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Part III Performance evaluation and design of manufacturing systems

Part III Performance evaluation and design of manufacturing systems. Objectives. Understanding important performance measures of manufacturing systems Understanding the impact of random perturbation on manufacturing systems

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Part III Performance evaluation and design of manufacturing systems

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  1. Part III Performance evaluation and design of manufacturing systems

  2. Objectives Understanding important performance measures of manufacturingsystems Understanding the impact of random perturbation on manufacturingsystems Developping a system theoryapproach for performance evaluation and design of manufacturingsystems

  3. Problems Manufacturingsystems engineering not as advanced as otherfields of engineering Practitionersencouraged to rely on gurus, slogans, and black boxes Gap betweentheoreticians and practitioners Separation of product, process, and system design

  4. Problems • Confusions about objectives • maximize capacity • minimize capacity variability • maximize capacity utilization • minimize leadtime • minimize leadtime variability • maximize profit • System issues are often studied last, if at all.

  5. Problems • Manufacturing gets no respect • Systems not designed with engineering methods • Product designers and sales staff are not informed of manufacturing costs and constraints • Black box thinking • Factories not treated as systems to be analyzed and engineered • Simplistic ideas often used for management and design.

  6. Problems • Reliable systems intuition is lacking. As a consequence, there is … • Management by software • managers buy software to make production decisions, rather than to aid in making decisions • Management by slogan • Gurus provide simple solutions which sometimes work. Sometimes.

  7. Observations When a system is not well understood, rules proliferate. This is because rules are developed to regulate behavior But the rules lead to unexpected, undesirable behavior. New rules are developed to regulate the new behavior. Et cetera.

  8. Observations - example A factory starts with one rule: do th latest jobs first. Over time, more and more jobs are later and later. A new rule is added: treat the highest priority customers orders as though their due dates are two weeks earlier than they are. The low priority customers find other suppliers, but the factory is still late.

  9. Basic issues Frequent new product introductions Product lifetimes often short Process lifetimes often short This leads to frequent building and rebuilding of factories.

  10. Basic issues – consequent needs Tools to predict performance of proposed factory design. Tools for optimal real-time management (control of facories. Manufacturing systems engieering professionals who understand factories as complex systems

  11. Basic issues – Quantity, quality and variability Quantity – how much and when Quality – how well. We emphasize quantity. General statement: variability is the enemy of manufacturing.

  12. Basic issues – concepts operator machine Operations part part waste Consumable Nothing happens until everything is present.

  13. Basic issues – concepts Waiting: whateverdoes not arrive last must wait. Inventory : parts waiting Underutilization: machine waiting Idlework force: operatorswaiting.

  14. Kinds of systems Flow shop, flow line, tranfer line, production line machine Buffer ou stock tampon Traditionally used for high volume, low variety production.

  15. Kinds of systems Assembly system Assembly systems are trees, and may involve thousands of parts.

  16. Kinds of systems Closed loop lines with limited number of pallets empty pallet buffer Pallets or fixtures travel in a closed loop.

  17. Kinds of systems Reentrant systems type2 type 1 Semiconductor fabircation is highly reentrant.

  18. Kinds of systems Job-shops: Machines not organized according to process flow. Often, machines grouped by department Great variety of products. Different products follow different paths. Complex management.

  19. Two issues Effient design of systems Efficient operation of systems after they are built.

  20. Time Most factory performance measures are about time. Production rate: how much is made in a given time. lead time: how much time before delivery cycle time: how much time a part spends in the factory (leadtime) delivery reliability: how often a factory delivers on time capital pay-back period: the time before the company get its investment back.

  21. Time • Time appears in two forms • delay • capacity utilization • Every action has impact on both.

  22. Time – Capacity utilization An operation that takes 10 min takes up 10 min of the available time of a machine an operator or other resources Since there are a limited number of minutes of each resource available, there are a limited number of operations that can be done.

  23. Time – Production rate Operation time: the time that a machine takes to do an operation Production rate: the average number of parts produced in a time unit (also called throughput) If nothing interesting happens (no failures, etc) Production rate = 1 / operation time … but something interesting always happens.

  24. Time – Capacity • Capacity: the maximum possible production rate of a manufacturing system, for systems that are making only one part type. • Short term capacity: determined by the resources available right now • Long term capacity: determined by the average resource availability • Capacity is harder to define for systems making several part types. It depends on the product mix.

  25. Randomness, variability, uncertainty • Factories are full of random events: • machine failures • changes in orders • quality failures • human variability • The economic environment is uncertain • demand variations • supplier unreliability • changes in costs and prices

  26. Randomness, variability, uncertainty • Therefore, factories should be • designed as reliable as possible, to minimize the creation of variability • designed with shock absorbers, to minimize the propagation of variability • operated in a way that minimizes the creation of variability • operated in a way that minimizes the propagation of variability.

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