• 320k people own 3d printers in 2015 - [1]
• Basic question is why are people not getting involved when expected payback per year is $300-2000? [2]. An answer to this lies in first testing the prints suggested and seeing the outcome. One side is developing the production engineering so it is highly reliable - at this point, it appears that

Incentive Design

1. Enforced collaboration by requiring use of accepted modules pending clear interface design
2. Requirements are specified for performance, admissible parts and interface design
3. The trick lies in explicit specification of modules in a way that degenerates design to a high degree towards a specific implementation.
4. Degenerate production engineering - one slicer, one operating system, one machje, one software toolchain, one package. Trick here is reconciling diversity of options with starting a business. For widespread distribution, we need the most open tools possible.

Marketing

• Solicit a representative from every single country to start a business in their country
• Low entry cost revolves around a low cost production machine (3D printer)
• For uniformity, every single production machine involved is 100% open source.
• Production infrastructure uses scrap plastic.
• Plastic testing protocols are included for the waste stream

Advisors

• Use this as a chance to recruit top technology advisers, funders, and judges such as Dan Gelbart, Lee Felsenstein, and others.

Incentive and Judging

• Total reward specified and large. Number of rewards is unspecified and as large as the number of contributions provided. Prize around $100k, but may be $2-300k.
• One prize could be awarded if one person does all the work. Inpossible.
• Extended transparency on logic of the prize
• Admissible content is that which is posted on the wiki.
• OSE Incentive Challenge Wiki Template is used. Evaluate HeroX for the type of content that is uploadable. Solution for OSE is to use external repos or increase memory limit to 5MB
• People are rewarded for collaboration. Basic logic if incentive is that - if you are entering, you are serious about the possibility of producing. BUT, you will be required to provide to a regenerative standard. For this, you will be using recycled plastic, contributing to a database of filament production - AND you will be cleaning up the environmental because you will be taking plastic from the waste stream. So you are motivated for the full package and educated in the process.

Prerequisites to Challenge

• Fully developed examples of D3D machine productivity and capacity(calipers, vise, drill prototype, tablet for running the printer, Soft Rubber Printing)
• Gear production methods- included or off the shelf?
• Testing MIG Casting and Desktop ZA 3D printing foundry.
• Claerand Desktop ZA 3D printing foundry.
• Clear production goals - 12 drills per day from printed parts, and 100 per month. $50 profit each.
• Extreme efficiency for beating mass manufacturing with on-demand production

Calculations

• $10B market. At $100 per drill - 100,000,000 sold per year. Out of 8 billion people, that is 2% of the population buys a drill every year?

End State

Elements

• Collaboration Architecture Taxonomy developed and deployed as the new Development Template
• Website templates are produced, and deployable readily on common open source platforms
• Operations are set up for a country head in every qualifying country, with marketing support established at high level for each country
• Tranining and certification for producers. Independent producers can get involved without license agreement (true open source).
• Producers are incentivized to continue development by virtue of a transparent, open source platform.
• Sound governance and corporate form adheres to Distributive Enterprise mission

More

• 3 years for Distributed Market Substitution from the time the contest ends.
• OS Microfactory for producing cordless drills from the waste stream of plastic, aluminum, zinc, and rubber.
• Lifecycle stewardship on the part of producers, takeback for 100% recycling of materials. This means the most for the circuit boards. These should be in house manufactured and should use COTS parts
• Enterprise Level - a way for anyone to be trained to produce professional grade 3D printed cordless drills with lifetime design
• Materials cost - $20, profit $80 per drill, relies in a heavy level of Technological Recursion and automation.
• 12 per day build capacity from 3D printed parts. Production bottleneck is 3D printing of complex shapes.
• Most of process is highly automated.
• Product comes in kit form with minimum assembly required, 30 minutes to 1 hour, or fully assembled.
• Distributed quality control and production at 3 Sigma level
• Collaboration with Big Box stores for distribution
• Training ability to get any additional producer trained in a period of 1 month
• Certification procedure for producers
• Distributed quality control protocol that is transparent via online documentation

Challenges

• Scope creep - full production tool chain. Determining the level of depth of recursion. Do we make our own motors? Gearboxes? Circuits that are milled? Solution is examining this all in detail to determine which fits in the end game scenario of 100,000 producers worldwide producing drills.

Opportunities

• Converting other projects such as V1 Engineering to open source as ancillary tools. However, this does not address degeneracy of toolchain.
• Resolution of tool chain degeneracy is modularity. Making the parts so modular that they can do everything. We are the only guys that can do it at present.

Production Infrastructure

• Explicit production engineering design is part of the Challenge, and a key element of distributed quality control
• Uniformity and low cost can be achieved by 3D printed organizing systems. Drawers and bins, using a 12" bed 3d printer.
• Larger 3D printer may be required for packaging and shipping - using 3D printed shipping boxes or cases. A Tool Case can also serve as a shipping case if provisions are made for closing the box securely for shipping
• Abrasive disk can be made from a sand-plastic filament. See Abrasive 3D Printing Filament

More About the Drill

• Drill Technical Specifications

Links

• Steve
• Cordless Drill Industry Standards
• OSE Incentive Challenge Value Proposition
• Cordless Drill Statistics