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Статті в журналах з теми "Modular Manufacturing"

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Автор: Grafiati
Опубліковано: 10 грудня 2022
Оновлено: 28 січня 2023

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1

Tsukune, H., M. Tsukamoto, T. Matsushita, F. Tomita, K. Okada, T. Ogasawara, K. Takase, and T. Yuba. "Modular manufacturing." Journal of Intelligent Manufacturing 4, no. 2 (April 1993): 163–81. http://dx.doi.org/10.1007/bf00123909.

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2

Barylski, Adam. "Configuration of modular fixtures in manufacturing." AUTOBUSY – Technika, Eksploatacja, Systemy Transportowe 19, no. 6 (June 30, 2018): 349–53. http://dx.doi.org/10.24136/atest.2018.091.

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Анотація:
The article presents construction and the assembly of designed modular handles. The work appoints, in variant mode, costs of handles of the elements for the same type subjected to machining. The applied methodology can be used, inter alia, in the process of engineering education of technologic mechanics.
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3

Kaula, Rajeev. "A modular approach toward flexible manufacturing." Integrated Manufacturing Systems 9, no. 2 (April 1998): 77–86. http://dx.doi.org/10.1108/09576069810369218.

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4

Rudolph, K., and R. Wätzig. "Modular Software for Flexible Manufacturing Systems." IFAC Proceedings Volumes 20, no. 5 (July 1987): 167–70. http://dx.doi.org/10.1016/s1474-6670(17)55312-4.

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5

Oden, Howard W. "Modular implementation of computer integrated manufacturing." Computers & Industrial Engineering 11, no. 1-4 (January 1986): 603–7. http://dx.doi.org/10.1016/0360-8352(86)90162-2.

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6

Cao, Hong Jian, and Hui Zhang. "Modular Network in Manufacturing Industry and its Competitive Advantages." Key Engineering Materials 474-476 (April 2011): 1802–7. http://dx.doi.org/10.4028/www.scientific.net/kem.474-476.1802.

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Анотація:
There has been a modularization trend in manufacturing industry since 1990s. Modular network is a simpler and more effective way to form complex product system. The information processing in modular network includes information assimilation and information encapsulation. The competitive advantages of modular network lie in Network Externality, back-to-back competition, innovation and anti-risk abilities. The emergence of modular network leads to the change of industrial organization. Adjustments should be made to enterprises’ competition strategies.
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7

Takeuchi, Yoshimi, Naoki Asakawa, and Yoshihiro Totani. "Automatic Combination of Modular Machine Elements Forming Complex Manufacturing Cell." Journal of Robotics and Mechatronics 7, no. 3 (June 20, 1995): 230–33. http://dx.doi.org/10.20965/jrm.1995.p0230.

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Анотація:
This study addresses the combination technology between modular machine elements which forms futural complex manufacturing systems. It is thus important for modular machine elements to automatically combine themselves with each other to form complex manufacturing systems according to the needs. Therefore, the method of recognizing the position and attitude of modular machine elements and combining them is proposed. The validity of the method is experimentally confirmed.
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8

Riesener, Michael, Casimir Ortlieb, and Günther Schuh. "Analyzing Modular Platform Potential for Complex Product Portfolios of Manufacturing Companies." Advanced Materials Research 1140 (August 2016): 521–28. http://dx.doi.org/10.4028/www.scientific.net/amr.1140.521.

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Анотація:
The increasing demand for product individualization and the challenges of globalization force manufacturing companies to expand their product range while keeping internal expenses low. To tackle the dichotomy between economies of scale and economies of scope, companies make use of modular product platforms and carry-over-parts. To improve the modular platform performance, it is crucial to define its structure in the early planning phase. In vertical direction, the modular platform structure defines considered technical solutions, whereas in horizontal direction, it is characterized by the products that use these solutions. When introducing or adapting modular product platforms of complex product portfolios, companies often make upfront decisions regarding the modular platform’s structure based on expert intuition. This mainly results from a lack of time, organizational restrictions and missing systematic approaches. The sheer number of product data associated with the products in the portfolio as well as the often missing transparency regarding existing components and interfaces force decision makers to decide in an intuitive approach. However, this hinders an optimal design of modular platforms and reduces the optimal performance exploitation. In order to increase modular platform performance and hence the company´s profitability, a holistic approach prior to the actual platform design process is required to determine the optimal modular platform structure for a complex product portfolio. The basis for this methodology is a generic descriptive model, which helps to describe current and planned products of a serial manufacturer’s portfolio in a structured way. The introduced methodology determines optimal modular platform scopes through systematic identification of anchor products by aid of Data Mining.
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9

Lampón, Jesús F., Vincent Frigant, and Pablo Cabanelas. "Determinants in the adoption of new automobile modular platforms." Journal of Manufacturing Technology Management 30, no. 4 (June 3, 2019): 707–28. http://dx.doi.org/10.1108/jmtm-07-2018-0214.

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Анотація:
PurposeThe purpose of this paper is to analyse the key factors behind the adoption of new automobile modular platforms from the perspectives of product design, manufacturing network and production systems.Design/methodology/approachAn in-depth and qualitative cross-case analysis of European manufacturing networks was performed based on the modular platforms of seven automobile manufacturers.FindingsThe adoption of modular platforms has changed automobile product architecture helping automobile manufacturers to improve their manufacturing network outputs. The results show that operational flexibility and scope and scale economies at manufacturing network level depend on the platform design – degree of modularity – and the manufacturer’s product and manufacturing network conditions. This new product architecture allows for the new production systems to be efficient in terms of flexibility and versatility without overinvestment.Originality/valueThe main contribution to the research literature is the combination of traditional product architecture with the manufacturing network approach to analyse the influence of product design on production systems, especially regarding the adoption of new automobile modular platforms.
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10

Baade, Ralf, Friedrich Klinge, Kevin Lynaugh, Frank Woronkowicz, and Klaus-Michael Seidler. "Modular Outfitting." Journal of Ship Production 14, no. 03 (August 1, 1998): 170–79. http://dx.doi.org/10.5957/jsp.1998.14.3.170.

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Анотація:
The concept of modular construction is not new in the manufacturing, construction, automotive, aeronautical or marine industries. This concept is presented from the initial stages of design, and production, through shipbuilder's trials and operations. Through careful thought, engineering, and communications with all involved, from design, construction, and operation, a quality product with schedule reduction is ensured using modular outfitting. Each phase of modular outfitting is discussed to explain how it has affected organizational issues, design issues, financial issues, production issues and life-cycle or operational issues.
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11

Sand, J. C., P. Gu, and G. Watson. "HOME: House Of Modular Enhancement—a Tool for Modular Product Redesign." Concurrent Engineering 10, no. 2 (June 2002): 153–64. http://dx.doi.org/10.1177/1063293x02010002638.

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Анотація:
Product modularization aims to improve the overall design, manufacturing, operational, and post-retirement characteristics of products by designing or redesigning the product architectures. A successful modular product can assist the reconfiguration of products, while reducing the lead-time of design and manufacturing and improving the ability for upgrading, maintenance, customization and recycling. This paper presents a new modular design method called the House Of Modular Enhancement (HOME) for product redesign. Information from various aspects of the product design, including functional requirements, product architecture and life cycle requirements, is incorporated in the method to help ensure that a modularized product would achieve the objectives. The HOME method has been implemented in a software system. A case study will be presented to illustrate the HOME method and the software.
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12

Brunoe, Thomas Ditlev, Daniel GH Soerensen, and Kjeld Nielsen. "Modular Design Method for Reconfigurable Manufacturing Systems." Procedia CIRP 104 (2021): 1275–79. http://dx.doi.org/10.1016/j.procir.2021.11.214.

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13

Marinin, Kenneth J., and Tim R. V. Davis. "Modular assembly strategy in international automotive manufacturing." International Journal of Automotive Technology and Management 2, no. 3/4 (2002): 353. http://dx.doi.org/10.1504/ijatm.2002.002094.

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14

Martínez, Fernando Marín, and Luis Miguel Arreche Bedia. "Modular simulation tool for modelling JIT manufacturing." International Journal of Production Research 40, no. 7 (January 2002): 1529–47. http://dx.doi.org/10.1080/00207540110119081.

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15

Yazgaç, Tülin, and Rifat Gürcan Özdemir. "A cutting sequencing approach to modular manufacturing." Journal of Manufacturing Technology Management 15, no. 1 (January 2004): 20–28. http://dx.doi.org/10.1108/09576060410512211.

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16

Friedrich, Jens, Stefan Scheifele, Alexander Verl, and Armin Lechler. "Flexible and Modular Control and Manufacturing System." Procedia CIRP 33 (2015): 115–20. http://dx.doi.org/10.1016/j.procir.2015.06.022.

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17

Papadoudis, Jan, and Anthimos Georgiadis. "Distributable Modular Software Framework for Manufacturing Systems." Procedia CIRP 41 (2016): 712–16. http://dx.doi.org/10.1016/j.procir.2015.12.079.

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18

Carpanzano, Emanuele, Claudio R. Boer, Andrea Cataldo, and Paolo Pedrazzoli. "Modular Development of Agile Manufacturing Control Systems." IFAC Proceedings Volumes 37, no. 4 (April 2004): 407–12. http://dx.doi.org/10.1016/s1474-6670(17)36148-7.

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19

Baldea, Michael, Thomas F. Edgar, Bill L. Stanley, and Anton A. Kiss. "Modular manufacturing processes: Status, challenges, and opportunities." AIChE Journal 63, no. 10 (August 5, 2017): 4262–72. http://dx.doi.org/10.1002/aic.15872.

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20

Shaik, Abdul Munaf, V. V. S. Kesava Rao, and Ch Srinivasa Rao. "Development of modular manufacturing systems—a review." International Journal of Advanced Manufacturing Technology 76, no. 5-8 (September 6, 2014): 789–802. http://dx.doi.org/10.1007/s00170-014-6289-2.

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21

Moyano Sanz, Sandra, and Mercedes Valiente López. "Printed thermoplastic modular piece, P.T.M.P. = Piezas termoplásticas modulares, P.T.M.P." Building & Management 2, no. 1 (April 30, 2018): 12. http://dx.doi.org/10.20868/bma.2018.1.3707.

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Анотація:
This research tries to design a modular part suitable for construction, with new materials and manufacturing processes. Polymers and 3D printing are the key elements in the process. It is about implanting a new model of modular part that is able to replace the conventional brick. With this research, we want to make known the new construction processes derived from 3D printing and how we can improve the existing technology. The main objective is to design a modular part, using additive manufacturing systems and plastic materials. Then we are going to determine the physical characteristics that the pieces must have, and the geometric possibilities that the manufacturing process allows us, as well as the materials that the pieces will be made. These pieces will be subject to all the actual tests to ceramic pieces, according to the current standard. Additionally, we will analyze the results obtained and compare them with an expensive ceramic brick to assess the advantages obtained. Finally, we will determine some conclusions derived from these investigations, and propose new study proposals. With this research, we intend to demonstrate that, although conventional brick are basic elements of construction and fulfils its functions perfectly, it is time to adapt the new technologies to the constructive methods.ResumenEste estudio trata de diseñar una pieza modular apropiada para la construcción mediante nuevos procesos de producción y nuevos materiales. Los polímeros y la impresión 3D son los elementos clave del proceso. Además, se estudia implantar un nuevo modelo de pieza modular que sea capaz de sustituir al ladrillo convencional. Con esta investigación queremos divulgar los nuevos procesos asociados a la impresión 3D y como podemos mejorar la tecnología existente. El objetivo principal es diseñar una pieza modular, usando sistemas de fabricación aditiva y materiales plásticos. Posteriormente vamos a determinar las características físicas que deben tener las piezas y las posibilidades en cuanto a la geometría que el proceso de producción nos permite, además de los materiales que compondrán las piezas. Estas piezas serán sujeto de todos los test estándar aplicables a las piezas cerámicas. Adicionalmente, analizaremos los resultados obtenidos y los compararemos con piezas de ladrillo de alta calidad para asegurarnos de las posibles ventajas obtenidas. Finalmente, haremos algunas conclusiones derivadas del estudio, y se harán propuestas para nuevas vías de estudio. Con la investigación tenemos la intención de demostrar que aunque los ladrillos convencionales son elementos constructivos básicos, que cumplen su función perfectamente, es momento de adaptar las nuevas tecnologías a los métodos constructivos.
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22

Rudy, Vladimír, and Andrea Lešková. "Concept to Support the Flexibility of Manufacturing System through Reconfigurable Structure Based on Modular Design." Applied Mechanics and Materials 816 (November 2015): 536–46. http://dx.doi.org/10.4028/www.scientific.net/amm.816.536.

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Анотація:
This article deals about the challenges of structural changes in manufacturing conditions. The objective of this paper is to present the modular workstations concept based on miniaturization and re-configurability trends. The article is aimed at problems of designing of production systems with a modular construction structure. The modular structure allows an individual and flexible adaptation to varying requirements but also the realization of low-cost solutions for creation of new or modernized production base. The goal is to present the example of modular workstations solutions that correspond with new designing approach. The specification of basics principles, which should help to designing flexible manufacturing systems, discussed in this paper are: modularity; integrability; convertibility; diagnosability; customization. The theoretical part provides an overview of fundamental design principles in manufacturing structures. In the first part of this article are discussed the specification of basic flexibility types in production system and the main impacts influencing design of manufacturing structures. The closing section of the article provides the specification of example solution of adjustable production platform with modular frame (called desktop factory).
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23

Singh, Ashutosh, Mohammad Asjad, Piyush Gupta, and Jahangir Quamar. "An Approach to Develop Shaper Cum Slotter Mechanism: A Reconfigurable Machine Tool." South Asian Journal of Business and Management Cases 8, no. 2 (April 8, 2019): 195–206. http://dx.doi.org/10.1177/2277977919833765.

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Анотація:
The traditional structure of machines (such as lathe, milling, shaper, slotter, drilling and planer) has become questionable because of the modular concepts (such as modularity, scalability, convertibility, mobility and flexibility) and reconfiguration becomes a promising approach towards modular manufacturing machines, in which manufacturing techniques are independent of changes. In this area, reconfigurable machine tool (RMT) forms a new class of modular machines in current manufacturing scenario where the manufacturing industry put a strong pressure on good quality and price reduction. The capabilities of the machines tool and manufacturing systems in reconfigurable manufacturing system (RMS) change with each reconfiguration (both software and hardware modules). In this case, an approach is presented for reconfiguration of horizontal shaper machine for developing the modular shaper cum slotter machine in a manufacturing system by adding some auxiliary (like Scott Russel mechanism) and some basic modules and the reconfiguration features of traditional shaper and slotter machine are also discussed. The proposed approach is illustrated with a figure, which has been designed on 3-D design tool (solid-works software platform). It is expected that, this work will help designers and practising engineers by making them aware of the reconfiguration mechanisms on traditional shaper machine, which have become a necessity for the very survival of manufacturing by lowering the operational costs.
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24

Svetlík, Jozef, and Peter Demeč. "Principles of Modular Architecture in the Manufacturing Technology." Applied Mechanics and Materials 309 (February 2013): 105–12. http://dx.doi.org/10.4028/www.scientific.net/amm.309.105.

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Анотація:
The article deals with the issue of modularity as a tool for flexible and efficient production systems. When having closer look at implemented terms in production structures there emerges amount of terms used, such as: flexible, modular, modular manufacturing systems, which are often viewed from a subjective point of view. Due to efforts to standardize and clarify the terms referred above this paper brings definitions of flexible production structures terminology, their relationships and new idea for the efficient division.
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25

Lohse, Oliver, and Peter Robl. "Digitalisierung modular umsetzen." Konstruktion 73, no. 01-02 (2021): 44–46. http://dx.doi.org/10.37544/0720-5953-2021-01-02-44.

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Анотація:
Der Aufwand für den Aufbau eines monolitischen Manufacturing Operations Management (MOM) ist sehr hoch. Deswegen und aufgrund der Aquise der Low-Code-Plattform Mendix hat Siemens untersucht, ob sich eine MOM-Lösung auf Basis von App-Bausteinen entwickeln lässt. Gleichzeitig wurde untersucht, wie sich eine solche Lösung von einer herkömmlichen Entwicklung unterscheidet und wie sie eingesetzt werden muss, damit sie Mehrwert erzeugt. Es zeigt sich, dass deren Modularität eine schrittweise Digitalisierung in kleinen und mittelständischen Unternehmenseinheiten ermöglicht.
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26

Shin, Jiwong, and Byungjoo Choi. "Design and Implementation of Quality Information Management System for Modular Construction Factory." Buildings 12, no. 5 (May 13, 2022): 654. http://dx.doi.org/10.3390/buildings12050654.

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Анотація:
Modular construction has been gaining increasing attention from industry and academia as a solution to the limitations of the traditional on-site orient production systems in the construction industry. Various attempts have been made to improve modular construction performance. However, while previous studies have attempted to enhance the productivity of modular construction, attempts to improve the efficiency of quality management in modular construction have been limited. Moreover, the quality management practices in a modular factory still rely on document-oriented quality information management, which is inefficient. Therefore, this study aims to develop a quality information management system to improve quality information management during module manufacturing. Accordingly, quality information during module manufacturing has been standardized using integration definition for process modeling, and system functions are defined using standardized quality information. The developed modular factory quality information management system includes module information and production-type management, material management, and module production management. The practicability and validity of the developed system were examined by accredited tests and certification laboratory and modular construction experts. The developed system is expected to contribute to improving the existing inefficient quality management process of module manufacturers by providing an integrated and systematic method to manage quality information generated during manufacturing.
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27

Cao, Dong Mei, Dong Bo Li, and Fei Yu. "Research of Modular Experimental Production System." Advanced Materials Research 591-593 (November 2012): 2531–35. http://dx.doi.org/10.4028/www.scientific.net/amr.591-593.2531.

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Анотація:
On the basis of former researcher domestically and abroad about flexible production system technologies, the experiment platform for modular flexible manufacturing system (KNT-FMS) is designed and implemented according to customers’ requirements. After analysis of system requirements, the architecture of modular flexible manufacturing system (KNT-FMS) is constructed. Then the design and implementation of production status recognition and monitoring are focused on. Finally, the application of monitoring system is illustrated by an example of 11-stop experimental flexible manufacturing system. The experiment platform can train professional skills for the students and engineers before working through simulating the work conditions of factual production system so as to shorten the gaps between theory and practice and improve the comprehensive skills all around. Also it provides practical training equipments for training applicable skilled talent and is of application value.
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28

Hwang, Hyun-Jun, and Chan-woo Jung. "Improvement of Manufacturing Drawings for Manufacturing Quality Assurance of Modular Housing Unit." Journal of the Korean Housing Association 27, no. 6 (December 25, 2016): 137–44. http://dx.doi.org/10.6107/jkha.2016.27.6.137.

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29

Torayev, Agajan, Giovanna Martínez-Arellano, Jack C. Chaplin, David Sanderson, and Svetan Ratchev. "Towards Modular and Plug-and-Produce Manufacturing Apps." Procedia CIRP 107 (2022): 1257–62. http://dx.doi.org/10.1016/j.procir.2022.05.141.

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30

Garbacz, Kamil, Lars Stagun, Sigrid Rotzler, Markus Semenec, and Malte von Krshiwoblozki. "Modular E-Textile Toolkit for Prototyping and Manufacturing." Proceedings 68, no. 1 (January 6, 2021): 5. http://dx.doi.org/10.3390/proceedings2021068005.

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Анотація:
We present a novel E-textiles toolkit that can be used in the rapid prototyping of electronic textiles during the research and evaluation phase. The modular, Arduino-compatible toolkit incorporates various sensors and control and communication modules. The needs of fashion professionals have been considered during the conception of the toolkit, which was developed in close cooperation with partners from textile research institutes, the textile industry, art schools and design. After the initial manual prototyping, the toolkit modules can be directly transferred to reliable industrial integration using advanced machinery. To achieve this, we developed the E-textile Bonder, a machine capable of mechanically and electrically connecting modules to textiles with integrated conductors. This paper gives an overview of the toolkit as well as the design considerations discussed and implemented during the cooperation with textile industry stakeholders. Furthermore, the integration process with the E-Textile Bonder is described, and its advantages over other technologies are discussed.
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31

Rząsiński, Rafał. "Application supporting the process of manufacturing modular construction." International Journal of Materials and Product Technology 56, no. 1/2 (2018): 95. http://dx.doi.org/10.1504/ijmpt.2018.089120.

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32

Rząsiński, Rafał. "Application supporting the process of manufacturing modular construction." International Journal of Materials and Product Technology 56, no. 1/2 (2018): 95. http://dx.doi.org/10.1504/ijmpt.2018.10010002.

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33

Badurdeen, Fazleena, and Dale Masel. "A modular minicell configuration for mass customisation manufacturing." International Journal of Mass Customisation 2, no. 1/2 (2007): 39. http://dx.doi.org/10.1504/ijmassc.2007.012812.

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34

Wright, C. D., and K. Case. "Emulation of modular manufacturing machines using CAD modelling." Mechatronics 4, no. 7 (October 1994): 713–35. http://dx.doi.org/10.1016/0957-4158(94)90033-7.

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35

Carrere, Carol G., and Trevor J. Little. "A CASE STUDY AND DEFINITION OF MODULAR MANUFACTURING." International Journal of Clothing Science and Technology 1, no. 1 (January 1989): 30–38. http://dx.doi.org/10.1108/eb002943.

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36

Khan, Abdul Salam Salam. "Impact of Modular Design and Interchangeable Systems on Business Profit." Asia Proceedings of Social Sciences 2, no. 1 (December 2, 2018): 5–8. http://dx.doi.org/10.31580/apss.v2i1.230.

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Анотація:
In resource constraint environment, business operates by “doing it right the first time” for timely production and effective delivery. Modular design, Interchangeable systems and “Leagile” manufacturing are essential tools for coping with variable demands. We discuss manufacturing system design & its importance for firm’s competitiveness by operationalizing competitiveness in terms of profit share and understanding mediation of interchangeability between modular design and market share. Our findings suggest that modular design provides an enterprise to explore new customer base, focus on niche market and start on a new learning curve.
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37

Wrede, S., M. Wojtynek, J. Prof Steil, O. Beyer, C. Frobieter, and V. Franke. "Modulare Fertigungslinien für die individualisierte Produktion/Modular manufacturing systems for individualized production - Improving flexibility through business process modelling." wt Werkstattstechnik online 106, no. 04 (2016): 204–10. http://dx.doi.org/10.37544/1436-4980-2016-04-14.

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Анотація:
Der Beitrag beschreibt ein Hard- und Softwarekonzept für vernetzte Fertigungsmodule. Eine modulare Systemarchitektur sowie die dezentrale Steuerung durch Prozessmodelle auf Basis von BPMN2 erlauben eine kundenspezifische Produktion bis hin zu Losgröße eins. Anhand eines vertikal in die Unternehmens-IT integrierten Demonstrators wurden die Vorteile als Showcase für Industrie 4.0 auf verschiedenen Fachmessen erlebbar. Der innovative Ansatz wurde im Verbundprojekt itsowl-FlexiMon im Rahmen des BMBF Spitzenclusters „Intelligente Technische Systeme OstWestfalenLippe“ (it’s OWL) entwickelt.   This contribution describes a distributed modular production system for individualized production. A modular system architecture and semi-autonomous cell control based on executable process models with BPMN2 are used to realize a customer specific production down to lot size one. The advantages have become tangible through a vertically integrated demonstrator that has been exhibited at different fares and showcases the progress towards Industry 4.0. The overall approach was developed in the project itsowl-FlexiMon in the framework of the BMBF leading edge cluster „Intelligent Technical Systems OWL“ (it’s OWL).
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38

Pashaei, Sebastian, and Jan Olhager. "The impact of global operations on product architecture: an exploratory study." International Journal of Operations & Production Management 37, no. 10 (October 2, 2017): 1304–26. http://dx.doi.org/10.1108/ijopm-06-2015-0367.

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Purpose The purpose of this paper is to explore how global operations of manufacturing companies influence the choice of product architecture decisions, ranging from integral to modular product designs. Design/methodology/approach The authors perform a multiple-case study of three global manufacturing companies with integral and modular product architectures. Findings The authors find that the internal network capabilities, the number of capable plants, the focus of component plants, the focus of assembly plants, the distances from key suppliers to internal plants, and the number of market segments significantly influence the choice of integral vs modular architecture. Research limitations/implications This study is limited to three large manufacturing companies with global operations. However, the authors investigate both integral and modular products. The authors develop propositions that can be tested in further survey research. Practical implications The findings show that the type of global operations network influences the decision on product architecture, such that certain global operations characteristics support integral product designs, while other characteristics support modular designs. Originality/value To the best of the authors’ knowledge this paper is the first study on the explicit impact of global operations on product architecture, rather than the other way around.
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39

Habib, Tufail, Muhammad Omair, Muhammad Salman Habib, Muhammad Zeeshan Zahir, Sikandar Bilal Khattak, Se-Jin Yook, Muhammad Aamir, and Rehman Akhtar. "Modular Product Architecture for Sustainable Flexible Manufacturing in Industry 4.0: The Case of 3D Printer and Electric Toothbrush." Sustainability 15, no. 2 (January 4, 2023): 910. http://dx.doi.org/10.3390/su15020910.

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Integrating sustainability, a flexible manufacturing system, and Industry 4.0 resolves the issues of fluctuating market demand arising from customization requirements. Modular products allow flexibility to adapt to changing requirements and optimize resource utilization. In this study, a method was proposed and applied to two products, i.e., a 3D printer and an electric toothbrush featuring modular architecture, multiple product versions, and customization, to contribute to the development of sustainable flexible manufacturing systems. From the results of the two case studies nine modules were identified that contain specific functions and related interface information. From these modules, one platform was developed that comprises common entities used in all variants of the products. This platform was further extended to product families. From the modules, product architecture was developed that supports the product and process relationships. These relationships can be developed concurrently, enabling product features to be linked to the manufacturing setup. Thus, when a modular architecture is developed, the factory has to be reorganized accordingly, or reconfiguration is possible. Hence, the main aim of the research was to develop modular product architecture to identify product and process relationships for a sustainable flexible manufacturing system.
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40

Su, Meng, Bauer Yang, and Xiaomin Wang. "Research on Integrated Design of Modular Steel Structure Container Buildings Based on BIM." Advances in Civil Engineering 2022 (January 17, 2022): 1–13. http://dx.doi.org/10.1155/2022/4574676.

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Modular container buildings, as new modular steel structure buildings with the advantages of modular construction and transportation, fast construction speed, and conformance to the concept of sustainable development, have achieved rapid development in the field of civil engineering in recent years. However, in view of the incompatibility of the standards and systems between the traditional construction industry and the container manufacturing industry, contradictions between industrialization, standardization requirements and diversified demands of buildings, and the low integration of the design system of modular steel structure buildings, the further development of the modular container building industry has encountered a bottleneck. In this study, for resolving this problem, it was proposed to coordinate the modular sequence of the construction and container manufacturing, establish a modular system for modular steel structure buildings, establish a database of container building components and parts, and integrate BIM and PDM platforms, to strengthen professional coordination and improve the integrated design that can increase the integration of the whole process of design. The application and verification in pilot projects such as Huaduhui Commercial Street have approved that this design method can effectively improve the standardization, industrialization, and information levels of design, production, and construction, increase the diversity and overall quality of modular buildings, and promote the achievement of the integration target of the modular steel structure building system.
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41

Li, Meng Qi, and Dong Ying Li. "Theory and Application of Modular Manufacturing for Complex Product System." Advanced Materials Research 156-157 (October 2010): 1513–17. http://dx.doi.org/10.4028/www.scientific.net/amr.156-157.1513.

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To solve the rapidly increasing of complexity and uncertainty and inappropriate solving space of innovative with the complex product using the traditional combination manufacturing mode, this paper proposed modular manufacturing theory by separating the need of function, performance, structure, and size in the manufacturing process into the external modules and internal modules. The theory of generalize modularize decomposition, modules solving and optimize, modularize integrated are systematical represented. To reduce the complexity and uncertainty by the way of separate the business with internal model and external model. An example of installed and calibrated system of Laser device is given to illustrate the theory and methodology of modular manufacturing.
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42

Słota, Adam, Jerzy Zając, and Marimuthu Uthayakumar. "Synthesis of Petri Net based Model of a Discrete Event Manufacturing System for Nonlinear Process Plan." Management and Production Engineering Review 7, no. 2 (June 1, 2016): 62–72. http://dx.doi.org/10.1515/mper-2016-0018.

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Abstract This work presents a modelling approach for nonlinear process plan (NLPP) implementation in discrete event manufacturing system (DEMS). NLPP is used for the building of the modular structure of an Object Observable Petri Net model of DEMS. The general capabilities of DEMS are defined by resources’ operation templates and the transition incidence relation. Based on system specification and NLPP executed in the system, the modular model of DEMS is defined. The required steps for constructing a modular model through the integration of resource models are presented. The proposed approach to modular modelling is illustrated by means of a sample DEMS and an example of NLPP.
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43

Yao, Jia Ming, Cheng Hong Lu, and Yan Hui Wang. "Implementation Techniques of Modular BOM in Automobile Flexible Manufacturing." Advanced Materials Research 988 (July 2014): 739–44. http://dx.doi.org/10.4028/www.scientific.net/amr.988.739.

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The role of bill of material (BOM) was firstly introduced. Then, the techniques of how to establish modular BOM in multi-products enterprise was analyzed to realize accuracy and just-in time delivery of materials.
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44

Rong, Yiming (Kevin), and Yong Bai. "Automated Generation of Fixture Configuration Design." Journal of Manufacturing Science and Engineering 119, no. 2 (May 1, 1997): 208–19. http://dx.doi.org/10.1115/1.2831097.

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Flexible fixturing is a necessary aspect of Flexible Manufacturing Systems (FMS) and Computer-Integrated Manufacturing Systems (CIMS). Modular fixtures are most widely used in industry for job and batch production. Computer-Aided Fixture Design (CAFD) has become a research focus in implementing FMS and CIMS. Fixture configuration design is an important issue in the domain of CAFD. A review of the current research in CAFD indicates that a major problem impeding the automated generation of fixture configurations is the lack of studies on fixture structures. This paper investigates fundamental structures of dowel-pin based modular fixtures and fixturing characteristics of commonly used modular fixture elements. A Modular Fixture Element Assembly Relationship Graph (MFEARG) is designed to represent combination relationships between fixture elements. Based on MFEARG, algorithms are developed to search all suitable fixturing unit candidates and mount them into appropriate positions on a baseplate with interference checking. A prototype system for automated design of dowel-pin modular fixture configurations is presented in this paper. Fixture design examples are given at the end of the paper.
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45

Ge, Congqin, and Zhihong Yuan. "Production scheduling for the reconfigurable modular pharmaceutical manufacturing processes." Computers & Chemical Engineering 151 (August 2021): 107346. http://dx.doi.org/10.1016/j.compchemeng.2021.107346.

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46

OLOFSGÅRD, PETTER, AMOS NG, PHILIP MOORE, JUNSHENG PU, CHI BUI WONG, and LEO DE VIN. "DISTRIBUTED VIRTUAL MANUFACTURING FOR DEVELOPMENT OF MODULAR MACHINE SYSTEMS." Journal of Advanced Manufacturing Systems 01, no. 02 (December 2002): 141–58. http://dx.doi.org/10.1142/s0219686702000131.

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To support all phases of an agile modular manufacturing machine life cycle with CAE and Virtual Manufacturing tools, a number of different engineering applications (e.g. specialist software based tools) are typically used for design, simulation, analysis, programming, control and monitoring of a machine. These applications mainly exist today as small applications islands where each of them manages their own data. When a manufacturing machine is designed, simulated, programmed, analyzed, tested, or operated, the information, connected to that specific machine, used and generated by each application island is stored separately by each application. These application islands often use different storage technologies. Each one of the applications has an information structure to separate the information connected to each machine; however, they do not necessarily use the same information structure. Another issue concerning these applications is the functionality that is implemented in them to manage information; namely, processes such as store, retrieve, search, permissions, etc. The functionality for one process is the same in all applications that has the process implemented. But the implementation of the process functionality may differ, due to misinterpretation of the functionality specification and regular implementation bugs, which could lead to problem with integrity and consistency of the data. Applications that make use of newer information technologies, such as databases and software development tools can simplify the implementation of the functionality but each application still has to implement their own version of the functionality. This paper presents a research investigation focused on the development of a distributed integration platform that supports the whole life cycle of agile modular machine systems, which includes the design, simulation, programming, analysis, machine operation and re-configuration. The environment supports distributed management and storage of information in a system-wide library, information management and storage that is machine oriented, not application oriented, and information storage structured as reusable components to enable reuse of information and know-how that is produced throughout the life cycle of machines.
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47

Liu, Shenghui, Shuli Zhang, Chao Ma, Hongguo Zhang, and Xing Zhang. "Cloud manufacturing service evaluation based on modular neural network." International Journal of Internet Manufacturing and Services 5, no. 2/3 (2018): 204. http://dx.doi.org/10.1504/ijims.2018.091992.

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Liu, Shenghui, Shuli Zhang, Chao Ma, Hongguo Zhang, and Xing Zhang. "Cloud manufacturing service evaluation based on modular neural network." International Journal of Internet Manufacturing and Services 5, no. 2/3 (2018): 204. http://dx.doi.org/10.1504/ijims.2018.10013202.

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49

Dabirian, Sanam, Joonhee Lee, and Sanghyeok Han. "Noise exposure assessment of a modular construction manufacturing factory." Journal of the Acoustical Society of America 144, no. 3 (September 2018): 1756. http://dx.doi.org/10.1121/1.5067778.

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50

Krystek, Jolanta. "Computer aided design of teaching, modular flexible manufacturing system." Mechanik, no. 7 (July 2015): 562/443–562/452. http://dx.doi.org/10.17814/mechanik.2015.7.259.

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