Team 14026 – MSD I Presentation

1. Team 14026 – MSD I Presentation Mike Allocco, Soham Chakraborty, Leslie Havens, Danielle Koch, Andrew Miller, Kristeen Yee, Stephanie Zambito P14026_Detailed Design Review 12/05/13

2. Agenda • Sensor Placement • Pressure Sensors • Flow Sensors • Bill of Materials • Budget • Test Plan • Risk Assessment • Plan for MSD II • Problem Statement • Engineering Needs and Requirements • Functional Decomposition • Week 6 System Design • Current System Design • Connection to PEV • Assist & CPR Mode • Tubing • Trachea • Lung P14026_Detailed Design Review 12/05/13

3. Problem Statement • Current State • 1st generation of a validation system • Desired State • Simulate the respiratory system and measure flow, pressure, volume, and oxygen concentration • Project Goals/Opportunities • Collect data to evaluate 13027’s PEV • Constraints • ANSI Z79.7 • ISO 5469:1967 • ASTM F1100-90 • ISO 80601-2-12 P14026_Detailed Design Review 12/05/13

4. Matrix P14026_Detailed Design Review 12/05/13

5. Functional Decomposition P14026_Detailed Design Review 12/05/13

6. Design Proposed Week 9 P14026_Detailed Design Review 12/05/13

7. Why the Design Changed • Testing the LTV • Connection to the MediResp-III • Breathing into the LTV P14026_Detailed Design Review 12/05/13

8. Why the Design Changed • Breaths per Minute • Breaths per Minute at 0.9 Lpb P14026_Detailed Design Review 12/05/13

9. WHY The Design Changed • The LTV takes readings at the beginning and end of the tubing • Using the LTV would require the team to reverse engineer the LTV • Would be outside the time constraint of the project • Potentially, would be outside the budget constraint of the project P14026_Detailed Design Review 12/05/13

10. Current System Design P14026_Detailed Design Review 12/05/13

11. Connection to PEV P14026_Detailed Design Review 12/05/13

12. Current System Design P14026_Detailed Design Review 12/05/13

13. Assist Mode Components • Actuation is anexcellent way to makea process repeatable. • The rotational energyof a small motor wouldhave to be converted tolinear pushing/pulling. • An easy-to-execute choicewas to use the rack-and-pinion • A lead screw was alsoconsidered, but these areless efficient P14026_Detailed Design Review 12/05/13

14. Assist Mode Components • The syringe is 150mL and we expect to move roughly 100mL at a time, based on a typical inhalation. • The rack part of the rack-and-pinion must make a solid connection with the plunger 100 mL Dist = x P14026_Detailed Design Review 12/05/13

15. Assist Mode Components • The rack will need support to avoid slipping out of place. • The typical solution is to fit the rack into a short channel to constrain its path. Characteristics of the Rack as Designed: Keep rack on a level with the pinion. Leave space (0.01 in) on either side. Fairly wide to allow for easierconnection to plunger of the syringe. P14026_Detailed Design Review 12/05/13

16. Assist Mode Components • THREE CARDINAL RULES OF GEAR DESIGN: • Meshing gears must have the same height, • Distance between gears’ teeth (“pitch”) should be as close to same as possible • Different number of teeth is mechanically advantageous for torque-to-turn ratio and for speed of rotation. P14026_Detailed Design Review 12/05/13

17. Assist Mode Components -35-45 HR -Pressure Angle 20deg -Circular Pitch 2mm -300mm Long -Pressure Angle 20deg -Circular Pitch 2mm -Bore Size to Order -23 Teeth RM-2M-300 SH2MS2B250F7A P14026_Detailed Design Review 12/05/13

18. Assist Mode Components • The gear connection to the stepper motor relies on the motors default pin being able to find purchase in the gear bore. • The round pin of the motor is 5mm. We expect to order the gear at a NEMA#23 single-flat bore type. P14026_Detailed Design Review 12/05/13

19. Assist Mode Components • SIZING OF THE STEPPER MOTOR • The maximum expected resistance to motion is a volume of 100mL of air. • We would like to be able to apply the pressure of roughly half a breath (17 cmH2O or 1.667 kPa) • We would like a fairly quick reaction time of 0.2 sec. • Recall that Work/Time is Power, so analysis yielded: • Moreover, stepper motors are roughly 50% efficient, so the stepper motor selected was sized at 2 Watts of power. • The stepper motor is also bidirectional to allow for retraction. P14026_Detailed Design Review 12/05/13

20. CPR Mode • Originally, the team planned on using the syringe, stepper motor, and actuation to simulate a patient receiving compressions • At first team 13027 counted compressions by sensing pressure • Team 13027 has narrowed the scope of their project P14026_Detailed Design Review 12/05/13

21. Current System Design P14026_Detailed Design Review 12/05/13

22. Tubing • Why PVC? • PVC has many standard sizes and variations for connections. • Will be easier to implement. • PVC has smooth Inner Diameter walls. • Turbulent Vs. Laminar Flow? • If Re<2300 then we can assume flow is laminar: • , for air at STP: , and • Where , , • 20.83<<2300 therefore we can easily assume flow is laminar. P14026_Detailed Design Review 12/05/13

23. Current System Design P14026_Detailed Design Review 12/05/13

24. Trachea Resistance • Airway Resistance Basics • (1) • Orifice Plate Feasibility • (2) • plugging in ρQ=ṁand solving for results in, • where ΔP comes from Equation (1)(3) • Which results in orifice plate diameters as follows: • These orifice plate ΔPs will need to be validated; diameters may need to be adjusted based on empirical correction factors and experimental results. P14026_Detailed Design Review 12/05/13

25. Trachea Resistance cont’d. P14026_Detailed Design Review 12/05/13

26. Current System Design P14026_Detailed Design Review 12/05/13

27. Lung Compliance • How can we vary lung compliance with only one test lung? • Add a weight • Use a rubber band P14026_Detailed Design Review 12/05/13

28. Bezier Curves • Bezier Curves are splines that are controlled through the manipulation of control points P14026_Detailed Design Review 12/05/13

29. Bezier animation P14026_Detailed Design Review 12/05/13

30. Compliance program • Uses Bezier curves to model an ideal breath curve and generate simulated data based on this curve • We “force” the program to generate a curve that we want and use it to predict how different factors will affect our results • 5th degree Bezier Curve gives more control • This equation gives an x or y value for a specific t value. 0≤t≤1 • Rearranging the equation allows us to get control points from given coordinates. • Gives us a useful estimation of data P14026_Detailed Design Review 12/05/13

31. Comparison to Real data P14026_Detailed Design Review 12/05/13

32. Current System Design P14026_Detailed Design Review 12/05/13

33. Sensor Placement P14026_Detailed Design Review 12/05/13

34. Pressure Reading • SM5470 -Product of Silicon Microstructures Incorporated • Low Pressure Scale 0-3 PSI • Gauge Pressure Sensor • Accuracy is .25% • Used within Medical Instrumentation and Monitoring P14026_Detailed Design Review 12/05/13

35. Sensor Placement P14026_Detailed Design Review 12/05/13

36. Flow Meter • TSI 4000 Series Flow Meter • Flow Measurement: • Accuracy +/- 2% of reading • Range 0.01-99.9L • Response: 4ms • Pressure Measurement: • Accuracy +/- 1 kPa • Range 50-199kPa • Computer Cable (mini-DIN to 9 pin D-Sub) allows interface between device and computer. • Outcome: Data logging for flow and volume measurements *Note – same device used by 13027 to calibrate MediResp-IV P14026_Detailed Design Review 12/05/13

37. Preliminary Flow testing • Tested Mike exhalation of breath • Connected tubing to flow meter • Read in real time data P14026_Detailed Design Review 12/05/13

38. Sensor Placement P14026_Detailed Design Review 12/05/13

39. Release Valve • 4320T15 Miniature PVDF Relief Valve • Temp. Range: 26F to 255F • Use with air • Relieve excess pressure in air lines • Valve body is PVDF • Seal is Buna-N P14026_Detailed Design Review 12/05/13

40. Current System Design P14026_Detailed Design Review 12/05/13

41. Electrical Schematic P14026_Detailed Design Review 12/05/13

42. EMANT300 Low Cost USB 24 DAQ Module • Up to 6 channels of differential multiplexed ADC • Single channel 22 bit @ 10 samples/sec • Single channel 16 bit waveform @ 2500 samples/sec • 1 channel of 8-bit D/A conversion • 8 digital IO channels • One 16-bit general-purpose counter or 16-bit PWM • USBconnection • 25 pin D-Sub connects to physical world • Application adaptors with instructional guides • LabView compatible • Cost = $99.00 http://www.emant.com/251004.page P14026_Detailed Design Review 12/05/13

43. PCB Layout P14026_Detailed Design Review 12/05/13

44. Bill of Materials P14026_Detailed Design Review 12/05/13

45. Budget P14026_Detailed Design Review 12/05/13

46. Test Plan for our system • Leak Test • Test sequentially over build of assembly using flow meter • If lose 1% of flow, then look into forming better seals • Calibration Test of Pressure Sensors • Use manometer to validate pressure sensors • If within 5% of the sensor, then proceed • Calibration Test of Flow Meter • Use validated pressure sensors over a known distance to validate flow meter • Take into account the discrepancy between analytical and experimental values • Timing of Actuation • Use stopwatch or switch to time and validate actuation is working as expected • See mitigation plan (in future slide) P14026_Detailed Design Review 12/05/13

47. Risk assessment P14026_Detailed Design Review 12/05/13

48. Risk Assessment P14026_Detailed Design Review 12/05/13

49. Risk Assessment P14026_Detailed Design Review 12/05/13

50. Plan for Msd II P14026_Detailed Design Review 12/05/13