SUSTAINABLE INVENTORY MODEL FOR OPTIMIZING GREENHOUSE INVENTORY MANAGEMENT THROUGH SUSTAINABLE PRACTICES

Archit Jain; Lakhan Singh

doi:10.29121/ijetmr.v13.i2.2026.1743

Authors

Archit Jain Scholar, Institute, Digamber Jain College, Baraut, UttarPradesh, India https://orcid.org/0000-0002-0612-5731
Lakhan Singh Professor & Supervisor, Institute, Digamber Jain College, Baraut, UttarPradesh, India https://orcid.org/0009-0001-0294-7535

DOI:

https://doi.org/10.29121/ijetmr.v13.i2.2026.1743

Keywords:

Sustainability, Inventory, GreenTechnology, Preservation, Deterioration, Inflation, CarbonEmission, Optimization

Abstract

The major source of the variance in the environmental system is the dramatic increase in carbon emission (CO2). Deterioration on the massive scale is compelled in the green house companies due to the fact that green product is life cycle very limited (summer). The modern companies (green companies especially) are striving to simplify their current inventories processes so as to carry out the maximum profitability in terms of the environmental issues. To gain the economic and ecological benefits, they must make a sustainable system of inventory. The second similarity to the modern inventory system is the inflation factor that has steadily risen throughout the years during the pandemic of COVID-19 to most of the items. Due to the topicality of these concerns, the contemporary study focuses on the notion of green technology investment to prevent not only the carbon release produced by the use of the transport system but also the application of preservation technology to control the disintegrating character of the latter under the impact of inflation. The existing model was considered to be an economic order quantity model having a scheme of advance payment, the variable holding cost, and the demand rate based on the size of the amount on hand. A number of sub cases have been performed through the use of numerical examples to test the validity of the proposed model. The sensitivity analysis depicts the observation of the positive effects of controllable deterioration and emission of carbon. The results revealed that the system cost cuts by 5.96 percent as a result of putting funds in the green technology and preservation technology.

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