1 / 11

An introduction to Factory Physics

An introduction to Factory Physics. Main Objectives. Provide an analytical characterization of the operation of production systems and their performance, based on queueing-theoretic models

jannetteg
Télécharger la présentation

An introduction to Factory Physics

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. An introduction to Factory Physics

  2. Main Objectives • Provide an analytical characterization of the operation of production systems and their performance, based on queueing-theoretic models • Derive qualitative insights on the attributes and factors that shape the behavior and performance of these systems. • Focus primarily on flow lines, since they are the main layout used in the context of high-volume, repetitive manufacturing. • Also, flow line dynamics are easier to trace and analyze, and therefore, more enlightening in terms of qualitative and quantitative insights. • However, many of the derived insights and results are extensible to more complex environments either directly or through some appropriate decomposition.

  3. A conceptual characterization of the considered environment • Flow line: A sequence of workstations supporting the production of a single part type. • Each workstation consists of one or more identical servers executing one particular stage of the entire production process. • The part processing time at each workstation follows some general distribution which must be defined in such a way that accounts for the various detractors affecting the station operations; these detractors will include machine downtime, lack of consumables, operator unavailability, experienced set-up times, preventive maintenance, etc. • Finished parts could constitute end items or raw material for some other downstream process. • The operation of the line workstations can be decoupled through the installation of some buffering capacity between them. • Some performance measures of interest: line capacity (i.e., maximum sustainable production rate or throughput), line cycle time, average Work-In-Porcess (WIP) accumulated at different stations, expected utilization of the station servers.

  4. Production Authorization Mechanisms • The issue here is to what extent part production is triggered from actual orders or from forecasted demand. • In a “produce-to-stock” scheme, a certain amount of end-item inventory is maintained in an effort to serve the experienced demand with zero lead time. • “Produce-to-stock” operation is most appropriate for highly commoditized and standardized items. • A key performance measure for “produce-to-stock” production systems is the fill rate, i.e. the percentage of the experienced demand that is actually met from stock. • In a “produce-to-order” scheme, end items are produced in response to particular orders. • “Produce-to-order” operation is more appropriate for (highly) customized items. • A key performance measure for “produce-to-order” production is the attained service level, i.e. the percentage of orders that are served within the quoted lead time. • In practice, many systems are a hybrid scheme consisting of some “produce-to-stock” and some “produce-to-order” components. • In particular, today’s mass customization is supported by an “assemble-to-order” scheme where end-items are assembled to order from a number of sub-assemblies that are produced to stock.

  5. Shop-Floor / Line Control Mechanisms • Mechanisms that control the part release and advancement through the line. • They are broadly distinguished into “push” and “pull” mechanisms. • A “push” mechanism releases material into the line according to a target production rate, and material is advanced to downstream stations as early as possible. • Typical instantiations of “push” systems are: the asynchronous transfer line and the synchronous transfer line. • A “pull” system controls the part release and advancement in the line taking into consideration the status of the various workstations in the line. • Typical instantiations of “pull” systems are: the KANBAN and the CONWIP (controlled) production lines. • In general, “pull” systems reduce congestion, since they take into consideration the actual shop-floor status in their decision making, but the same mechanisms will also make them more inert in case of shifts in the production level. • Both mechanisms are effectively implementable in a “produce-to-stock” or “produce-to-order” context.

  6. Asynchronous Transfer Lines W1 W2 W3 TH TH TH TH B1 M1 B2 M2 B3 M3 • Some important issues: • What is the maximum throughput that is sustainable through this line? • What is the expected cycle time through the line? • What is the expected WIP at the different stations of the line? • What is the expected utilization of the different machines? • How does the adopted batch size affect the performance of the line? • How do different detractors, like machine breakdowns, setups, and maintenance, affect the performance of the line?

  7. Synchronous Transfer Lines • The key issue (Assembly Line Balancing – ALB) • Given • a set of tasks to be supported by the line stations • each possessing a nominal processing time, • a number of precedence constraints among these tasks, • and a target throughput, • determine • a partitioning of these tasks to a number of stations that observes the aforementioned specifications, while it minimizes the resulting number of stations (and therefore, the resulting labor cost).

  8. Station 1 Station 2 Station 3 KANBAN-based production lines • Some important issues: • What is the throughput attainable by a certain selection of KANBAN levels? • What is the resulting cycle time? • How do we select the KANBAN levels that will attain a desired production rate? • How do we introduce the various operational detractors into the model?

  9. FGI Station 1 Station 2 Station 3 CONWIP-based production lines • Some important issues: • Same as those for the KANBAN model, plus • How can we compare the performance of such a system to that of an asynchronous transfer line and/or a KANBAN-based system?

  10. Plan for this part of the course • Modeling and Performance Analysis of Asynchronous Transfer Lines through a Series of G/G/m queues • Investigating the effect of blocking • Design of Asynchronous Transfer Lines • Design of Synchronous Transfer Lines • Modeling the impact of operational detractors • Employing factory physics in line diagnostics • Modeling and Performance Analysis of CONWIP-based production lines through Closed Queueing Networks • Designing batching policies based on factory physics • A comparison of the various “push” and “pull”-based production systems

  11. Reading Assignment This part of the course is based on • Chapters 7-10 and • Chapter 18 of your textbook, plus on • any other material reported or quoted in class.

More Related