Relevant bibliographies by topics / Paperboard Testing

Academic literature on the topic 'Paperboard Testing'

Author: Grafiati
Published: 10 December 2022
Last updated: 29 January 2023

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Journal articles on the topic "Paperboard Testing"

1

Wang, Bao Zhong, and Li Jie Cao. "Different Thickness of Honeycomb Paperboard Vibration Frequency of Testing and Simulation." Advanced Materials Research 328-330 (September 2011): 1421–24. http://dx.doi.org/10.4028/www.scientific.net/amr.328-330.1421.

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This paper measured the vibration transmissibility of several honeycomb paperboards and the attenuation coefficient. Laboratory was used to determine the natural frequency of the thickness of 10mm, 20mm, 30mm, 40mm Honeycomb Paperboard. The test results show that the honeycomb paperboard resonance frequency decreases with increasing thickness, while the vibration transmissibility increases with increasing thickness. We have also established finite element model of honeycomb paperboard to simulate its vibration properties. The result of simulation is in good coincidence with the experimental result. In addition, some cases can use computer simulation instead of laboratory testing to obtain the natural frequencies of honeycomb paperboard.
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Hagman, Anton, and Mikael Nygårds. "Investigation of sample-size effects on in-plane tensile testing of paperboard." Nordic Pulp & Paper Research Journal 27, no. 2 (May 1, 2012): 295–304. http://dx.doi.org/10.3183/npprj-2012-27-02-p295-304.

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Abstract The impact of sample size on in-plane strain behavior in paperboard was investigated, with the aim to explore the differences between local and global properties in paperboard, and try to pinpoint the mechanisms behind such differences. The local properties are of interest in converting as well as for future 3D forming of paperboard. It is important to identify differences in behavior between local and global properties since most paperboards are evaluated against the latter. The methods used for evaluation were tensile tests in controlled environment and speckle photography. The results show that there is a difference in strain behavior that is dependent of the length to width ratio of the sample, that this behavior cannot be predicted by standard tensile tests and that it depends on the board composition. The speckle analysis revealed that the behavior is a result of the activation of strain zones in the sample. These zones are relatively constant in size and therefore contribute differently to total strain in samples of different size.
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Lv, Jun. "Honeycomb Multistage Control of Hydraulic Loading Testing Machine." Applied Mechanics and Materials 271-272 (December 2012): 606–10. http://dx.doi.org/10.4028/www.scientific.net/amm.271-272.606.

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Static and dynamic characteristics of the honeycomb paperboard with different size and structure are mechanics research priorities. Study on its mechanical characteristics of the basic way is the basic mechanical properties testing by loading testing machine. In order to get the stability of compressive strength of honeycomb paperboard, compressive strength of honeycomb paperboard models should be tested. Based on the existing equipment, new equipment has been made with new hydraulic systems and control programmes, control accuracy and method has been analyzed. Experimental testing results have shown that the device is credible, and its precision meets to the design requirements. The honeycomb paperboard testing machine not only provides a high pressure range and flexible control equipment, but provides a function of testing sample size effects.
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Tryding, Johan, Gustav Marin, Mikael Nygårds, Petri Mäkelä, and Giulio Ferrari. "Experimental and theoretical analysis of in-plane cohesive testing of paperboard." International Journal of Damage Mechanics 26, no. 6 (March 11, 2016): 895–918. http://dx.doi.org/10.1177/1056789516630776.

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In-plane cohesive failure of paperboard was characterized by short-span uniaxial tension tests. Six paperboards' qualities were experimentally investigated, from which cohesive stress–widening curves were extracted. A fracture energy was defined, expressed in the tensile strength and maximum slope of the cohesive stress–widening relation. Analytical cohesive relations were derived based on the tensile strength and maximum slope, utilizing the Morse potential for diatomic molecules. It was experimentally found that the maximum slope and fracture energy depend on the tensile strength. The ratio of the maximum slope to the elastic modulus (stable length) was shown to be independent of the tensile strength.
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Park, Jong-Min, Jae-Min Sim, and Hyun-Mo Jung. "Finite Element Simulation of the Flat Crush Behavior of Corrugated Packages." Applied Sciences 11, no. 17 (August 26, 2021): 7867. http://dx.doi.org/10.3390/app11177867.

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Corrugated paperboards are used for packaging because of their high strength-to-weight ratio, recyclability, and biodegradability. Corrugated paperboard consists of a liner and a corrugated medium and has an orthotropic sandwich structure with unique characteristics for each direction owing to its flute shape. In this study, finite element analysis (FEA) was performed on the flat crush behavior of the corrugated paperboard based on the flute type. The stress-strain (SS) curve and shape change of the flute were analyzed during the flat compression. In addition, it was compared with the FEA results through various experiments. The restraints and boundary conditions applied during FEA were used to properly describe the conditions during the experiment. Specifically, the horizontal translation motion of the top and bottom surfaces of the modeled test specimen was constrained during FEA to correspond to the effect of sandpaper attached to the upper and lower plates of the testing machine. This was done to prevent the specimen from sliding in one direction during the flat crush test. The change in the flute shape of the corrugated paperboard by flute type analyzed through experiments and FEA was very similar; although there was a difference in the absolute value between the two methods of the SS curve, the flute type exhibited a similar trend. Therefore, a qualitative comparative study on the flat crush behavior by flute type was possible with the FEA method, as in this study. Further studies on the material properties of the corrugated paperboard components and the modeling methods of the corrugated paperboard will enable the FEA-based simulation technique to be an alternative tool that can replace the flat crush test.
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Gao, De, and Jun Li. "Investigation into Energy Absorption of Corrugated Paperboard with B-Flute." Applied Mechanics and Materials 200 (October 2012): 94–97. http://dx.doi.org/10.4028/www.scientific.net/amm.200.94.

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In this paper, the characteristics of B-flute corrugated paperboard is obtained by quasi-static compression experiment on a universal testing machine. The constitutive relationship is identified. Then, according to the relation, we calculate the energy absorption curve of corrugated paperboard with B-flute. At last, a bearing example of the paperboard is given to introduce its application.
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Bi, Wu, and Douglas W. Coffin. "Racking strength of paperboard based sheathing materials." BioResources 2, no. 1 (December 18, 2006): 3–19. http://dx.doi.org/10.15376/biores.2.1.3-19.

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Small-scale racking testers were developed for use as a means to evaluate paperboard-based sheathing materials used in framed wall-construction. For the purpose of evaluating the performance of different sheathing materials, the tester provides an economic alternative to standard full-scale racking tests. In addition, results from testing provide practical insight into the racking response of framed and sheathed walls. The load-deformation responses of three commercial sheathing boards were measured, and initial racking stiffness and racking strength were proposed as parameters for characterizing the board. The racking test results showed that the initial paperboard racking stiffness correlated to elastic modulus and caliper, but the response was insensitive to paperboard orientation or test dimensions. Observations and results showed that both panel buckling and paperboard cutting at the staples affected the racking response, but the dominating factor influencing the racking response appears to be load transfer through the staples.
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Ju, Wang, Liang Jifeng, and Lv Lei. "Research on Static Compression Test of Polyurethane Foam/Honeycomb Paperboard Composite Material." Open Materials Science Journal 9, no. 1 (August 27, 2015): 64–70. http://dx.doi.org/10.2174/1874088x01509010064.

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To study the mechanical behavior and energy absorption ability of polyurethane foam/honeycomb paperboard composite material under the static compression test. The static compression tests of polyurethane foam/honeycomb paperboard composite material are conducted by electronic universal testing machine. The mechanical behavior under the condition of static compression and the factors influencing the composite materials’ static cushioning properties were analyzed. Then, a comparison was made based on the energy absorption ability between composite materials and simple materials. The yield stress, strength and other indicators of foam/honeycomb paperboard have doubled the growth after filling polyurethane. The aperture size is the main influencing factor affecting the static cushioning properties of composite material. The energy absorption amount of composite materials is about 1.85 times than the total energy of two simple materials.
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SKILLINGTON, PAULINE, J. CHRISTEL CRONJE, FRANCOIS WEWERS, and PATRICE C. HARTMANN. "Vapor-phase migration of DiBP and DBP through barrier-coated paperboard: Correlation between a permeation test method and simulated migration." April 2015 14, no. 4 (May 1, 2015): 247–56. http://dx.doi.org/10.32964/tj14.4.247.

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The aim of the study was to construct a correlation between a permeation test method that simulates the migration of organic vapors and the actual migration of chemical contaminants from barrier-coated paperboard packaging. A correlation of this nature would enable manufacturers of barrier-coated paperboard to estimate the barrier properties of paperboard on a quality control level. A direct correlation was not plausible because the migration mechanisms that apply to the permeation test method and the actual migration differ. However, an indirect correlation was established. The permeation test method gave an indication of film integrity, whereas the actual migration was found to be rather dependent on coating weight. The spiking method, testing temperature, and vapor pressure of the contaminants were found to be variables directly affecting the validity of the correlation between permeation and migration methods.
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Park, Jongmin, Minjung Park, Dong Soo Choi, Hyun Mo Jung, and Sung Wook Hwang. "Finite Element-Based Simulation for Edgewise Compression Behavior of Corrugated Paperboard for Packaging of Agricultural Products." Applied Sciences 10, no. 19 (September 25, 2020): 6716. http://dx.doi.org/10.3390/app10196716.

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Since most goods are transported and stored in a unit-load form in today’s global supply chain, there has been a growing concern regarding the compression strength of corrugated paperboard boxes for packaging of agricultural products. The best predictor of the compression strength of corrugated boxes is the edgewise compression test (ECT) value; therefore, its efficient measurement or prediction is crucial for the design of more efficient corrugated boxes for food and agricultural and industrial products. This study investigated the edgewise compression behavior (load vs. displacement plot, ECT, and failure mechanism) of corrugated paperboard based on different types of testing standards and flute types using finite element analysis (FEA) and experimental analysis. The results of this study showed that the magnitude of the ECT values produced by the FEA was different from the values produced by the experiment. The difference in the ECT can be possibly explained by layer thickness approximations, together with glue line width assumptions between fluting and the liners in the numerical models. However, the trends of the values were the same. If the material properties of corrugated paperboard components and modeling methods of the corrugated paperboard are further studied, the FE (finite element)-based simulation technique will be a useful alternative tool that can replace the edgewise compression test.
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Dissertations / Theses on the topic "Paperboard Testing"

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Weyrauch, Thomas. "The Paperboard Testing-Machine : Development Process." Thesis, KTH, Hållfasthetslära (Inst.), 2011. http://urn.kb.se/resolve?urn=urn:nbn:se:kth:diva-92639.

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The design of a paperboard testing machine, developed in order to analyse the mechanical behaviour of paperboard during the combined of out-of-plane shear and compressive loading as in the deepdrawing process, is presented. The methodology to design a paperboard testing machine is discussed and the most appropriate concepts are compared and evaluated. The design process is presented in detail, and some pilot tests are performed to give an overview about the functionality of the manufactured prototype.
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Sjöstrand, Björn. "Evaluation of Compression Testing and Compression Failure Modes of Paperboard : Video analysis of paperboard during short-span compression and the suitability of short- and long-span compression testing of paperboard." Thesis, Karlstads universitet, Institutionen för ingenjörs- och kemivetenskaper (from 2013), 2013. http://urn.kb.se/resolve?urn=urn:nbn:se:kau:diva-27519.

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The objectives of the thesis were to find the mechanisms that govern compression failures in paperboard and to find the link between manufacturing process and paperboard properties. The thesis also investigates two different test methods and evaluates how suitable they are for paperboard grades. The materials are several commercial board grades and a set of hand-formed dynamic sheets that are made to mimic the construction of commercial paperboard. The method consists of mounting a stereomicroscope on a short-span compression tester and recording the compression failure on video, long-span compression testing and standard properties testing. The observed failure modes of paperboard under compression were classified into four categories depending on the appearance of the failures. Initiation of failure takes place where the structure is weakest and fiber buckling happens after the initiation, which consists of breaking of fiber-fiber bonds or fiber wall delamination. The compression strength is correlated to density and operations and raw materials that increase the density also increases the compression strength. Short-span compression and Long-span compression are not suitable for testing all kinds of papers; the clamps in short-span give bulky specimens an initial geometrical shape that can affect the given value of compression strength. Long-span compression is only suitable for a limited range of papers, one problem with too thin papers are low wavelength buckling.
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Haidar, Mohamed. "Modelling of failure mechanisms for corrugated board." Thesis, KTH, Hållfasthetslära (Inst.), 2015. http://urn.kb.se/resolve?urn=urn:nbn:se:kth:diva-176010.

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The present work describes the construction of a semi-analytical model for prediction of buckling loads in simply supported corrugated paperboard panels. The model accounts for transverse shear, due to the weakness of the core in such plates compared to the facings. This was done utilizing energy relations and rst order transverse shear. The panel was homogenised using laminate theory. A detailed model using FEM was derived in order to validate the predictive capabilities of the analytical model. Experimental testing was performed to estimate the accuracy of both theoretical models, and assess the limitation of the analytical model. All modes of analysis showed good agreement for cubic boxes. Further investigation into expanding the scope of the analytical model was carried out and commented on.
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Eagleton, Danny Geoffrey. "Creep properties of corrugated fibreboard containers for produce in simulated road transport environment." Thesis, 1995. https://vuir.vu.edu.au/18159/.

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Standard methods for the performance testing of corrugated fibreboard boxes use some static or quasi-static characteristic of the box as the performance indicator. The aim of this project was to develop a performance-based test method for corrugated boxes for fresh horticultural produce, using a dynamic fatigue-type approach. It was hypothesised that a dynamic test is more appropriate for produce packaging due to the relatively dynamic nature of the produce distribution environment. Measurements were made of vibration, shock, temperature, relative humidity, and handling impacts in a typical produce distribution environment, and a dynamic performance test method was developed. It was concluded that this dynamic test method is more sensitive to performance differences between boxes than standard quasi-static methods. The dynamic tests, however, take considerably more time to conduct than standard quasi-static methods and are not suitable for automation. This dynamic test method may have uses in developing a database for the comparison of different box types, however for routine performance testing the quasistatic methods are more appropriate.
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Books on the topic "Paperboard Testing"

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E, Mark Richard, ed. Handbook of physical testing of paper. 2nd ed. New York: Marcel Dekker, 2001.

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2

Wright, P. G. Corrugated fibreboard boxes: Their design, use, quality control, and testing. 4th ed. Camberwell, Vic: Amcor Fibre Packaging, 1992.

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Mark, Richard E., Charles Habeger, Jens Borch, and M. Bruce Lyne. Handbook of Physical Testing of Paper. Taylor & Francis Group, 2001.

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(Editor), Richard E. Mark, Charles Habeger (Editor), Jens Borch (Editor), and M. Bruce Lyne (Editor), eds. Handbook of Physical Testing of Paper Volume 1. 2nd ed. CRC, 2001.

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Mark, Richard E., Charles Habeger, Jens Borch, and M. Bruce Lyne. Handbook of Physical Testing of Paper: Volume 2. Taylor & Francis Group, 2001.

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Mark, Richard E., Charles Habeger, Jens Borch, and M. Bruce Lyne. Handbook of Physical Testing of Paper: Volume 2. Taylor & Francis Group, 2001.

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Mark, Richard E., Charles Habeger, Jens Borch, and M. Bruce Lyne. Handbook of Physical Testing of Paper: Volume 2. Taylor & Francis Group, 2001.

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(Editor), Jens Borch, M. Bruce Lyne (Editor), Richard E. Mark (Editor), and Charles Habeger (Editor), eds. Handbook of Physical Testing of Paper Volume 2. 2nd ed. CRC, 2001.

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Mark, Richard E., Charles Habeger, Jens Borch, and M. Bruce Lyne. Handbook of Physical Testing of Paper: Volume 2. Taylor & Francis Group, 2001.

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Mark, Richard E., Charles Habeger, Jens Borch, and M. Bruce Lyne. Handbook of Physical Testing of Paper: Volume 1, Second Edition,. Taylor & Francis Group, 2001.

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Book chapters on the topic "Paperboard Testing"

1

"BENDING STIFFNESS, WITH SPECIAL REFERENCE TO PAPERBOARD." In Handbook of Physical Testing of Paper, 253–76. CRC Press, 2001. http://dx.doi.org/10.1201/9781482290103-12.

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Conference papers on the topic "Paperboard Testing"

1

Guofang, Luo, Zhou Yunqi, Cheng Li, Yang Lijun, and Zhou Guliang. "Traceability testing of oil-impregnated insulating paperboard." In 2022 IEEE International Conference on High Voltage Engineering and Applications (ICHVE). IEEE, 2022. http://dx.doi.org/10.1109/ichve53725.2022.9961588.

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Suda, Mitsunori, Jiahui Yang, Takanori Kitamura, Kanta Ito, Kenji Wada, Zhiyuan Zhang, Yuqiu Yang, and Hiroyuki Hamada. "Lateral Compressive Properties of Paper Tube." In ASME 2014 International Mechanical Engineering Congress and Exposition. American Society of Mechanical Engineers, 2014. http://dx.doi.org/10.1115/imece2014-37923.

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Recycled paper is helpful to reduce trash discharge, save resource and cost. Tube is one of the most common structures of recycled paper in application. It is an excellent choice for packing. It’s also used in the construction of temporary structures for both exhibition spaces or for rapid-recovery shelters in emergency operations. As paper tubes are laminated by paperboards which are inherent anisotropy materials, the researches on mechanical property and fracture behavior became complicated. In the current study, paperboards used for paper tubes were tested on universal testing machine to investigate their basis mechanical properties. Then, paper tubes fabricated with different kinds of paperboard and number of ply were used to investigate lateral compressive properties by Instron universal testing machine. And, a camera was employed to record the fracture process of paper tube during compression process. The fracture mechanism of paper tubes were discussed and analyzed during compressed process based on the load-displacement curves and detailed observation. Additionally, ls-dyna software was used to conduct numerical simulation and analyze stress distribution of paper tube during lateral compression.
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Tóth, Barnabás, László Koltai, and Péter Böröcz. "QUALITY PERFORMANCE TESTING FOR BASE PAPER OF CORRUGATED PAPERBOARD BY DSC METHOD." In 9th International Symposium on Graphic Engineering and Design. Faculty of Technical Sciences, 2018. http://dx.doi.org/10.24867/grid-2018-p16.

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