P13027: Portable Ventilator

P13027: Portable Ventilator Team Leader: Megan O’Connell Matt Burkell Steve Digerardo David Herdzik Paulina Klimkiewicz Jake Leone 1 of 75

Technical Review Overview • Engineering Specs • Proposed redesign • Battery and Power Calculations • Power: Electrical • Electric Board Layout • SPO2 Sensor • CO2 Sensor • Pneumatic Design • Pressure Sensor Testing • Housing Vision-Casing Structure • Project Comparison • System Testing • BOM • Risk Assessment • Project Passover • Questions? 2 of 75

Engineering Specifications 3 of 75

Revision B- Proposed Redesign Update: • Battery Size-> Reduce Size & keep same capacity • Reduce Circuit Board size-> Create custom board for all electrical connects • Reduce Electrical Drive Motor • Display Ergonomics • Reduce Size and weight of PEV • Instruction manual Additions: • Visual Animated Display-> Moving Vitals • Memory capabilities • USB extraction of Data • Co2 Sensor as additional Feature to PEV • Mechanical Overload Condition due to Pump Malfunction 4 of 75

Battery Choice: Tenergy Li-Ion • 14.8 V • 4400mAh • 0.8375 lbs • 7.35cm x 7.1cm x 3.75cm • Rechargeable up to 500 times • Price: $50.99 • Bulk pricing • Each cell: $3.18 = $25.44 (8 cells) • $10 Protection Circuit Module • ~$40 with packaging and connectors 5 of 75

Power Calculation 6 of 75

Charger (Brick) • HP AC Adapter • 18.5V • 3.5Amps • Power: 65W • Max power: 70W • Price: $14.35 (Amazon) • Bulk pricing: $6.48 when quantity of 1000 is bought 7 of 75

DC-DC Boost ConverterT.I. TPS55340 8 of 75

Component Calculations • Designed for Vin = 12-18V, Vout=18V, Iout= 2.5A • Most components were chosen using TI’s WEBENCH component selection tool • Calculating RFREQ • RFREQ(kΩ) = 57500 × ƒsw(kHz)-1.03 • Calculating minimum Inductance required for CCM 9 of 75

Voltage Regulation • Input and output capacitors were chosen with regard to values on datasheets. 10 of 75

Battery Charging Circuit • Suggested Solution: 11 of 75

Our Solution 12 of 75

Battery Charging Circuit • Many discrete components suggested by proposed solution were used • Determining the values of R8 and R9: • Timing Capacitors changed in order to set longer charging times for larger battery • Thermistor not needed for our application, replaced with resistor. • Current sense resistors set by: IFSS = 0.1V/R12 and IFSI = 0.2V/R18 • Dual-channel Power MOSFET chosen for power switch – rated well for our application • All components chosen with safety margins in order to achieve proper operation 13 of 75

Electrical Schematics • Refer to Electrical Schematics (confidential) 14 of 75

Revised Board Layout 15 of 75

Connections to PCB • User Inputs Sensors LCD • and Power and Audio 16 of 75

SpO2Sensor • Difference in Absorption between Red and Infrared is used to determine SpO2 17 of 75

SpO2 Sensor Continued Simplified Design: 18 of 75

SpO2 Flow Chart 19 of 75 Source: Freescale Pulse Oximeter Fundamentals and Design

CO2 Sensor 1. Original Target -> Telaire 6004 OEM Module Problem: Supplier went out of business, similar models are not being sold by GE Sensing 2. GE SENSING: Does not sell CO2 OEM Module within concentration range needed Upon Further Investigation: The average exhale returns ~ 40,000 ppm of CO2 Dollar Range for CO2 OEM Concentration Modules (using NDIR) 20 of 75

Cheapest option:CO2 Meter- K-30 10% CO2 Sensor • Cost $249 for 1 • $163 for 250+ • Programmable Range: 0-100,000 ppm • Accuracy: ± 30 ppm ± 3 % of measured value (up to 3% CO2) • Sensor Life Expectancy: > 15 years • Sampling Method: Diffusion • Current Consumption: 40 mA average • Simple analogue output sensor transmitter signal directed to OUT1 and OUT2 21 of 75

Electrical Bill of Materials • Total Cost: • For 1: $311.94 • For 100: $193.43 • (This includes PCB, MCU, Sensors, and LCD) • Refer to Electrical BOM for complete parts list (confidential) 22 of 75

Initial Test Plan for PCB AssemblyWeeks 1 and 2: PCB Assembly • First two weeks will be spent soldering PCB. • Check that all pads match component footprints • If any component(s) do not match footprint, attempt to solder jumper wire to pins. • If jumper wire is not possible or if component overlaps another component, make changes to PCB and reorder (2 week lead time +$66) • Solder components in CIMS using heat gun and solder paste. Larger components such as connectors will be hand-soldered 23 of 75

Week 3: Power System I and Hello World Program Power System I: Powered from only external or only Battery • Apply 18V to external input power using Lab Power Supply. Set Current Limit to 500 mA to prevent damage to circuits. • Measure voltage on 10V, 5V and 3.3V nodes to confirm outputs are as expected. • Disconnect external power and connect charged battery. • Measure voltage on 10V, 5V and 3.3V nodes to confirm outputs are as expected. Hello World Program: • Plug in JTAG connector. Ensure correct orientation. • Test to see if JTAG Debugger has connection to MCU. • Download Test Program to MCU. • Connect LED to output pin. LED should start blinking. 24 of 75

Week 4: Power Systems II Motor Drive Testing Power Systems II: Battery Charging and various DC inputs • Connect depleted battery and attach oscilloscope across battery and battery current sense resistor. • Apply external Power with Current Limit set to 2.5 A. • Observe that current stays less than or equal to 2 A and voltage on battery steadily increases up to but not over 16.8V. Monitor battery temperatures and discontinue temperatures if battery exceeds 110 F in Ambient. Motor Drive Testing: • Download PWM program to MCU • With Motor Disconnected, observe proper pulsing from MOT_PWM • Connect Motor • Test Motor from DC=.05 to DC=.66 25 of 75

Initial Testing 26 of 75

Initial Testing- Differential Pressure Sensor Model 27 of 75

Differential Pressure Sensor • System Architecture • No Capacitor • No Backpressure

Differential Pressure Sensor • Capacitor • Backpressure 29 of 75

Static Pressure Sensor • System Architecture • No Capacitor • No Backpressure 30 of 75

Screen Shots • System Architecture DP Sensor GP Sensor 31 of 75

Screen Shots • Mechanical Capacitor DP Sensor GP Sensor 32 of 75

Screen Shots • Electrical RC Circuit • 10 kΩ Resistor • Capacitor 100 μF DP Sensor 33 of 75

Screen Shots DP Sensor GP Sensor • Results of temporarily resisting flow and then releasing • Pressure builds • Flow spikes and then quickly levels 34 of 75

Video Proof • Impact of mechanical capacitor in system • Flow speed • Sensor dampening • Proof of flow sensor accuracy Conversion of Mechanical Flow Sensor: Cheat: 12 = 20 l/min 35 of 75

Human Trials- • Determine if sensor can observe human backpressure • System Architecture • No Capacitor 36 of 75

Mechanical Relief Valve Pressure Release at 1 psi  Reusable 37 of 75

Rough Correlation to Factory Specifications • System Pressure 0-4.5 kPa (0-.65 psi) • Patient Pressure 0.5-2kPa (.07-.29 psi) 38 of 75

Concerns- Calibration • Currently have no way of measuring pressure accurately • Mechanical gauge cannot handle pulsation • Uncertainty as to whether we can calibrate against another digital sensor 39 of 75

Housing Modifications • 13026 Physical Extremes: • 15in long X 10in high X 7in deep • Projected 13027 Physical Extremes: • 12in long X 7.5in high X 7in deep Team: 13026 Team: 13027 40 of 75

Housing Vision 41 of 75

Housing Vision Speaker Mode O2 Sensor port CPR Compression # CO2 Sensor port Manual Mask tube ports Power 42 of 75 BPM Flow Rate Pressure Limit

Project Comparison GOAL: Analyze the size and weight reduction between major contributing components of MSD 13026 PEV to our projected design. 47 of 75

Summary: 48 of 75

Casing Assembly Material: Plastic, Styrene for molding with rubber soles to protect damaging case Goal: Create an enclosed structure for our system components. Problem: Limiting the capabilities to ability/ access vacuum molding machine to produce similar appearance result as MSD 13026 49 of 75

Option 1- Recruit RIT Industrial Design Major to recreate vision Option 2- Create a paneled assembly from plastic • Cons: • - Visual appearance would degrade • - Casing would not be seamlessly enclosed • Expense for sheet plastic • (ranges from $50-$200 based on thickness) Option 3- Purchase premade casing • Cons: • - Visual appearance would degrade • Casing would make entire device be larger & heavier than intended • Expense (~$158)

P13027: Portable Ventilator