1. Wireless Test Instrumentation for Rotating Parts ECE 193 Advisor: Rajeev Bansal Olivia Bonner David Vold Brendon Rusch Michael Grogan ME 32 Advisor: Robert Gao Kyle Lindell Andrew Potrepka

2. Sikorsky Contacts  Company Advisor: Paul Inguanti pinguanti@sikorsky.com  Senior Test Engineer: Chris Winslow cwinslow@sikorsky.com  Test Instrumentation Engineer: Daniel Messner daniel.messner@sikorsky.com

3.  Company Background  The Problem  System Requirements  2012-2013 Team Design  Design Challenges  Project Goals  Timeline  Budget Outline

4.  Sikorsky Aircraft Company:  Founded in 1925 by Igor Sikorsky in Roosevelt, NY  Owned by United Technologies Company (UTC)  Moved to Stratford, CT in 1929  Produces aircraft and helicopters  Well known models:  UH-60 Blackhawk and SH-60 Seahawk Company Background

5.  Produced 30 military and 10 commercial helicopters in the first quarter of 2013  Generated $6.8 Billion [2012-2013] in net-sales  Serves 25 governments world-wide  Used in all 5 U.S. military branches  Saved close to 2 million lives since first helicopter rescue mission in 1944 Company Background

6.  S-92 helicopter has four blade, twin engines with a medium lift  Used for search and rescue  S-92 aircraft elements need monitoring:  gearboxes, control systems, rotor blades, powertrain element Company Background

7.  Wired sensors have several inefficiencies:  The components are heavy  The wires break  The connectors fail  Slip rings are needed for rotating components The Problem

8.  A wireless sensor network is a possible solution to the problems of a wired system.  Benefits of a Wireless System:  No long, heavy wires  No slip rings  Overall weight of system reduced The Problem

9.  Challenges of a Wireless System:  Powering system  Large Temperature Range  -65ºF to 400ºF  The team’s goal is to find solutions to these challenges through research and testing. The Problem

10. Figure. An interior sketch of the tail rotor gearbox on the Sikorsky S92 Helicopter. The Problem

11. Figure. Exterior view of the tail rotor, (where the electrics cavity is located). The Problem

12.  The team must complete the following project requirements:  Monitor the bearing:  Temperature, Vibration, or Strain  Process the measured data:  Fast Fourier Transform (FFT) or Band Pass Filter (BPF)  Digitize and compress the data for storage  Temporarily store the measured data  Transmit the data to a stationary system for long term storage and analysis  Data must travel wirelessly upwards of 40 feet System Requirements

13.  Provide power to the measurement system and to the transmitter and receiver System Requirements Figure. Illustrates the anti-bearing end of the electronics cavity. Access is provided here.

14.  Electronics Compartment:  Size: 1.5” diameter x 5.1” long  Temperature Range: -65ºF to 300ºF  Sensor(s):  Minimum of 2 sensor types  Temperature Range: -65ºF to 400ºF  Rotating Speed of Tail Rotor Shaft:  1200 RPM System Requirements

15.  Battery Life: - 1 year min (3 years recommended) - Must run for 12 hours a day and survive a 30 day period of inactivity  Energy Harvesting - Thermoelectric (Thermocouple) - Vibrational (Piezoelectric) - Magnetic (Alternator) System Requirements

16.  Environmental Parameters:  Exterior hostile environment (maintain system internally)  Cavity is lubricated with oil  Moisture expected  High vibration level expected System Requirements

17.  Accelerometer, microcontroller, transceiver, and lithium battery mounted in the electronics compartment  One sensor  Signal quality needs improvement  Some components in need of replacement  Mounted on lathe-like test rig  Bearings need replacement 2012-2013 Team Design

18. Figure. Test Rig from 2012-2013 team.

19. Figure. System block diagram from 2012-2013 team. 2012-2013 Team Design

20.  ECE:  Sensor selection (at least two different sensors)  Signal analysis, storage, and transmission  Ensure sufficiently clean signal  Battery selection and power management  ME:  Energy harvesting/energy generation to power/recharge system  Repair and improvement of last year’s test rig  Mounting and installation of sensors and transmitter Project Goals

21. Figure. General block diagram for 2013-2014 redesign.

22. Timeline Period Highlight: 6 Plan Actual % Complete Actual (beyond plan ) % Complete (beyond plan) Semester 1 Semester 2 PLAN ACTUAL PERCENT SeptemberOctoberNovemberDecemberJanuary FebruaryMarchApril ACTIVITYSTARTDURATIONSTARTDURATIONCOMPLETEWeeks 1234567891011121314151617181920212223242526272829303132333435 Project Statement1414 100% Research21025 10% Design87 Component selection123 Purchasing133 Prototype Build168 Testing245 Debugging285 Final Presentations324

23.  Budget funds from Sikorsky: $2,000  Re-use Mechanical components from last year.  Estimated Electronics costs from last year’s expenses: $2,129.36  Budget deficit: $129.36 Budget

24.  Which sensors should be used?  Will data processing be accomplished at the transmitter or receiver end?  Which energy harvesting technique will be best for this application?  What is the power envelope of the full electronics package?  Can we deliver that power through energy harvesting? Mission Questions

25.  Please vote with your iClicker based on the three criteria:  Grade: A, B, or C Questions?