750 research outputs found
Object Oriented Automation Systems
This master's thesis is about the implementation and evaluation of a small object-oriented automation system. By using a realtime Java VM from Jamaica, a sheet feeding magazine from the machine Tetra Aptiva Aseptic has been controlled. The expectations included to achieve more structured and safer programming, better documentation through UML and to separate application developers from developers of basic functionality. The work has involved to understand the existing control program, to design an object oriented model in Java and to run it on a test rack. The system worked fine, and most expectations were fulfilled. The performance measurements indicated that the Java was fast but also had a slightly larger jitter
Design, modelling, simulation and integration of cyber physical systems: Methods and applications
The main drivers for the development and evolution of Cyber Physical Systems (CPS) are the reduction of development costs and time along with the enhancement of the designed products. The aim of this survey paper is to provide an overview of different types of system and the associated transition process from mechatronics to CPS and cloud-based (IoT) systems. It will further consider the requirement that methodologies for CPS-design should be part of a multi-disciplinary development process within which designers should focus not only on the separate physical and computational components, but also on their integration and interaction. Challenges related to CPS-design are therefore considered in the paper from the perspectives of the physical processes, computation and integration respectively. Illustrative case studies are selected from different system levels starting with the description of the overlaying concept of Cyber Physical Production Systems (CPPSs). The analysis and evaluation of the specific properties of a sub-system using a condition monitoring system, important for the maintenance purposes, is then given for a wind turbine
A brief comparison of real-time software design methods
This paper briefly attempts to compare several mainstream methods/methodologies that are used for the analysis and design of real time systems. These are i) CORE, ii) YSM, iii) MASCOT, iv) CODARTS, v) HOOD, vi) ROOM, vii) UML, viii) UML-RT. Methods i-iii are use a data driven approach, whilst methods iv-vii use an object-oriented approach. All these methods have their advantages and disadvantages. Thus it is difficult to decide which method is best suited to a particular real-time design situation. Some methods like YSM, MASCOT and CODARTS are more oriented towards designing event driven systems and reactive behavior. Object oriented methods like the UML have many diagrams obtained from other methods. In the first part of the paper each method is briefly presented and its main features are explained. In the second part a score based ranking is used to try to identify which method has the best overall characteristics for real time development. The final results are presented in a tabular form and using a bar chart. In addition to this it is explained how each method fits in the SDLC. Both the score of each method and how it fits in the SDLC must be considered when selecting methods. To conclude some other issues are explained, because the selection of one method does not automatically imply that there will not be any problems.peer-reviewe
Component-based control system development for agile manufacturing machine systems
It is now a common sense that manufactures including machine suppliers and system
integrators of the 21 st century will need to compete on global marketplaces, which are
frequently shifting and fragmenting, with new technologies continuously emerging.
Future production machines and manufacturing systems need to offer the "agility"
required in providing responsiveness to product changes and the ability to
reconfigure. The primary aim for this research is to advance studies in machine
control system design, in the context of the European project VIR-ENG - "Integrated
Design, Simulation and Distributed Control of Agile Modular Machinery"
A Framework for Industry 4.0
The potential of the Industry 4.0 will allow the national industry to develop all kinds of
procedures, especially in terms of competitive differentiation. The prospects and motivations
behind Industry 4.0 are related to the management that is essentially geared towards industrial
internet, to the integrated analysis and use of data, to the digitalization of products and services,
to new disruptive business models and to the cooperation within the value chain. It is through
the integration of Cyber-Physical Systems (CPS), into the maintenance process that it is
possible to carry out a continuous monitoring of industrial machines, as well as to apply
advanced techniques for predictive and proactive maintenance.
The present work is based on the MANTIS project, aiming to construct a specific
platform for the proactive maintenance of industrial machines, targeting particularly the case
of GreenBender ADIRA Steel Sheet. In other words, the aim is to reduce maintenance costs,
increase the efficiency of the process and consequently the profit. Essentially, the MANTIS
project is a multinational research project, where the CISTER Research Unit plays a key role,
particularly in providing the communications infrastructure for one MANTIS Pilot.
The methodology is based on a follow-up study, which is jointly carried with the client,
as well as within the scope of the implementation of the ADIRA Pilot. The macro phases that
are followed in the present work are: 1) detailed analysis of the business needs; 2) preparation
of the architecture specification; 3) implementation/development; 4) tests and validation; 5)
support; 6) stabilization; 7) corrective and evolutionary maintenance; and 8) final project
analysis and corrective measures to be applied in future projects.
The expected results of the development of such project are related to the integration of
the industrial maintenance process, to the continuous monitoring of the machines and to the
application of advanced techniques of preventive and proactive maintenance of industrial
machines, particularly based on techniques and good practices of the Software Engineering area
and on the integration of Cyber-Physical Systems.O potencial desenvolvido pela Indústria 4.0 dotará a indústria nacional de capacidades
para desenvolver todo o tipo de procedimentos, especialmente a nível da diferenciação
competitiva. As perspetivas e as motivações por detrás da Indústria 4.0 estão relacionadas com
uma gestão essencialmente direcionada para a internet industrial, com uma análise integrada e
utilização de dados, com a digitalização de produtos e de serviços, com novos modelos
disruptivos de negócio e com uma cooperação horizontal no âmbito da cadeia de valor. É
através da integração dos sistemas ciber-físicos no processo de manutenção que é possível
proceder a um monitoramento contínuo das máquinas, tal como à aplicação de técnicas
avançadas para a manutenção preditiva e pró-ativa das mesmas.
O presente trabalho é baseado no projeto MANTIS, objetivando, portanto, a construção
de uma plataforma específica para a manutenção pró-ativa das máquinas industriais, neste caso
em concreto das prensas, que serão as máquinas industriais analisadas ao longo do presente
trabalho. Dito de um outro modo, objetiva-se, através de uma plataforma em específico, reduzir
todos os custos da sua manutenção, aumentando, portanto, os lucros industriais advindos da
produção. Resumidamente, o projeto MANTIS consiste num projeto de investigação
multinacional, onde a Unidade de Investigação CISTER desenvolve um papel fundamental,
particularmente no fornecimento da infraestrutura de comunicação no Piloto MANTIS.
A metodologia adotada é baseada num estudo de acompanhamento, realizado em
conjunto com o cliente, e no âmbito da implementação do Piloto da ADIRA. As macro fases
que são compreendidas por esta metodologia, e as quais serão seguidas, são: 1) análise
detalhada das necessidades de negócio; 2) preparação da especificação da arquitetura; 3)
implementação/desenvolvimento; 4) testes e validação; 5) suporte; 6) estabilização; 7)
manutenção corretiva e evolutiva; e 8) análise final do projeto e medidas corretivas a aplicar
em projetos futuros.
Os resultados esperados com o desenvolvimento do projeto estão relacionados com a
integração do processo de manutenção industrial, a monitorização contínua das máquinas e a
aplicação de técnicas avançadas de manutenção preventiva e pós-ativa das máquinas,
especialmente com base em técnicas e boas práticas da área de Engenharia de Software
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