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Forming of the dynamics of the changes in convergent production system depending on size of production party


Forming of the dynamics of the changes in convergent production system depending on size of production party

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dc.contributor.author Zwolińska, Bożena pl
dc.contributor.author Kubica, Łukasz [USOS129350] pl
dc.date.accessioned 2017-12-04T11:07:24Z
dc.date.available 2017-12-04T11:07:24Z
dc.date.issued 2017 pl
dc.identifier.issn 1895-2038 pl
dc.identifier.uri https://ruj.uj.edu.pl/xmlui/handle/item/47117
dc.language eng pl
dc.rights Udzielam licencji. Uznanie autorstwa - Użycie niekomercyjne 3.0 Polska *
dc.rights.uri http://creativecommons.org/licenses/by-nc/3.0/pl/legalcode *
dc.title Forming of the dynamics of the changes in convergent production system depending on size of production party pl
dc.title.alternative Kształtowanie dynamiki zmian konwergentnego systemu wytwórczego w zależności od wielkości parti produkcyjnej pl
dc.title.alternative Gestaltung der Dynamik der Änderungen des Konvergenten Herstellungsprozesses in Abhängigkeit von der Grösse der Herstellungspartie pl
dc.type JournalArticle pl
dc.description.physical 301-311 pl
dc.abstract.en Background: In terms of Lean Six Sigma, the whole process focuses on clients and their needs. Existence of a client generates the supply of companies. Extended customization has a negative impact for a structure of the production system. Dynamics of changes and no predictability of system’s state in time t+1 lead to increase of the operational costs. It particularly affects those companies which are producing goods using MTO (make - to - order) method in short series. The goal of this article is to establish a mathematical model defining how the structure of a production system is subject to change depending on the volume of the production batch for a production system in accordance with MTO. Furthermore pilot calculations have been presented which determine the probability value, how subsequent random variables are contained within three standard deviations (±3δ) from the determined expected value (ET) for the entire production structure. Months of analysis and research on introducing selected lean toolbox components to a polish company from the small and medium enterprises sector resulted in the models presented in the article. The production structure of the discussed actual facility is complex and is of converged nature in accordance with MTO, while the final products are manufactured in short production series with a relatively wide customization options. Materials and results: Wrought models consider theories of Klir and Maserovicz [Mesarovic 1964] and also theory of mass operation (one of the probability areas). In the article there are results from two models which are fundamental in defining problems in logistics engineering and production in scientific research. Important attribute of presented models is a fact that they consider relations between variables in a structure of consecutive processes and also consider relations between a size of production party and a real object. Presented models are not only theoretical coverage but also consider real relations between objects. Real productive object specialized in producing cooling devices destined to store hematogenous objects, plasma and cryoprecipitate has been analyzed. Those devices have very strict quality requirements (consistent with ISO 13485 and CE0434 in accordance with Directive 93/42/EEC). In the article there is a presentation of three models which indicates two different functions of production time for production party of 2 ≤ k ≤ 30 and k > 30 items. In the following model there are a few different parameters of the production system: variable parameters of processes’ times which depend on a kind of half-finished product, dependency of time needed to produce an item, size of a production party and also dependency of operational times and implemented technology. Conclusions: It is important to customize tools to individual attributes of a system whilst implementing changes in real objects. One change can be effective in one organization and not necessarily in the other. Wrought model is a first of the steps in building a scheme necessary to validate a real object in time t+1. On the next step those theories will be implemented in IT tool environment of R Studio or Witness System Simulation Modeling to conduct statistical analysis based on historical data. pl
dc.subject.en convergent production system pl
dc.subject.en model of the changes’ dynamics pl
dc.description.volume 13 pl
dc.description.number 3 pl
dc.identifier.doi 10.17270/J.LOG.2017.3.5 pl
dc.identifier.eissn 1734-459X pl
dc.title.journal LogForum pl
dc.language.container eng pl
dc.affiliation Wydział Matematyki i Informatyki pl
dc.subtype Article pl
dc.rights.original CC-BY-NC; otwarte czasopismo; ostateczna wersja wydawcy; w momencie opublikowania; 0 pl
.pointsMNiSW [2017 B]: 13

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Udzielam licencji. Uznanie autorstwa - Użycie niekomercyjne 3.0 Polska Except where otherwise noted, this item's license is described as Udzielam licencji. Uznanie autorstwa - Użycie niekomercyjne 3.0 Polska