Future Manufacturing Systems edited by Dr. Tauseef Aized SCIYO Future Manufacturing Systems Edited by Dr. Tauseef Aized Published by Sciyo Janeza Trdine 9, 51000 Rijeka, Croatia Copyright © 2010 Sciyo All chapters are Open Access articles distributed under the Creative Commons Non Commercial Share Alike Attribution 3.0 license, which permits to copy, distribute, transmit, and adapt the work in any medium, so long as the original work is properly cited. After this work has been published by Sciyo, authors have the right to republish it, in whole or part, in any publication of which they are the author, and to make other personal use of the work. Any republication, referencing or personal use of the work must explicitly identify the original source. Statements and opinions expressed in the chapters are these of the individual contributors and not necessarily those of the editors or publisher. No responsibility is accepted for the accuracy of information contained in the published articles. The publisher assumes no responsibility for any damage or injury to persons or property arising out of the use of any materials, instructions, methods or ideas contained in the book. Publishing Process Manager Jelena Marusic Technical Editor Goran Bajac Cover Designer Martina Sirotic Image Copyright Yuri Samsonov, 2010. Used under license from Shutterstock.com First published September 2010 Printed in India A free online edition of this book is available at www.sciyo.com Additional hard copies can be obtained from publication@sciyo.com Future Manufacturing Systems, Edited by Dr. Tauseef Aized p. cm. ISBN 978-953-307-128-2 SCIYO.COM WHERE KNOWLEDGE IS FREE free online editions of Sciyo Books, Journals and Videos can be found at www.sciyo.com Chapter 1 Chapter 2 Chapter 3 Chapter 4 Chapter 5 Chapter 6 Chapter 7 Chapter 8 Chapter 9 Chapter 10 Preface VII Flexible manufacturing system: hardware components 1 Dr. Tauseef Aized Discrete event models for flexible manufacturing cells 17 Constantin Filote and Calin Ciufudean Process rescheduling: enabling performance by applying multiple metrics and efficient adaptations 39 Rodrigo da Rosa Righi, Laércio Pilla, Alexandre Carissimi, Philippe Navaux and Hans-Ulrich Heiss Reliability Modeling and Analysis of Flexible Manufacturing Cells 65 Mehmet Savsar Multi agent and holonic manufacturing control 95 Sugimura Nobuhiro, Tehrani Nik Nejad Hossein and Iwamura Koji Materials handling in flexible manufacturing systems 121 Dr. Tauseef Aized Scheduling methods for hybrid flow shops with setup times 137 Larysa Burtseva, Victor Yaurima and Rainier Romero Parra ACO-based Multi-objective Scheduling of Identical Parallel Batch Processing Machines in Semiconductor Manufacturing 163 Li Li, Pan Gu, Fei Qiao, Ying Wu and Qidi Wu Axiomatic Design of Agile Manufacturing Systems 179 Dominik T. Matt A Blended Process Model for Agile Software Development with Lean Concept 195 Indika Perera Contents VI Chapter 11 Chapter 12 Process Monitoring Systems for Machining Using Audible Sound Energy Sensors 217 Eva M. Rubio and Roberto Teti Hybrid particle swarm algorithm for job shop scheduling problems 235 Xiaoyu Song Manufacturing is a vital activity for a society from a strategic point of view. It has a long history in human civilizations and gives a society a denite edge over its competitors. A manufacturing system can be viewed as an arrangement of tasks and processes, properly put together, to transform a selected group of raw materials and semi-nished products to a set of nished products. Historically, manufacturing activities have grown over centuries and their evolution can be divided into three stages. These are craft, mass and lean production methods. The development of electrical devices has led to better control of machines and resulted in machines with greater exibility. Recent developments in information technology have made it feasible to achieve the purpose of rapid product prototyping, concurrent engineering, exible and agile automation and computer integrated manufacturing. Many manufacturing system paradigms have been developed throughout the history of manufacturing, such as mass production, just in time manufacturing, lean manufacturing, exible manufacturing, mass customization, agile manufacturing and others. All these systems are working efciently under particular conditions attached to them. With the overall evolution of human society, product demand patterns are changing which force manufacturers to adjust their system paradigms according to changes. Thus, a change of product demand patterns always demands to remodel and improve manufacturing system designs, layouts, facilities and provisions which lead to an ongoing search of development of new ways and means of designing modern manufacturing systems. This book is a collection of articles aimed at nding new ways of manufacturing systems developments. The articles included in this volume comprise of current and new directions of manufacturing systems which I believe can lead to the development of more comprehensive and efcient future manufacturing systems. People from diverse background like academia, industry, research and others can take advantage of this volume and can shape future directions of manufacturing systems. Editor Dr. Tauseef Aized Professor, Mechanical Engineering, University of Engineering and Technology (UET)- KSK campus, Lahore, Pakistan and Research Fellow, Institute for Manufacturing (IFM), University of Cambridge, UK August 29, 2010. Preface Flexible manufacturing system: hardware components 1 Flexible manufacturing system: hardware components Dr. Tauseef Aized X Flexible manufacturing system: hardware components Dr. Tauseef Aized Professor, Department of Mechanical , Mechatronics and Manufacturing Engineering, KSK Campus, University of Engineering and Technology, Lahore, Pakistan A flexible manufacturing system is a highly automated system consisting of a group of workstations interconnected by an automated material handling and storage system and controlled by a distributed computer system. It is capable of processing a variety of different part styles simultaneously at various workstations and the mix of part styles and quantities of production can be adjusted in response to changing demand patterns. A flexible manufacturing system comprises of processing stations, material handling and storage systems and requires hardware and software provisions. The hardware components typically required for a FMS are; Machine tools, for example, machining centers, turning centers, etc. Load/unload stations Guided vehicles Robots Inspection facilities like coordinate measuring machines Programmable Logic Controllers (PLC). This chapter describes the hardware provisions required for a flexible manufacturing system. Introduction Flexible manufacturing systems consist of hardware and software components. The hardware components typically comprise of processing stations, material handling systems and automated material storage and retrieval systems. The processing stations are the workstations that perform different operations on part families. These workstations are CNC machine tools, inspection equipments, assembly stations and material loading/ unloading areas. Material handling systems include automated guided vehicle systems, roller conveyors, tow line, shuttle cars etc whereas automated storage and retrieval systems are used to store and retrieve work parts automatically. Various types of storage and retrieval systems are pallets, carousels etc which help in convenient access of different types of parts from stores and increase machine utilization of flexible manufacturing systems. The 1 Future Manufacturing Systems2 processing and assembly equipments used in a flexible manufacturing system depend upon the type of work being accomplished by the system. In a system designed for machining operations, the principal types of processing stations are CNC machines like CNC machining and turning centers. However, the FMS concept is applicable to various other processes like automated assembly lines, sheet metal fabrication etc. Machining Stations One of the most common applications of flexible manufacturing system is in the machining operations. The workstations designed in these systems, therefore, predominantly consist of CNC machines tools. The most common CNC machines tools used include CNC machining center, in particular, horizontal machining turning centers. These CNC machine tools possess the features that make them compatible with the FMS. These features include automatic tool changing and storage, use of palletized work parts, etc. CNC Machining Center A CNC machining center is a highly automated machine tool capable of performing multiple machining operations under CNC control in one setup with minimal human attention. Machining centers generally include automated pallet changers to load the work part to the machine and to unload the finished part that can be readily interfaced with the FMS part handling system. A CNC machining center is a sophisticated CNC machine that can perform milling, drilling, tapping, and boring operations at the same location with a variety of tools. Fig. 1. CNC Horizontal Machining Center There are several special features that make a machining center more productive machine are as follows: Automatic tool-changing As there is a variety of machining operations to be performed by the machines on different part styles in a FMS environment, so cutting tools must be changed to switch from one machining operation to another. This is done on a machining center under NC program control by an automated tool-changer designed to exchange cutters between the machine tool spindle and a tool storage drum. The capacities of these drums commonly range from 16 to 80 cutting tools. Fig. 2. Tool Storage Pallet shuttles Some machining centers in FMS are equipped with two or more pallet shuttles, which can automatically transfer the work part to the spindle of the machining center to perform the machining operation on it. With two shuttles, the operator may unload the finished part and load the next raw part on load/unload station while the machine tool is engaged in machining the current part. This reduces nonproductive time on the machine. [...]... Production Systems and Computer Integrated Manufacturing , 3rd Edition, Pearson Education, Inc., 2008 2 Implementing Flexible Manufacturing Systems by Greenwood, Nigel Published by M Macmillan Education 1988 3 Flexible manufacturing system (FMS): the investigative phase By David L Setter, Published by Technical Communications, Kansas City Division, Allied-Signal Aerospace, 1993 4 Flexible Manufacturing Systems: ... theory and practice, By Ali K Kamrani, Emad Abouel Nasr 7 http://www.robots.com 16 Future Manufacturing Systems Discrete event models for flexible manufacturing cells 17 2 X Discrete event models for flexible manufacturing cells Constantin Filote and Calin Ciufudean Stefan cel Mare University of Suceava Romania 1 Introduction A manufacturing system includes a set of machines performing different operations,... - t - T1i + Analogous results with those of the previous section are obtained: Pi+1=1+int {[BL(i) + pri (T2i - T1i)] pr1 i } pr1 pr i i (19) 24 Future Manufacturing Systems 3 The System Model of Flexible Manufacturing Cells In this paper, a flexible manufacturing system (FMS) is treated as a discrete event system and we consider that the system evolution constitutes a discrete state-space stochastic... part on load/unload station while the machine tool is engaged in machining the current part This reduces nonproductive time on the machine 4 Future Manufacturing Systems Automatic work part positioning To enhance the productivity of a machine tool and to reduce the manufacturing lead time, machine tools in FMS are equipped with automatic work part positioning system that exactly position the work part... cylindrical work part at a specified angle so that a rotating cutter can machine features into the outside surface of the work part Flexible manufacturing system: hardware components Fig 4 CNC Turning Center Fig 5 CNC mill-turn center 5 6 Future Manufacturing Systems Load/Unload Stations Load/unload station is the physical interface between an FMS and the rest of the factory It is the place where raw... starvation Thus, production lines may be modeled as sets of machines and buffers connected according to a certain topology From a system theoretic perspective, production 18 Future Manufacturing Systems lines are discrete event systems Two basic models of machine reliability are mentioned in the literature: Bernoulli (Jacobs & Meerkov, 1995) and Markov (Gershwin, 1994), (Lim et al., 1990) The first... are coincident with a cartesian coordinator Fig 7 A Cartesian robot 8 Future Manufacturing Systems Fig 8 A Gantry robot Cylindrical robot These robots are used for assembly operations, spot welding, and handling at die-casting machines It's a robot whose axes form a cylindrical coordinate system Fig 9 A cylindrical robot Flexible manufacturing system: hardware components 9 Spherical/Polar robot The... the flexible manufacturing system The basic cell of the proposed model for flexible manufacturing system analysis consists of a machine, for example Mi, its upstream buffer Bi-1 and its downstream buffer Bi In Fig 4 we have the Markov chain representation of the basic cell of our model for flexible manufacturing system analysis and in Fig 5 we depicted our Makov chain model for flexible manufacturing. .. large number of components with failure/repair processes, the system-level Markov model becomes computationally intractable In this paper, a decomposition approach for the analysis of manufacturing systems is decomposed in manufacturing cells A Markov chain is constructed and solved for each cell i to determine the probability of at least Ni operational machines at time t Ni satisfies the production capacity... in addition to CMM station These machines inspect equipment in work centers by inserting a probe into the gripper or spindle and then moving the probe contacting the work piece or fixture 14 Future Manufacturing Systems Fig 18 Example of on-machine checking and inspection Programmable Logic Controllers (PLC’s): A programmable logic controller (PLC) is a microcomputer-based controller that uses stored . Future Manufacturing Systems edited by Dr. Tauseef Aized SCIYO Future Manufacturing Systems Edited by Dr. Tauseef Aized Published by Sciyo Janeza. integrated manufacturing. Many manufacturing system paradigms have been developed throughout the history of manufacturing, such as mass production, just in time manufacturing, lean manufacturing, . efcient future manufacturing systems. People from diverse background like academia, industry, research and others can take advantage of this volume and can shape future directions of manufacturing