Integrating the spare parts supply chain: an inter‐disciplinary account

PurposeDespite the widespread expectation that additive manufacturing (AM) will become a disruptive technology to transform the spare parts supply chain, very limited research has been devoted to the quantitative modeling and analysis on how AM could fulfill the on-demand spare parts supply. On the other hand, the choice of using AM as a spare parts supply strategy over traditional inventory is a rising decision faced by manufacturers and requires quantitative analysis for their AM-or-stock decisions. The purpose of this paper is to develop a quantitative performance model for a generic powder bed fusion AM system in a spare parts supply chain, thus providing insights into this less-explored area in the literature.Design/methodology/approachIn this study, analysis based on a discrete event simulation was carried out for the use of AM in replacement of traditional warehouse inventory for an on-demand spare parts supply system. Generic powder bed fusion AM system was used in the model, and the same modeling approach could be applied to other types of AM processes. Using this model, the impact of both spare parts demand characteristics (e.g. part size attributes, demand rates) and the AM operations characteristics (e.g. machine size and postpone strategy) on the performance of using AM to supply spare parts was studied.FindingsThe simulation results show that in many cases the AM operation is not as cost competitive compared to the traditional warehouse-based spare parts supply operation, and that the spare parts size characteristics could significantly affect the overall performance of the AM operations. For some scenarios of the arrival process of spare parts demand, the use of the batched AM production could potentially result in significant delay in parts delivery, which necessitates further investigations of production optimization strategies.Originality/valueThe findings demonstrate that the proposed simulation tool can not only provide insights on the performance characteristics of using AM in the spare parts supply chain, especially in comparison to the traditional warehousing system, but also can be used toward decision making for both the AM manufacturers and the spare parts service providers.

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Additive manufacturing in the spare parts supply chain: hub configuration and technology maturity

Rapid Prototyping Journal ◽

10.1108/rpj-03-2017-0052 ◽

2018 ◽

Vol 24 (7) ◽

pp. 1178-1192 ◽

Cited By ~ 13

Author(s):

Siavash H. Khajavi ◽

Jan Holmström ◽

Jouni Partanen

Keyword(s):

Supply Chain ◽

Additive Manufacturing ◽

Spare Parts ◽

Content Type ◽

Local Manufacturing ◽

Efficiency And Effectiveness ◽

Industrial Operations ◽

Production Configuration ◽

Part Production

PurposeInnovative startups have begun a trend using laser sintering (LS) technology patents expiration, namely, by introducing LS additive manufacturing (AM) machines that can overcome utilization barriers, such as the costliness of machines and productivity limitation. The recent rise of this trend has led the authors to investigate this new class of machines in novel settings, including hub configuration. There are various supply chain configurations to supply spare parts in industrial operations. This paper aims to explore the promise of a production configuration that combines the benefits of centralized production with the flexibility of local manufacturing without the huge costs related to it.Design/methodology/approachThis study quantitatively examines the feasibility of different AM-enabled spare parts supply chain configurations. Using cost data extracted from a case study, three scenarios per AM machine technology are modeled and compared.FindingsResults suggest that hub production configuration depending on the utilized AM machines can provide economic efficiency and effectiveness to reduce equipment downtime. While previous studies have suggested the need for AM machines with efficiency for single part production for a distributed supply chain, the findings in this research illustrate the positive relationship between multi-part production capability and the feasibility of a hub manufacturing configuration establishment.Originality/valueThis study explores the promise of a production configuration that combines the benefits of centralized production with the flexibility of local manufacturing without the huge costs related to it. Although the existing body of knowledge contains research on production decentralization, research on various levels of decentralization is lacking. Using a real-world case study, this study aims to compare the feasibility of different levels of decentralization for AM-enabled spare parts supply chains.

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Performance tradeoffs for spare parts supply chains with additive manufacturing capability servicing intermittent demand

Journal of Defense Analytics and Logistics ◽

10.1108/jdal-08-2020-0016 ◽

2021 ◽

Vol ahead-of-print (ahead-of-print) ◽

Author(s):

Kyle C. McDermott ◽

Ryan D. Winz ◽

Thom J. Hodgson ◽

Michael G. Kay ◽

Russell E. King ◽

...

Keyword(s):

Supply Chain ◽

Additive Manufacturing ◽

Production Capacity ◽

Spare Part ◽

Spare Parts ◽

Mixed Integer ◽

Network Configuration ◽

Intermittent Demand ◽

Content Type ◽

Demand Patterns

PurposeThe study aims to investigate the impact of additive manufacturing (AM) on the performance of a spare parts supply chain with a particular focus on underlying spare part demand patterns.Design/methodology/approachThis work evaluates various AM-enabled supply chain configurations through Monte Carlo simulation. Historical demand simulation and intermittent demand forecasting are used in conjunction with a mixed integer linear program to determine optimal network nodal inventory policies. By varying demand characteristics and AM capacity this work assesses how to best employ AM capability within the network.FindingsThis research assesses the preferred AM-enabled supply chain configuration for varying levels of intermittent demand patterns and AM production capacity. The research shows that variation in demand patterns alone directly affects the preferred network configuration. The relationship between the demand volume and relative AM production capacity affects the regions of superior network configuration performance.Research limitations/implicationsThis research makes several simplifying assumptions regarding AM technical capabilities. AM production time is assumed to be deterministic and does not consider build failure probability, build chamber capacity, part size, part complexity and post-processing requirements.Originality/valueThis research is the first study to link realistic spare part demand characterization to AM supply chain design using quantitative modeling.

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SUPPLY CHAIN MANAGEMENT INDUSTRY TANNERY IN GARUT INDONESIA

Review of Behavioral Aspect in Organizations and Society ◽

10.32770/rbaos.vol11-8 ◽

2019 ◽

Vol 1 (1) ◽

pp. 1-8

Author(s):

Yusuf Tojiri ◽

Imas Komariyah

Keyword(s):

Supply Chain ◽

Supply Chain Management ◽

Customer Value ◽

Qualitative Method ◽

Single Case ◽

Spare Parts ◽

Raw Material ◽

Chain Management ◽

Depth Interviews

This research was conducted in the Tannery Industry in Garut – Indonesia, about suplly chain management, research methods using qualitative method, with a single case study. In this case study researchers collecting data through observation, interviews and in-depth interviews with entrepreneurs, academics and expert tannery. Supply Chain Management, in this case, describe the process of delivery of the goods from the supplier, and then processed by the industry, the result posted by the distributor to the subscriber. The Supply Chain Management must provide a level of efficiency in the process of delivering customer value, so that customers can be more satisfied, or in other words from the center (supplier), Company, Chanels (distribution) and Customer (4C). Supply Chain Management will be effective in improving the competitiveness of the industry, either by the supplier of the raw material leather, leather chemicals, leather production machinery, spare parts, and also any other relevant parties if able to improve cooperation between the core industry, supporting industry, and related industry is strong, so each others corroborate (linkage), as well as the distribution of goods to the customer must be of high quality and on time.

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Proactive Event Management in the Supply Chain of Aircraft Spare Parts

Strategies and Tactics in Supply Chain Event Management ◽

10.1007/978-3-540-73766-7_5 ◽

2007 ◽

pp. 65-82 ◽

Cited By ~ 1

Author(s):

Johannes Bussmann ◽

Thomas Schmidt ◽

Andreas Bauer

Keyword(s):

Supply Chain ◽

Spare Parts ◽

Event Management

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Economic and Environmental Assessment of Spare Parts Production Using Additive Manufacturing

Industry 4.0 and Hyper-Customized Smart Manufacturing Supply Chains - Advances in Logistics, Operations, and Management Science ◽

10.4018/978-1-5225-9078-1.ch007 ◽

2019 ◽

pp. 159-181

Author(s):

Atanu Chaudhuri ◽

Dennis Massarola

Keyword(s):

Supply Chain ◽

Additive Manufacturing ◽

Dynamic Simulation ◽

Environmental Sustainability ◽

Selective Laser Sintering ◽

Spare Part ◽

Spare Parts ◽

Logistics System ◽

Supply Chain Costs ◽

System Dynamic Simulation

This chapter aims to investigate the potential economic and environmental sustainability outcomes of additive manufacturing (AM) for spare parts logistics. System dynamic simulation was conducted to analyze the sustainability of producing a spare part used in a railways subsystem using a particular additive manufacturing (AM) technology (i.e., selective laser sintering [SLS]) compared to producing it using injection molding. The results of the simulation showed that using SLS for the chosen part is superior to the conventional one in terms of total variable costs as well as for carbon footprint. Compared to the conventional supply chain, for the AM supply chain, the costs of the supplier reduces by 46%, that of the railways company reduces by 71%, while the overall supply chain costs reduce by 61.9%. The carbon emissions in the AM supply chain marginally reduces by 2.89% compared to the conventional supply chain.

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