Modeling and Analysis of Cushioning Performance for Multi-layered Corrugated Structures

The objective of this study was to develop cushion curves models and analyze the cushioning performance of multi-layered corrugated structures (MLCS) using a method based on dynamic stress-energy relationship. Methods: Cushion tests were performed for developing cushion curve models under 12 combina...

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Veröffentlicht in:	Journal of biosystems engineering 2016-09, Vol.41 (3), p.221-231
Hauptverfasser:	Park, Jong Min, Kim, Ghi Seok, Kwon, Soon Hong, Chung, Sung Won, Kwon, Soon Goo, Choi, Won Sik, Kim, Jong Soon
Format:	Artikel
Sprache:	kor
Schlagworte:	Cushion curve Cushioning packaging design Dynamic stress-energy method Multi-layered corrugated structure Shock pulse
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container_end_page	231
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container_title	Journal of biosystems engineering
container_volume	41
creator	Park, Jong Min Kim, Ghi Seok Kwon, Soon Hong Chung, Sung Won Kwon, Soon Goo Choi, Won Sik Kim, Jong Soon
description	The objective of this study was to develop cushion curves models and analyze the cushioning performance of multi-layered corrugated structures (MLCS) using a method based on dynamic stress-energy relationship. Methods: Cushion tests were performed for developing cushion curve models under 12 combinations of test conditions: three different combinations of drop height, material thickness, and static stress for each of four levels of energy densities between 15 and 60 kJ/m 3 . Results: Dynamic stress and energy density for MLCS followed an exponential relationship. Cushion curve models were developed as a function of drop height, material thickness, and static stress for different paperboards and flute types. Generally, the differences between the shock pulse (transmitted peak acceleration) and cushion curve (position and width of belly portion) for the first drop and the averaged second to fifth drop were greater than those for polymer-based cushioning materials. Accordingly, the loss of cushioning performance of MLCS was estimated to be greater than that of polymer-based cushioning materials with the increasing number of drops. The position of the belly of the cushion curve of MLCS tends to shift upward to the left with increasing drop height, and the belly portion became narrower. However, depending on material thickness, under identical conditions, the cushion curve of MLCS showed an opposite tendency. Conclusions: The results of this study can be useful for environment-friendly and optimal packaging design as shock and vibrations are the key factors in cushioning packaging design.
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Methods: Cushion tests were performed for developing cushion curve models under 12 combinations of test conditions: three different combinations of drop height, material thickness, and static stress for each of four levels of energy densities between 15 and 60 kJ/m 3 . Results: Dynamic stress and energy density for MLCS followed an exponential relationship. Cushion curve models were developed as a function of drop height, material thickness, and static stress for different paperboards and flute types. Generally, the differences between the shock pulse (transmitted peak acceleration) and cushion curve (position and width of belly portion) for the first drop and the averaged second to fifth drop were greater than those for polymer-based cushioning materials. Accordingly, the loss of cushioning performance of MLCS was estimated to be greater than that of polymer-based cushioning materials with the increasing number of drops. The position of the belly of the cushion curve of MLCS tends to shift upward to the left with increasing drop height, and the belly portion became narrower. However, depending on material thickness, under identical conditions, the cushion curve of MLCS showed an opposite tendency. Conclusions: The results of this study can be useful for environment-friendly and optimal packaging design as shock and vibrations are the key factors in cushioning packaging design.</description><identifier>ISSN: 1738-1266</identifier><identifier>EISSN: 2234-1862</identifier><language>kor</language><publisher>한국농업기계학회</publisher><subject>Cushion curve ; Cushioning packaging design ; Dynamic stress-energy method ; Multi-layered corrugated structure ; Shock pulse</subject><ispartof>Journal of biosystems engineering, 2016-09, Vol.41 (3), p.221-231</ispartof><lds50>peer_reviewed</lds50><oa>free_for_read</oa><woscitedreferencessubscribed>false</woscitedreferencessubscribed></display><links><openurl>$$Topenurl_article</openurl><openurlfulltext>$$Topenurlfull_article</openurlfulltext><thumbnail>$$Tsyndetics_thumb_exl</thumbnail><link.rule.ids>314,780,784,885</link.rule.ids></links><search><creatorcontrib>Park, Jong Min</creatorcontrib><creatorcontrib>Kim, Ghi Seok</creatorcontrib><creatorcontrib>Kwon, Soon Hong</creatorcontrib><creatorcontrib>Chung, Sung Won</creatorcontrib><creatorcontrib>Kwon, Soon Goo</creatorcontrib><creatorcontrib>Choi, Won Sik</creatorcontrib><creatorcontrib>Kim, Jong Soon</creatorcontrib><title>Modeling and Analysis of Cushioning Performance for Multi-layered Corrugated Structures</title><title>Journal of biosystems engineering</title><addtitle>Journal of biocystems Engineering</addtitle><description>The objective of this study was to develop cushion curves models and analyze the cushioning performance of multi-layered corrugated structures (MLCS) using a method based on dynamic stress-energy relationship. Methods: Cushion tests were performed for developing cushion curve models under 12 combinations of test conditions: three different combinations of drop height, material thickness, and static stress for each of four levels of energy densities between 15 and 60 kJ/m 3 . Results: Dynamic stress and energy density for MLCS followed an exponential relationship. Cushion curve models were developed as a function of drop height, material thickness, and static stress for different paperboards and flute types. Generally, the differences between the shock pulse (transmitted peak acceleration) and cushion curve (position and width of belly portion) for the first drop and the averaged second to fifth drop were greater than those for polymer-based cushioning materials. Accordingly, the loss of cushioning performance of MLCS was estimated to be greater than that of polymer-based cushioning materials with the increasing number of drops. The position of the belly of the cushion curve of MLCS tends to shift upward to the left with increasing drop height, and the belly portion became narrower. However, depending on material thickness, under identical conditions, the cushion curve of MLCS showed an opposite tendency. 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The position of the belly of the cushion curve of MLCS tends to shift upward to the left with increasing drop height, and the belly portion became narrower. However, depending on material thickness, under identical conditions, the cushion curve of MLCS showed an opposite tendency. Conclusions: The results of this study can be useful for environment-friendly and optimal packaging design as shock and vibrations are the key factors in cushioning packaging design.</abstract><pub>한국농업기계학회</pub><tpages>11</tpages><oa>free_for_read</oa></addata></record>
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source	Free E-Journal (出版社公開部分のみ）; KoreaScience (Open Access)
subjects	Cushion curve Cushioning packaging design Dynamic stress-energy method Multi-layered corrugated structure Shock pulse
title	Modeling and Analysis of Cushioning Performance for Multi-layered Corrugated Structures
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