Congratulations to Our 2024 Grand Prize and First Place Winners!

NETrolyze, a novel immunotherapy for triple-negative breast cancer (TNBC), was named the $25,000 grand prize winner at a live finalist round held November 15 in New York. The first-in-class therapeutic injectable gel prevents the spread of TNBC, one of the most aggressive cancer types, enabling patients to avoid toxic chemotherapy and expensive treatments – potentially transforming their lives. Click here for the full list of 2024 winners. Also see the Top 100 highest scoring entries.

Special thanks to our esteemed panel of judges.

Help build a better tomorrow

Since Tech Briefs magazine launched the Create the Future Design contest in 2002 to recognize and reward engineering innovation, over 15,000 design ideas have been submitted by engineers, students, and entrepreneurs in more than 100 countries. Join the innovators who dared to dream big by entering your ideas today.

Read About Past Winners’ Success Stories

Special Report spotlights the eight top entries in 2023 as well as past winners whose ideas are now in the market, making a difference in the world.

Click here to read more

A ‘Create the Future’ Winner Featured on ‘Here’s an Idea’

Spinal cord injury affects 17,000 Americans and 700,000 people worldwide each year. A research team at NeuroPair, Inc. won the Grand Prize in the 2023 Create the Future Design Contest for a revolutionary approach to spinal cord repair. In this Here’s an Idea podcast episode, Dr. Johannes Dapprich, NeuroPair’s CEO and founder, discusses their groundbreaking approach that addresses a critical need in the medical field, offering a fast and minimally invasive solution to a long-standing problem.

Listen now

Thank you from our Sponsors

“At COMSOL, we are very excited to recognize innovators and their important work this year. We are grateful for the opportunity to support the Create the Future Design Contest, which is an excellent platform for designers to showcase their ideas and products in front of a worldwide audience. Best of luck to all participants!”

— Bernt Nilsson, Senior Vice President of Marketing, COMSOL, Inc.

“From our beginnings, Mouser has supported engineers, innovators and students. We are proud of our longstanding support for the Create the Future Design Contest and the many innovations it has inspired.”

— Kevin Hess, Senior Vice President of Marketing, Mouser Electronics

Follow Create the Future

Self-Adjusting Bushing Bearing

Votes: 0
Views: 11578

Bushing bearings are used as a cost effective alternative to much more expensive ball or roller bearings. The main drawback, however, is the radial clearance between the bearing and the shaft that continues to increase as the bearing wears. In addition to the noise generated, especially in a reciprocating motion application, there is a critical maximum clearance where the lubrication breaks down resulting in damage to the shaft as well as the bearing. The self-adjusting bushing bearing (SABB) design eliminates this failure mode and provides additional benefits that make it a more advantageous and cost effective alternative to ball, roller, as well as conventional bushing bearings.

Figures 1, 2, and 3 show an exploded view, partially assembled view, and assembled cross-sectioned view, respectively, of the SABB shown in a reciprocating linkage mechanism application. The figures shows that it consists of three bushing bearing segments continually “spring-loaded” against the bearing shaft by means of two O-rings wrapped around the OD of the bearing segments. Circumferential grooves around the OD of the bearing segments are used to position the O-rings. A retaining ring is used to retain the bearing segments in the bearing housing. The SABB design can replace bearing applications with cylindrical shafts using cylindrical ID SABB segments rather than the spherical ID segments shown.

The SABB has the following advantages with respect to standard bushing, ball, and roller bearings:
1.While there is a slight increase in the cost of the O-rings with respect to standard bushing bearings, it is still significantly less expensive than ball or roller bearings.
2.There is no need for any type of press fit to secure the bearing to the housing to prevent the bearing from spinning relative to the housing, reducing machining tolerances and costs and making it much easier to replace in the field.
3.The gap between the bearing segments functions as a wear indicator for preventative maintenance to prevent the shaft from being damaged.
4.The constant “zero clearance” between the bearing segments and the shaft helps prevent contaminant (dirt, water, etc) from entering between the bearing and the shaft resulting in less susceptibility to contamination without seals or with bearing seals if/when they fail. Note: when used with sintered bushing bearing material, any dirt particle that is small enough to migrate into the essentially “zero clearance” oil boundary layer will be small enough to pass into the sintered bearing material void space rather than become trapped between the bearing material and shaft.
5.The O-ring spring loading between the bearing segments and the bearing housing also provides:
•Additional tolerance for misalignment
•Vibration dampening to assist in passing through any natural frequencies (such as during startup)
•Shock absorption
6.The “zero clearance” design accommodates the use of much less viscous (relative to oil) lubricants such as water for applications such as boat propeller shaft bearings.

  • Awards

  • 2012 Top 100 Entries

Voting

Voting is closed!

  • ABOUT THE ENTRANT

  • Name:
    Douglas Larson
  • Type of entry:
    team
    Team members:
    Tom Danowski
    Doug Larson
  • Profession:
    Engineer/Designer
  • Number of times previously entering contest:
    1
  • Douglas's favorite design and analysis tools:
    SolidWorks
  • Douglas's hobbies and activities:
    Golfing, writing, product development
  • Douglas belongs to these online communities:
    FaceBook
  • Douglas is inspired by:
    The importance of adding resiliency to otherwise rigid mechanical designs.
  • Software used for this entry:
    Solid Works
  • Patent status:
    pending