Readers will learn how to integrate quality and reliability control, machine tool maintenance, production and inventory control, and suppliers into the linked-cell system for one-piece parts movement within cells and small-lot movement between cells.
Cellular manufacturing (CM) is the grouping of similar products for manufacture in discrete multi-machine cells. It has been proven to yield faster production cycles, lower in-process inventory levels, and enhanced product quality. Pioneered on a large scale by Russian, British, and German manufacturers, interest in CM methods has grown steadily over the past decade. However, there continues to be a dearth of practical guides for industrial engineers and production managers interested in implementing CM techniques in their plants. Bringing together contributions by an international team of CM experts, the Handbook of Cellular Manufacturing Systems bridges this gap in the engineering literature.
Modern Manufacturing Methodologies have undergone three different evolutionary stages over the past 200 years. Before there were modern manufacturing plants, the world only knew skilled craftsmen who labored as individuals in very small groups to produce goods and services. The first factory evolution came about when James Watt invented the steam engine. Metal cutting, forming and assembly machines were co-located near streams or rivers forming what we now call the Job Shop or the American Armory System. The second factory evolution began when Henry Ford introduced the first modern assembly line using interchangeable parts and standardized manufacturing procedures. This gave rise to the modern flow shop, which reached its zenith during WWII. In the late 1970s, the third industrial evolution began when Taiichi Ohno and the Toyota Motor Company introduced what we now call Lean Manufacturing...and the world came. Over the last 40 years, all forms of manufacturing and service systems have embraced the concepts of Lean Thinking and proved its superiority to traditional manufacturing and service systems design. This book defines and characterizes a new breed of Manufacturing Engineer which we call the Lean Engineer. The Lean Engineer has roots in traditional Industrial engineering, but is also well trained in six-sigma methodologies and understands lean to green factory design principles. However, Lean Engineering transcends and redefines the classic Industrial engineer. Principles of Lean systems design, U-shaped Lean manufacturing cells, Linked Cell Manufacturing System design and Mixed Model final assembly lines are unique Lean Engineering strategies. This book attempts to define for the first time a new manufacturing engineering discipline called the Lean Engineer. This book: Introduces Lean System Design principles Demonstrates the conversion of traditional manufacturing lines into U-shaped Lean Cells Contrasts push versus pull manufacturing strategies Covers Balancing, Leveling and System synchronization Demonstrates Value Stream Mapping and the 7-Lean analysis tools Provides an introduction to Queuing Network Analysis for single and multiple product flows ....and many more Principles which define the Lean Engineer
By reconfiguring your traditional assembly lines into production cells based on one-piece flow, you can drastically reduce your lead time, staffing requirements, and number of defects. Kenichi Sekine studied under the late Shigeo Shingo and is responsible for many recent advances in the deployment of the Toyota Production System in Japan. In this comprehensive book, Sekine provides an in-depth education into the why's and how's of the restructuring process. Sekine first examines the basic principles of process flow building, then offers detailed case studies of how various industries designed unique one-piece flow systems (parallel, L-shaped, and U-shaped floor plans) to meet their particular needs. One-Piece Flow describes each step in the process of establishing one-piece flow and: (1) provides ample "test your skills" worksheets that guide you through the solution of problems, and (2) includes over 300 illustrations and 14 single-page case studies that show how to cut assembly personnel in various industries. With this book, plant managers will learn how to eliminate overstaffing waste and build a multi-skilled work force equipped to support JIT manufacturing. The book includes: Basic concept of one-piece production Case studies Process razing techniques U-shaped cells for assembly lines Techniques for removing waste from factories Establishing one-piece flow at a factory that produces small lots on a customer-order basis "Single" delivery at MYNAC
Production and manufacturing management since the 1980s has absorbed in rapid succession several new production management concepts: manufacturing strategy, focused factory, just-in-time manufacturing, concurrent engineering, total quality management, supply chain management, flexible manufacturing systems, lean production, mass customization, and more. With the increasing globalization of manufacturing, the field will continue to expand. This encyclopedia's audience includes anyone concerned with manufacturing techniques, methods, and manufacturing decisions.
The Just-in-time (JIT) manufacturing system is an internal system in use by its founder, Toyota Motor Corporation, but it has taken on a new look. Toyota Production System, Second Edition systematically describes the changes that have occurred to the most efficient production system in use today. Since the publication of the first edition of this book in 1983, Toyota has integrated JIT with computer integrated manufacturing technology and a strategic informa tion system. The JIT goal of producing the necessary items in the necessary quantity at the necessary time is an internal driver of production and operations management. The addition of computer integrated technology (including expert systems by artificial intelligence) and information systems technology serve to further reduce costs, increase quality, and improve lead time. The new Toyota production system considers how to adapt production schedules to the demand changes in the marketplace while satisfying the goals of low cost, high quality, and timely delivery. The first edition of this book, Toyota Production System, published in 1983, is the basis for this book. It was translated into many languages including Spanish, Russian, Italian, Japanese, etc., and has played a definite role in inspiring production management systems throughout the world.
In today's business world, competitiveness defines the industrial leading edge. Organizations and businesses of all sizes are adopting Lean manufacturing practices to increase efficiency and address worries about their bottom lines. In a detailed review of this staple of Lean manufacturing, Cellular Manufacturing: Mitigating Risk and Uncertainty ou
"This book explores the recent advancements in the areas of lean production, management, and the system and layout design for manufacturing environments, capturing the building blocks of lean transformation on a shop floor level"--
The chapters included in this book represent the work from the US, Canada, Japan, China, India, Iran, Netherlands, Turkey, Slovakia, and Portugal. The book attempts to cover the cellular manufacturing area from various angles. In terms of solution techniques, different approaches such as heuristics, mathematical models, networks models, genetic algorithm approaches, artificial neural networks, knowledge-based algorithms, a space search algorithm, simulated annealing, fuzzy concepts, analytic hierarchy processes and simulation are included in the book. As for performance measures, most chapters target a single objective whereas some others cover multiple objectives. In terms of the complexity of the problems, the authors divide them into simpler single phase problems versus more complex problems that require multiple-phase solutions. Most of the chapters discuss deterministic problems. On the other hand, a few of the chapters focus on stochastic cases. There are many new concepts and solution approaches covered in this book. The details of the material coverage is listed in the following paragraphs. The book starts with the evolution of cellular manufacturing. In terms of design-related issues, it covers the application of math modeling for cell formation, family and subfamily formation, production system selection, formation and evaluation of design alternatives, machine layout, dynamic cells, virtual cells, cell formation considering alternative routes, remainder cells, cell formation with product of life cycle considerations, demand-variability based cell formation, layered cellular design, assembly cells and a recent Japanese proposition called SERU cells. All types of cells, namely labor-intensive cells, machine-intensive cells and robotic cells are covered in the book. In terms of operational and control issues, human skills, manpower allocation, cell size determination, dispatching rules, parallel machine scheduling, flowshop scheduling, re-entrant flowshop scheduling, flexible job shop scheduling, assembly line balancing, process planning and scheduling, multiple-resource scheduling, cell loading and cell scheduling, synchronized flow, planning concepts such as period batch control, polka, Kanban, conwip and more are discussed. Cases studies include electromechanical assembly, bicycle manufacturing, igniter assembly system, jewelry manufacturing and semi-conductor industry. We believe that this book will be of value to students, researchers, academicians and practitioners.