Abstract
Current pallet design methodology frequently underestimates the load capacity of the pallet by assuming the payload is uniformly distributed and flexible. By considering the effect of payload characteristics and their interactions during pallet design, the structure of pallets can be optimized and raw material consumption reduced. The objective of this study was to develop a full description of how such payload characteristics affect load bridging on unit loads of stacked corrugated boxes on warehouse racking support. To achieve this goal, the authors expanded on a previously developed finite element model of a simplified unit load segment and conducted a study to screen for the significant factors and interactions. Subsequently, a Gaussian process (GP) regression model was developed to efficiently and accurately replicate the simulation model. Using this GP model, a quantification of the effects and interactions of all the identified significant factors was provided. With this information, packaging designers and researchers can engineer unit loads that consider the effect of the relevant design variables and their impact on pallet performance. Such a model has not been previously developed and can potentially reduce packaging materials’ costs.
Highlights
With more than 6.8 billion pallets in circulation around the world [1] and over 80% of the current shipping volume utilizing some form of corrugated fiberboard packaging [2], it is critical to optimize pallet and packaging design
The complete unit load finite element (FE) model was solved for the 64 factor level combinations
The number of columns in a unit load, the height of the payload, the friction coefficients of the payload’s contact with the pallet deck, and the contact friction between packages were all found to be significant factors influencing the bending response of pallet analogs loaded with stacked boxes
Summary
With more than 6.8 billion pallets in circulation around the world [1] and over 80% of the current shipping volume utilizing some form of corrugated fiberboard packaging [2], it is critical to optimize pallet and packaging design. This research has commonly shown that when a pallet carries a more rigid payload, the pallet’s deformation decreases. This behavior is known as the load bridging effect and entails the redistribution of the compressive forces towards the rigid supports and away from the critical pallet components that might be more susceptive to failure [14,15]. To characterize this effect, studies were conducted evaluating specific factors that could potentially influence the load bridging effect. This research has historically been conducted through physical experimentation with limited evaluation of the potential interactions between these factors
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