Loose Coupling Based Reference Scheme for Shop Floor-Control-System/Production-Equipment Integration.

Acoplamiento del sistema informático de control de piso de producción (SFS) con el conjunto de equipos de fabricación (SPE) es una tarea compleja. Tal acoplamiento involucra estándares abiertos y propietarios, tecnologías de información y comunicación, entre otras herramientas y técnicas. Debido a la turbulencia de mercados, ya sea soluciones personalizadas o soluciones basadas en estándares eventualmente requieren un esfuerzo considerable de adaptación. El concepto de acoplamiento débil ha sido identificado en la comunidad de diseño organizacional como soporte para la sobrevivencia de la organización. Su presencia reduce la resistencia de la organización a cambios en el ambiente. En este artículo los resultados obtenidos por la comunidad de diseño organizacional son identificados, traducidos y organizados para apoyar en la solución del problema de integración SFS-SPE. Un modelo clásico de acoplamiento débil, desarrollado por la comunidad de estudios de diseño organizacional, es resumido y trasladado al área de interés. Los aspectos claves son identificados para utilizarse como promotores del acoplamiento débil entre SFS-SPE, y presentados en forma de esquema de referencia. Así mismo, este esquema de referencia es presentado como base para el diseño e implementación de una solución genérica de acoplamiento o marco de trabajo (framework) de acoplamiento, a incluir como etapa de acoplamiento débil entre SFS y SPE. Un ejemplo de validación con varios conjuntos de equipos de fabricación, usando diferentes medios físicos de comunicación, comandos de controlador, lenguajes de programación de equipos y protocolos de comunicación es presentado, mostrando un nivel aceptable de autonomía del SFS. = Coupling shop floor software system (SFS) with the set of production equipment (SPE) becomes a complex task. It involves open and proprietary standards, information and communication technologies among other tools and techniques. Due to market turbulence, either custom solutions or standards based solutions eventually require a considerable effort of adaptation. Loose coupling concept has been identified in the organizational design community as a compensator for organization survival. Its presence reduces organization reaction to environment changes. In this paper the results obtained by the organizational de sign community are identified, translated and organized to support the SFS-SPE integration problem solution. A classical loose coupling model developed by organizational studies community is abstracted and translated to the area of interest. Key aspects are identified to be used as promoters of SFS-SPE loose coupling and presented in a form of a reference scheme. Furthermore, this reference scheme is proposed here as a basis for the design and implementation of a generic coupling solution or coupling framework, that is included as a loose coupling stage between SFS and SPE. A validation example with various sets of manufacturing equipment, using different physical communication media, controller commands, programming languages and wire protocols is presented, showing an acceptable level of autonomy gained by the SFS

Methodology to develop hybrid simulation/emulation model.

Trends towards reduced life-time of products and globalised competition has increased pressure on manufacturing industries to be more responsive to changing needs of product markets. Consequently, the use of simulation to describe short term future performance of manufacturing system has become more significant than ever. An application of simulation that has attracted attention is for testing of control logic before commissioning on site by using a detailed simulation model called emulation model. However, though the success of using emulation particularly in improving cost-effectiveness of automated material handling system delivery has been acknowledged by industries and simulation model developers, the uptake for this technology is still low. The major inhibitors are the high costs of its model building as well as simulation and emulation models are perceived to be non convertible.The main objective, of this research is to establish a methodology to develop simulation model that can be converted into emulation model with ease, thus making emulation technology more affordable. The product of this research called the methodology to build Hybrid Simulation Emulation Model (HSEM) is a new approach of building emulation model comprising of three phases namely (1) development of base simulation model, (2) development of detail emulation model, and (3) integration of controller with the emulation model. Important requirements for HSEM are flexibility of adding details to the simulation model and inter process communication between model and real control system. To facilitate implementation of the methodology, it is essential that the simulation software package provide functionalities for modular model development, access and adding of codes, integration with other application and real time (RT) modelling.The methodology developed offers a more affordable emulation modelling and an opening for further research into the comprehensive support for the implementation of real time control system testing using emulation

Modélisation du processus de pilotage d'un atelier en temps réel à l'aide de la simulation en ligne couplée à l'exécution

Ce travail de recherche met en avant l'intérêt qu'offre la simulation en ligne comme outil d'aide à la décision, outil centré sur le pilotage d'atelier vis-à-vis d'événements se produisant en temps réel et pour un horizon à très court terme. Après avoir présenté le contexte général du pilotage des systèmes de production, nous avons étudié les outils existants et utilisés industriellement pour l'exploitation de la production, de même que les outils d'aide au pilotage permettant d'assurer le respect optimal des objectifs fixés. Après un travail préalable sur la simulation hors ligne, nous proposons de coupler un outil de simulation en ligne à un outil d'exécution d'atelier de type MES afin de piloter en temps réel le processus de production. Une démarche de modélisation faisant appel de façon complémentaire à deux approches, analytique et simulatoire, est finalement mise en place. Nous mettons en exergue l'utilisation de la simulation de flux en ligne pour aider au pilotage d'un processus opérationnel. Ainsi nous modélisons le processus de pilotage en temps réel afin de décrire les fonctions requises. Pour cela, nous utilisons différentes stratégies d'utilisation des simulateurs en ligne pour le pilotage, avec un ou deux modèles et avec plusieurs méthodes d'utilisation de ces modèles. La simulation en ligne apporte alors des informations objectives sur les conséquences à court terme d'un événement, ainsi que sur les divers scenarii de correction envisagés. Pour mieux convaincre les industriels de l'intérêt de la simulation en ligne, nous présentons des solutions pratiques aux spécifications et besoins énoncés précédemment en nous appuyant sur une plate-forme expérimentale. ABSTRACT : This research work highlights the interest of online simulation as a decision support tool. This tool is focused on workshop control in relation with real time and short-term events. Online simulation enables to analyze and compare scenarios affecting the production, such as failures or unexpected orders. Moreover online simulation allows a very short term projection in the future in order to quantify the consequences of some unexpected event: we call it projection simulation. Finally, online simulation is helpful to choose the solution that will reduce the impact of a critical event, through the simulation of several scenarios. To conclude, online simulation is one the most interesting decision support tool in workshop piloting. However, there are few industrial applications in manufacturing systems. The first part of this research work introduces the overall context of production system management. The different generic functions of controlling the production, the modes of piloting and the evolutions of workshop are detailed. We also explain piloting typologies according to their reactivity. In the second part, we study the existing software tools used in industry for the operation of production, and support tools that ensure optimal compliance in regard to the objectives. After a preliminary work on the offline simulation, we propose to couple an online simulation tool with a type MES delivery tool in order to control the production process in real time. A modeling approach using two complementary approaches, an analytical one and simulation, is then introduced. The objective of the third part is to emphasize the use of online flow simulation to assist in operating a production process. Thus we model the process in real time to describe the required functions. Therefore we try out different strategies of use of online simulators, through one or two models and several methods of using these models. Online simulation then provides realistic information on the short-term consequences of an event, as well as on the different ways of correcting the scenarios. To convince industry of the relevance of online simulation, the fourth part presents practical solutions to the specifications and requirements previously stated. An experimental platform helped us validate the concept of online simulation as piloting support tool, but also underline the difficulties of development