1. SYSTEMS DESIGN REVIEW Team Bass

2. BACKGROUND Suction Feeding is a method used by telost fish to force food and water in their mouths. To do this, the fish must create a pressure drop between the inside of the mouth and the outside water by expanding the buccal cavity prior to opening the mouth. This causes a fluid flow into the fish. Particle Image Velocimetry (PIV) and Doppler Ultrasound technology are widely used to visualize flow of fluid internally and externally. PIV is most useful for external fluid flow since the internal fluid must be optically accessible. In the scenario when that is not the case, Doppler Ultrasound is used to see through various membranes to visualize internal fluid flow. The drawbacks of these technologies include inaccessibility to internal fluid for optimal visualization and inaccuracies in ultrasound equipment.

3. PROBLEM STATEMENT Currently, the understanding of fluid flow during suction feeding inside the mouths of fish is relatively nonexistent. Up to this point in time, there has only been one test rig employed to collect data on this subject (using Particle Image Velocimetry (PIV) technology to observe fluid flow outside of fish). The goal of this project is to design and build a test rig that utilizes both PIV and Doppler Ultrasound (DUS) technologies; the device will have the ability to output streamlines of fluid flow in and around the mouth of a largemouth bass, as well as capture live video/images of how this unique method occurs. To do this, the two selected technologies must work synchronously both as data acquisition tools and as verification checks on one another. The resulting design and prototype will adhere to safety and size constraints while including all specialized concepts required for specific research. The data collected by this test rig will be of key importance in fully understanding the entire physics behind suction feeding in fish.

4. CUSTOMER REQUIREMENTS NumberReasoningCustomer Requirements Customer Weights 1 Data collectionObtain full external velocity of entire event area 3 2 SafetySafe for humans 3 3 Data collectionUtilize current PIV technology and equipment 3 4 Data collectionUtilize current DUS technology and equipment 3 5 Ease of useUtilize one interface for data acquisition and control 3 6 Data collectionAutomatic acquisition triggering 3 7Data Collection Track target to assure sensors are within functional distances from the fish 3 8 SafetySafe to use for fish 3 9 PortabilityManageable test rig size for two researchers people to move 2 10 FundingManageable budget 2 11 Ease of useAutomated fish feeder 1 12 AestheticsProfessional looking product (determined by users) 1 13 Ease of useClose proximity to power 1 14 SafetyFish tank filter and pump on the tank 1 15 SafetyCleanable tank 1 16Safety Minimal impact on the fish from motion of rig and moving the fish 2 17 Ease of useRig can be used on multiple species of suction feeding fish 2 18 LongevityLasts 5 years with 20-30 tests per day 2 19 Data collectionComparable data to previous tests 3 20 Data collectionObtain full internal velocity profile 3 21 Data collectionReliable with respect to consistency of acquiring data 3

5. ENGINEERING REQUIREMENTS NumberEngineering Requirements Target Accept able Units 1 Distance from vertical plane of data acquisition to vertical center plane along the length the of fish 0< 5Millimeters 2 External area captured by PIV with the center located at the lower lip of the fish 60 > 25Centimeters² 3 Maximum size of captured internal area with origin at lower lip, X pointed along the fish and the y pointed vertically up 12 X 10> 8 X 7X in cm by Y in cm 4 Rate of data capture 500 Frames/sec 5 Amount of water spilled on the user 0< 0.25Gallons 6 Distance from outlet 1< 3Meters 7 Total cost 250< 1000Dollars 8 Space allocated on vibration isolation table 1 X.875 < 2 X 1.875 Meters x Meters 9 Customers opinions on the professional aesthetics of the rig Yes Professional Opinion 10 Repeatability of position of fish with respect to the center of the field of view 1< 5Centimeters 11 Number of different acceptable types of bait for automated feeding 5> 0 different types of bait 12 Number of independent computers used for imaging 1< 2 Number of computers 13 Follow all requirements listed in New York State health and safety Law section 50 with regards to lasers Yes Binary 14 Distance between Doppler sensor and the side of the fish 0.5< 5Centimeters 15 Weight 23< 45Kilograms Number Engineering Requirements Target Accept able Units 16 Supported fish sizes 35 X 16 X 16 > 20 X 10 X 10 L in cm by H in cm by W in cm 17 Dimensions of flow profile 3D2D Dimensions with time 18 Percent of times rig triggers data acquisition during an event 100> 90 % of data collected 19 Volume of water from the tank filtered in an hour 150> 75Gallons / hour 20 Percent tank accessible without disassembly by the customer 100> 70 % of tank surface area 21 Predicted allowable wear on mechanical system found with simulation 10> 5 Years of continuous use 22 Manufactures supplied data on life of all individual electronic components 10> 5 Years of continuous use 23 Base sizes of fish tanks supported any>.5 X 1Meters x Meters 24 Amount of time required to assemble the rig into a fully functional state by the customer 1< 2Hours 25 Time required for cleaning tank by the customer to a state that does not harm the fish 0.5< 1.5Hour 26 Follows all state and national IACUC standards Yes Binary 27 Placement of bait with respect to center of field of view aligned with laser plane 0.52Centimeters 28 Distance between where the rig thinks the fish's mouth is respect to where it actually is 14Centimeters

6. HOUSE OF QUALITY AND REQUIREMENTS Metrics – How to test Ranges – Model Covers Requirements Conflict analysis (ie. want a lot of inertia but also want lightweight) Sawyer Done (9/29) Customer Requirements Engineering Requirements Proportionality of Engineering Requirements Strength and Correlation of CR and ER Difficulty and Importance

7. WHY HOW FUNCTIONAL DECOMPOSITION Focus on critically important and/or hard to do Does it enable me to develop the concepts that need to be developed? Hierarchy and how functions relate to each other Add safety compliance to functional decomposition Sami (9/23) Critically Important Aspects & Use in Concept Selection A) Plant Bait B) Locate/Track Fish C) Trigger Data E) Aggregate Data G) Simulate Flow Dr. Day’s Responsibility

8. MORPHOLOGICAL CHART 50+ concepts Stretch and safe concepts 3 concepts for morph chart Mike Ballow Everyone adds their drawings by (9/23) Done (9/30)

9. CONCEPT SELECTION Pugh chart Done (9/24) Once morph chart is done and compiled, everyone makes a Pugh chart with 3 concepts each by (9/24) Pull out criteria and 2 winning columns

10. FEASIBILITY ANALYSIS FMEA Cost models? Testing models? Cost, weight, rough position model, rough analysis, project plan, testing Done (9/30) 3D Fish Model: How long will it take to create a fish model and how will we test for functionality that resembles a real fish? - Wait time for rapid prototyping machines: Unknown - Time to print all parts (using pre-existing CAD files): 3 Days - Time to assemble components: 5 Days - Time to create and assemble “Skin”: 7 Days - Time for complete integration of pump: 5 Days -Time for testing/adjustment of flow created: 10 Days (use iterative process of comparing flow data and adjusting pump settings) Total Time for Creation: 30+ Days 3D Fish Model: How much cost will be involved in the creation of the 3D fish model? - CAD files: $0 - 3D printing cost: $0? (Possibly no cost to create components in the Brinkman Lab) - Latex sheet (12 in. x 12 in.): $8 (per sheet) - Electric pump: $25 -Various tubing and accessories: $30 Total Cost: $63+

11. FEASIBILITY ANALYSIS CON’T FMEA Cost models? Testing models? Cost, weight, rough position model, rough analysis, project plan, testing Done (9/30) Test Rig Scaffolding Structure: How much will the test rig structure weight and how much will all the materials cost? - Top of tank dimensions: 0.6 m x 0.6 m - Material to use: 6061 Aluminum - Approximate size/number of pieces: 0.05 m x 0.02 m x 0.6 m (4 pieces) - Density of 6061 Aluminum: 2700 kg/m^3 Total Weight of Scaffolding Structure: 6.4 kg Total Cost of Raw Material: $55 (Price does not include manufacturing work to create fixturing) Fish Feeder: How do we create a fish feeder that consistently delivers the right amount of food at the right time (and be compatible with a wide range of food sources)? - Benchmark against “fish feeders” that are on the market today (Fish Mate F14). - Brainstorm ideas on how to adapt a product meant for dry food to accommodate live bait. - Perform extensive testing to validate subsystem concept.

12. RISK ASSESSMENT SCALE Projected risk/time (sum of importances) Causes  Models Abatement strategies Priority Owners Project/program/team Target completion Mike (9/23)

13. RISK ASSESSMENT Projected risk/time (sum of importances) Causes  Models Abatement strategies Priority Owners Project/program/team Target completion Mike (9/23)

14. RISK ASSESSMENT CON’T Projected risk/time (sum of importances) Causes  Models Abatement strategies Priority Owners Project/program/team Target completion Mike (9/23)

15. RISK ASSESSMENT CON’T Projected risk/time (sum of importances) Causes  Models Abatement strategies Priority Owners Project/program/team Target completion Mike (9/23)

16. RISK ASSESSMENT CON’T Projected risk/time (sum of importances) Causes  Models Abatement strategies Priority Owners Project/program/team Target completion Mike (9/23)

17. SYSTEM ARCHITECTURE Incorporates all subsystems Block diagram format Interfaces (shows connections between systems) Color coded Energy Material Information Structure All functions included Sawyer Done (9/30)

18. PROJECT PLAN Dates Readable Milestones Owners of deliverables Slack (put it in test time) Coty Review (9/24)

19. TEST PLAN AND ACTION ITEMS FOR PHASE 3 Yes Finalize and review Powerpoint on (9/29) Run through presentation with Jerry (9/30) Draft Test Plan Simulations for mechanical components Research/datasheets for individual components Use 3D Model fish for flow rate testing Test and Behavior research on fish in varying environments Prototype automated fish feeders Action Items for Phase 3 Call Dr Schwartz specs on Ultrasound machine (including features and capabilities) Continue to demo equipment with Dr Day Order fish from fish farm and set up environment and behavior testing Confirm price of 3D printing and access to materials for 3D model fish Contact vendors, technicians, and experts (SME)

20. BIGGEST CHALLENGES DUS

21. PHASE REVIEW AND EFFICIENCY Efficiency from ZOHO

22. QUESTIONS?