Redesign of Autonomous Data Collection System (S.A.D.C.A.T.S.)

1. Redesign of aSubmersible Autonomous Data Collection and Transmission System(S.A.D.C.A.T.S.) Group Members: Matthew Rhoads BS ME (Lead) - Ballast, Hull John Robinson BS ME - Propulsion, Component Mounting Daniel Rubin BS ME - Stability, Propulsion, Comp. Mounting Matthew Buchwald BS/MS EE - Software Matthew Stith BS EE - Electrical Hardware Sponsor: Dr. Robert Kremens,Senior Research Scientist Chester F. Carlson Center for Imaging Science Faculty mentors: Dr. Wayne Walter, Mechanical Engineering Dept., Kate Gleason College of Engineering Professor George Slack, Electrical Engineering Dept, Kate Gleason College of Engineering

2. Overview of Presentation • Project Description • Mechanical Design • Hull • Ballast System • Propulsion System • Component Mounting Rack • Mechanical Status and Outlook • Electrical Design • Electrical Hardware diagram • Software diagram • Electrical Status and Outlook • Overall Project Testing Schedule

3. Project Description • An autonomous data-collecting submarine • A redesign of last year’s project • Deployable on Lake Ontario • Dives and resurfaces by pressurizing a ballast tank • Collects pressure, temperature, and color data as a function of depth • Propulsion systems allows sub to travel along surface

4. Hull • Improvements in size and weight of the overall vessel compared to first generation • Space-efficient packaging of components • Target external pressure of 4 atmospheres • Ease of access to internal components

5. Ballast System • Increase in control during diving • Integration into main body of vessel • Capability to influence vessel attitude • Removal of need for external medium • Additional areas of weight reduction

6. Propulsion System • Two, two-blade propellers will be used to navigate through the water. • Instead of a rudder, the propellers will vary in speed to change direction. • Propulsion system is assembled separately before placement in its enclosure • Lip Seal provides dynamic seal for propeller shaft. • Thrust bearing provides axial stability. • A more powerful motor must be considered to achieve locomotion

7. Component Mounting System • Allows electrical components to be mounted and accessible from the front end cap • Provides easy removal of components • Locates batteries in lower region of hull, aiding vessel stability

8. Mechanical Status ·Propulsion - Minimal fabrication left - Enclosure seal test planned for Tuesday - integrate to hull and test vessel locomotion Thursday ·Component Mounting Rack - Fully assembled, integrated with electrical parts ·Hull - Minimal fabrication left ·Ballast - Fully Assembled - Modification forthcoming to hold required ballast pressure

9. Electrical Hardware Diagram

10. Software Flowchart

11. Electrical Status ·Software • Initialization, diving, rising, and data acquisition functional, Simulated Dive Test Complete on vessel hardware • GPS reading and interpretation code complete • Propulsion and Navigation code complete, but untested; debug contingent on completion of propulsion system • Data transmission subroutine is functional • Data storage and retrieval not functional, currently in debug phase ·Hardware • Battery system complete • Power electronics board is complete, ready for dive test and propulsion system test • Microcontroller is interfaced with power electronics board • Pressure and Temperature sensors functional, color sensor still not interfaced • GPS not interfaced with Microcontroller • Radio transmission not functional, system is ready for modem to be supplied by sponsor

12. Overall Schedule ·Pool tests planned for next week to do the following: - Demonstrate hull sealing - Test proper ballast operation - Execute successful dive code sequence - Test locomotion on surface - Demonstrate data collection and retrieval - Establish color sensor operation ·Dry tests for next week: - Show proper GPS operation and connection to microcontroller