1. P15482: Breadfruit Shredder Brittany Griffin, Samantha Huselstein, Andrew Beckmann, Patrick Connolly, Alan Kryszak

2. Overview ●Background ●Concept Summary ●Final Design ●Testing ●Results and Recommendations

3. What is a Breadfruit? ● Nutrient rich tropical fruit o High in Carbohydrates, dietary fiber, Vitamin C, Potassium ● Member of the fig family ● Starchy, similar to a potato ● Common Haitian preparations: o Fufu* (similar to mashed potatoes) o Frying (similar to fried green plantains) o Boiled

4. Helping Haitian Farmers ● KGPB Farmers identified breadfruit as one the the most wasted agricultural products in the area ● Short shelf life (1-3 days) ● Summer harvest season ● Hard to transport, store, and preserve ● Solution must be low cost and have no energy cost Converting breadfruit into flour addresses these problems and it was our team’s challenge to do it at low cost and low energy!

5. Project Goals ● Flour producing process = 3 parts o Shredding o Drying o Grinding ● Working prototype(s) that shreds breadfruit to be dried and grinds dried breadfruit pieces

6. Customer Requirements of Highest Importance CategoryRequirement FeasibilityUses available resources FeasibilityMinimizes water usage CostNo energy cost CostLow maintenance cost Ease of UseCan be used by adult breadfruit farmer SafetyProvides barrier to hazardous parts SafetyDoes not contaminate food ProfitProvides flour that can be used to make fufu

7. Architecture

8. Functional Decomp

9. Concept Generation Brainstorming Benchmarking

10. Concept Selection Pugh Analysis Selection Criteria ● Doesn’t use electricity ● Available in Haiti ● Easy to maintain/sharpen ● Effort required to operate ● Easy to understand ● Within budget Bonus: Peels and cores breadfruit

11. Feasibility ● Prototyping o Question: Will our blade design work?  Created Mock-up blades from Al  Also used horizontal mill tooling o Results: Works well! 3 teeth seemed to work better and would be easier to manufacture ● Deflection of Plastic Blades o Question: Can we save cost by using plastic blades? o Results: We are not sure if they will be strong enough. Would be a huge risk. Al Prototype Mill tooling Plastic blade deflection

12. Feasibility Shear pin calculations ● Question: Can we have a shear pin that will allow breadfruit to be shredded but protect the blades? ●Results: Yes, but we needed to increase the size of the pin and get more durable keys for the shafts Fatigue Life of Shafts Question: Will this need to be repaired in Haiti? Results: Safety factor of ~300, therefore, will not break within its useful life

13. And then there was one... ● Cost Analysis o Shredder budget ~ $600 o Grinder budget ~ $325 o Problems: shipping cost not accounted for, no room for error in manufacturing, risky grinder design, rollers would need to be replaced for grinder design (before shipping to Haiti), does not include hopper or stand ● Project Plan o Over 100 parts to be made for shredder alone! o No time to build 2 machines in one semester Photo Credit: UMICH Breadfruit Grinder Team

14. Final Design

15. Final Design Details ● Materials o Non-corrosive, highly durable ● Shear Pin o Fail-safe, protect blades and shaft keys ● Hopper o Provide safety, holds up to 6 breadfruit (peeled and cored) ● Stand o Comfortable for person around average Haitian height o Braced for stability o Holds 5 gal bucket o Can place cinder blocks to help hold it down

16. Design Changes/Difficulties Design Difficulties ● Bending Guards Accurately ● Tight Clearance Between Blades ● Properly Building Welded Parts Design Changes ●Shear Pin Diameter ●Hopper Size ●Stand Cross Braces ●Key stock Material ●Shaft Size for Blades

17. Other Problems Overcome...

18. Testing ● Shear Pin Test ● Interference ● Operating Metrics ● Assembly Timing ● Shredder Yield

19. Shear Pin Results Conclusion: The result of the shear pin test above shows that all shear pins sheared at values less than the T high value of 11,697 psi. Therefore no damage will be done to the system and only the shear pin will need to be replaced.

20. Interference Results ● Interference testing was performed throughout the build process. ● All parts were measured to meet Drawing Specifications. ● Blades and spacers were precision ground in pairs to ensure no interference between parallel shafts. ● Blades have.003” Clearance (Less than a piece of paper!)

21. Operation Metrics Results Conclusions: All operating metrics met their target values. Average of ~71.2 breadfruit per hour. Cleaning met the marginal time. Recommendations: ● Cut breadfruit into eighths instead of quarters. (Does not need re-adjusting in hopper to get caught in blades) ● Feeding shreds through twice will make smaller more uniform shreds (will save on drying time) ● Use tube/bottle brush instead of toothbrush (Plastic of toothbrush was shaved off by blades) ● Look into sending a squirt bottle for faster cleaning

22. Assembly Timing Results Conclusion: All set up, disassemble, and reassemble times were below target values. Moving entire assembly can be done in a quick and efficient manner. Recommendations: Redo test with more people to make sure we continuously meet specs

23. Shredder Yield Results Conclusion: Shredder Yielded ~98.3% of input breadfruit by weight. Almost all of breadfruit was shredded leaving on only 1.7% of breadfruit left in shredder. Recommendation: By running the shredder in reverse for 3-4 turns, the remaining breadfruit can be retrieved and can be reprocessed through the blades.

24. Project Evaluation

25. Project Plan versus Actual ● Task tracker was used to determine when tasks needed to be completed versus when they were actually completed. ● Tasks were completed on average.13 and.75 days in advance for MSD I and MSD II respectively.

26. Budget Evaluation Proposed Budget vs Actual Budget VendorDescription Amount Charged Speedy MetalsMisc. parts$360.48 McMasterMisc. parts$163.39 BDI ExpressMisc. parts$95.43 Klein SteelAngle Iron$41.10 ePlasticsBlack acetal sheet$76.98 CurbellPolycarbonate sheet$30.00 Lowe’sPaint$27.50 WegmansBreadfruit$96.58 Remaining Balance$108.54 Total Spent$891.46

27. Recommendations for Future In Haiti: ● Teach about shear pin function ● Teach about hopper function (in regards to safety) ● Collect Feedback from Farmers o Shredder specific - What do you like? What do you not like? How often do you use the shredder? o Is flour being used by KGPB farmers? o Does your family use breadfruit flour? o Are the women selling the flour in the market? o Is there a part of the flour process that could be better?

28. Recommendations for Future If new shredder is needed: ● For 2nd iteration of MSD ● Easier to manufacture ● Look into cheaper materials to use o More thorough analysis on plastics ● Look into using less/lighter material ● Ability to use with manual AND motor power ● Implement any other design changes based on feedback from KGPB farmers

29. What we learned ● Feedback helps o Peer reviews and +/delta ● Risk Assessment o Identifying where things can go wrong helped us avoid problems ● Communication o Work Breakdown Structure o GroupMe ● Documentation ● Machining skills ● Problem solving skills ● Design processes/skills ● Presentation skills What we would do differently: ●Handle to pick up shredder ●Paint sooner (time to cure) ●Change finger bolts to countersunk for better locating ●Turn shaft nuts from scratch ●GroupMe communication sooner (beginning of MSDI) ●Check drawings more closely ●More than 1 person in charge of CAD ●Better use of our WBS

30. MSD Improvements ● Better use of MSD I class time o Lectures online and in class were repetitive ● MSD I storage space ● More experts in the machine shop ● Weekend hours for the machine shop ● More emphasis on prototyping ● Better matching of skills to project ● More team-to-team feedback

31. Questions? Photo Credit: Phil Medalie (Imagine RIT Photos), Rob Stevens (Haiti pictures), and MSD Team