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Environmentally Conscious Design & Manufacturing

Explore the needs, benefits, elements, limits, implementation, and evaluation of reuse in design and manufacturing. Discover strategies like repair, refurbishing, remanufacturing, and material recycling. Learn how to assess reuse potential and optimize product life cycles. Gain insights on motor reuse and its challenges and opportunities.

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Environmentally Conscious Design & Manufacturing

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  1. Environmentally Conscious Design & Manufacturing Class19: Reuse Prof. S. M. Pandit

  2. Agenda • Needs and Benefits • Elements • Limits • Implementation • Evaluation • Example

  3. Reuse and Life Cycle Analysis

  4. End-of-life Product Recovery Strategies • Repair • Refurbishing • Remanufacturing • Reuse of components • Material recycling and disposal • Energy recovery

  5. Needs and Benefits - 1

  6. Needs and Benefits - 2 • Design for reusability (Technology) • Better quality - ease of reuse • Bookkeeping and control over effect of • Design • Materials • Manufacturing • Use

  7. Needs and Benefits - 3 • Costs are reduced because: • Consistent guidelines are established for all • mechanics • When the part can and cannot be reused • Forms the basis for a quality control program • that lowers redo & warranty costs

  8. Elements - 1 • New Product Design • Developing guidelines • e.g. small project:reusability limitations and • salvage procedures for a shaft or a gear • e.g. Large project: reusability limitations and • salvage procedures for all the piece parts in • a family of components such as a • turbocharger

  9. Elements - 2 • Defining the project • grouping • Setting priorities • Costs of parts/ components • Field population • Wear or failure rate

  10. Element - 3 • Define reusable • Life? (80 % -100 %) • Used only on the same machine? • Risk of failure? • Fatigue life? • Remaining failure is often impossible • to determine

  11. Limits • Approximate reusable limits • Salvaging options • Second life probability • Laboratory tests • Field tests • Historical data

  12. Implementation - 1 • Measuring • Inspection tools • Visual, transducers, machine optics • Applications • severity factor

  13. Implementation - 2 • Failure analysis • Credibility of guidelines • Standardizing failure interpretation • Improves service quality • Sells more parts and service

  14. Evaluation • Maintain historical data on • Repair • Performance • Life • Failure modes and effects • Correlation with product batch

  15. Example: Motor Reuse - 1 • Today’s automobiles carry up to 100 electric • motors • There are two brushless and two stepping motors • and one or two brushless fan motors in a laptop • computer. • It is estimated for an average North American • household to have 60-80 electric motors, without • accounting for automobiles. Source: Klausner et al., 1998, Journal of Industrial Ecology, 2(2), pp.89-102.

  16. Example: Motor Reuse - 2 • Commutator motors mainly consist of steel, copper, and plastics. These materials cannot be easily separated at end of life. • Revenues of only some $22 per ton or $0.02 per motor (1998).

  17. Example: Motor Reuse - 3 • Reuse Potential • Not compromise product quality • Meet functional requirements of new motors • Need a thorough understanding of used motors’ failure mechanisms and causes

  18. Example: Motor Reuse - 4 • Assessment of the Reuse Potential • Need information on the degradation of the • motors • Approaches to assess reuse potential • Testing parameters after product return • Recording parameters during product use

  19. Example: Motor Reuse - 5 • Testing parameters after product return • Requires the identification of parameters that indicates degree of degradation (e.g., noise, torque. • Shortcoming: • Long time required for testing • High labor cost • Hard to identify the parameters that • reliably shows the degree of degradation

  20. Example: Motor Reuse - 6 • Recording parameters during product use • The temperature of certain spots on the motor • The number of starts and stops of the motor • The accumulated runtime of the motor • The power consumption

  21. Example: Motor Reuse - 7 • Changes in Design • Introduce one electronic data log (EDL), which records the history of the product’s usage and shows the degradation of the product when product is recovered. • Design for disassembly to allow the old motor to be removed intact.

  22. Example: Motor Reuse - 8 • EDL records and analyzes the following data • The number of starts and stops of the motor • The accumulated runtime of the motor • Motor temperature and the power consumption • Peak and average values of all parameters of interest

  23. Example: Motor Reuse - 9 • Economic efficiency • Additional cost incurred by EDL • Return rate • - Depends on consumers’ willing etc. • Recovery rate • - Determined by the return rate of old products • and the yield in the product recovery stage

  24. Big Picture - 1 • Less resources used • Resources diverted from waste stream • Savings in cost

  25. Big Picture - 2 • Setting up: • Classification • Clustering, group theory • Design for reuse • Tolerances, nominal dimensions, effect on performance • Failure mode and effects analysis

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