: A Hemodialysis System Design Project

Project Based Learning of the Engineering Method V: A Hemodialysis System Design Project. Young Engineers and Scientists Seminars Historical Electronics Museum Taryn Melkus Bayles, Ph.D. and Tania Monterastelli Chemical and Biochemical Engineering Department

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Project Based Learning of the Engineering Method V: A Hemodialysis System Design Project

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  1. Project Based Learning of the Engineering Method V: A Hemodialysis System Design Project Young Engineers and Scientists Seminars Historical Electronics Museum Taryn Melkus Bayles, Ph.D. and Tania Monterastelli Chemical and Biochemical Engineering Department University of Maryland Baltimore County December 13, 2007

  2. Reach for the Stars! Design Challenge Design and construct a self supporting structure for the least amount of money: Height (inches) Cost ($)

  3. EEK! Don’t Let It Leak! Design Challenge • Design and construct a device which will protect an egg when it is dropped from a 10 foot height. 1 . Mass (g) Cost ($)

  4. Separate This!! Design Challenge • Design and construct a device or series of devices to separate the blue sand from the mixture while maximizing the amount of blue sand recovered Final Mass (g) Initial Mass (g)

  5. Snap Krackle and Pop!! Design Challenge • Design and construct a device or series of devices to separate the Rice Krispies from the mixture of breakfast cereal while maximizing the amount of Rice Krispies recovered and minimizing cost

  6. YESS Program Mini Design Challenge: Let It Flow! • Design and construct an apparatus to transfer 500 ml of water a distance of 4 feet as quickly as possible while minimizing the cost of the apparatus. • Use only the materials provided • Three different diameter tubing (each are 2 feet long), funnels, plastic ties, rubber hose connectors, empty 500 ml bottle • You may not cut the tubing Final volume (ml) / initial volume (ml) [ time (s) x cost ($) ]

  7. Let It Flow! Design Challenge:

  8. Let it Flow!! Design Challenge • Design and construct a device which will transport 500 ml of water a distance of 4 feet as quickly as possible.

  9. YESS Program Design Projectwww.yesshem.com • Bragging Rights: Removal of impurities (mg) x Dialysate $ index x System $ Index

  10. YESS Program Design Projectwww.yesshem.com • How to Design a Hemodialysis System? • Factors that influence system performance: • Diffusion of impurities • Concentration • Temperature • Molecule size • Dialysis membranes • Pore size • Surface area • Simulated blood flow rate • Dialysate flow rate • Co-current/Counter-current flow

  11. YESS Program Design Projectwww.yesshem.com • Hemodialysis System Product Performance Bragging Rights Impurity removal - mg x dialysate cost index x device cost index • Cost Basis: • Choice of four membranes • 6.37 mm Diameter 14000 MW cut off $3.05/ft • 16 mm Diameter 14000 MW cut off $4.20/ft • 12.1 mm Diameter and 3500 MW cut off $2.84/ft • 16 mm Diameter and 3500 MW cut off $3.22/ft • Dialysate cost is $20.00 per liter • Cost index • Dialysate cost index • Minimum dialysate cost that meets design specifications Team dialysate cost • Device cost index • Minimum total system cost meets design specifications Team total system cost

  12. YESS Program Design Projectwww.yesshem.com • How do you make the Simulated Blood and the Dialysate Flow? • Pump • Gravity • Mathematical relationship Relates pressure, velocity and height Bernoulli equation

  13. YESS Program Design Project • Removal of Impurities • Tartrazine Dilution Standards

  14. YESS Program Design Project • Removal of Impurities • Visual Comparison is made • Concentration x Dialysate Quantity

  15. YESS Program Design Project • Examples of Hemodialysis Systems

  16. YESS Program Design Project • Examples of Hemodialysis Systems

  17. YESS Program Design Project • Examples of Hemodialysis Systems

  18. YESS Program Design Project

  19. YESS Program Design Project • For Tonight’s YESS Design Session • Design notebook • Complete Hemodialysis Design Project Sheet • Team Name, High School, Team Members & Emails • “Purchase” membrane • Membrane pore size, diameter – surface area, length, cost • Each team will be given 500 ml of simulated blood for practice testing • Old clothes • Gloves • How you will flow BOTH the blood and dialysate • How will you determine the amount of impurities that you have removed? • Volume of dialysate used • Concentration of dialysate at end of testing

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