An SKU decomposition algorithm for the tactical planning in the FMCG industry

Elzakker, M. A. H. van; Zondervan, Edwin; Raikar, N. B.; Hoogland, Hans; Grossmann, Ignacio E.

doi:10.1016/j.compchemeng.2013.11.008

Cited by 17 publications

(5 citation statements)

References 22 publications

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“…The model was demonstrated on an ice cream scheduling problem. In a very recent work, van Elzakker et al 29 proposed an MILP model to address optimization of the tactical planning for the FMCG industry. To solve these extremely large problems, they proposed an algorithm based on SKU decomposition.…”

Section: Industrial and Engineering Chemistry Researchmentioning

confidence: 99%

Multistage Production Planning in the Dairy Industry: A Mixed-Integer Programming Approach

Bilgen

Doğan

2015

Ind. Eng. Chem. Res.

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This paper addresses a production planning problem in a multistage production system consisting of continuous processing resources separated by finite-capacity storage tanks, stimulated by a particular case study in the dairy industry. The problem is formulated as a mixed-integer linear programming (MILP) model that incorporates several distinguishing characteristics of dairy production, such as multistage bulk production, shelf-life requirements, intermediate storage, setups, resource speeds, limitations on minimum and maximum lot sizes, and the conservation of flow among various tanks. The objective is to maximize the total profit while determining the quantity of intermediate products and SKUs processed on various resources, the assignment of products to various resources and intermediate storage tanks, the quantity of each SKU sold, lost sales of each SKU, and waiting times. The determinations often reveal production bottlenecks. The efficiency of the proposed model is illustrated through its application to the milk production plant of a leading dairy company. Special features of the proposed model are highlighted through several examples. The computational performance of the MILP model is examined in several test scenarios.

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Section: Industrial and Engineering Chemistry Researchmentioning

confidence: 99%

Multistage Production Planning in the Dairy Industry: A Mixed-Integer Programming Approach

Bilgen

Doğan

2015

Ind. Eng. Chem. Res.

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“…If the logistics of the distributed feed supply and products delivery to customers are tightly coupled to the manufacturing, then production planning and scheduling become intertwined with the process operations, while seasonal dynamics also play an important role. Such (desirable) integration presents a formidable optimization challenge, as shown by Van Elzakker et al for FMCG.…”

Section: Role Of Process Systems Engineeringmentioning

confidence: 99%

A systems engineering perspective on process integration in industrial biotechnology

Kiss

Grievink

Rito‐Palomares

2014

J of Chemical Tech & Biotech

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Biotechnology has many applications in health care, agriculture, industry and the environment. By using renewable raw materials, biotechnology contributes to lowering greenhouse gas emissions and moving away from a petro-based towards a circular sustainable economy. However, major developments are still needed to make industrial biotechnology an economic alternative to conventional processes for fuels, specialty and/or bulk chemicals production.Process integration is a holistic approach to process design, which emphasizes the unity of the process and considers the interactions between different unit operations from the outset, rather than optimizing them separately. Furthermore, it also involves the substitution of two or more unit operations by one single novel unit capable of achieving the same process goal.Conversely, process systems engineering (PSE) deals with the analysis, design, optimization, operation and control of complex process systems, as well as the development of model-based methods and tools that allow the systematic development of processes and products across a wide range of systems involving physical and chemical change. Mature tools and applications are available for chemical technology and steps have been taken to apply PSE principles also to bioprocess technology. This perspective paper argues that an interdisciplinary approach is needed towards integrated bio-processing in order to link basic developments in biosciences with possible industrial applications. PSE can foster the application of existing and the development of new methods and tools for bioprocess integration that could promote the sustainable production of bio-/chemical products. The inclusion of PSE principles and methods in biochemical engineering curricula and research is essential to achieve such goals.

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“…Calfa et al (2013) combined temporal Lagrangean decomposition with bilevel decomposition for the integration of planning and scheduling. The opportunity of decomposing the problem by subproblems is also identified by van Elzakker et al (2014). However, they propose a heuristic procedure, while we generalize these ideas using Lagrangean decomposition.…”

Section: Introductionmentioning

confidence: 96%

Product decomposition strategy for optimization of supply chain planning

Brunaud¹,

Ochoa²,

Grossmann³

2018

Front. Eng

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Optimization of large-scale supply chain planning models requires the application of decomposition strategies to reduce the computational expense. Two major options are to use either spatial or temporal Lagrangean decomposition. In this paper, to further reduce the computational expense a novel decomposition scheme by products is presented. The decomposition is based on a reformulation of knapsack constraints in the problem. The new approach allows for simultaneous decomposition by products and by time periods, enabling the generation of a large number of subproblems, that can be solved by using parallel computing. The case study shows that the proposed product decomposition exhibits similar performance as the temporal decomposition, and that selecting different orders of products and aggregating the linking constraints can improve the efficiency of the algorithm.

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An SKU decomposition algorithm for the tactical planning in the FMCG industry

Cited by 17 publications

References 22 publications

Multistage Production Planning in the Dairy Industry: A Mixed-Integer Programming Approach

Multistage Production Planning in the Dairy Industry: A Mixed-Integer Programming Approach

A systems engineering perspective on process integration in industrial biotechnology

Product decomposition strategy for optimization of supply chain planning

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