Bio-Inspired Design of Next Generation Honeycomb Sandwich Panel Cores

Bio-Inspired Design of Next Generation Honeycomb Sandwich Panel Cores

abstract: Honeycomb sandwich panels have been used in structural applications for several decades in various industries. While these panels are lightweight and rigid, their design has not evolved much due to constraints imposed by available manufacturing processes and remain primarily two-dimensiona...

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Bibliographic Details
Other Authors: Goss, Derek Lee (Author)
Format: Dissertation
Language:English
Published: 2020
Subjects:
Design
Biology
Additive Manufacturing
Bio-Inspired
Honeycomb
Sandwich Panel
Online Access:http://hdl.handle.net/2286/R.I.57296
id ndltd-asu.edu-item-57296
record_format oai_dc
spelling ndltd-asu.edu-item-572962020-06-02T03:01:24Z Bio-Inspired Design of Next Generation Honeycomb Sandwich Panel Cores abstract: Honeycomb sandwich panels have been used in structural applications for several decades in various industries. While these panels are lightweight and rigid, their design has not evolved much due to constraints imposed by available manufacturing processes and remain primarily two-dimensional extrusions sandwiched between facings. With the growth in Additive Manufacturing, more complex geometries can now be produced, and advanced design techniques can be implemented into end use parts to obtain further reductions in weight, as well as enable greater multi-functionality. The question therefore is: how best to revisit the design of these honeycomb panels to obtain these benefits? In this work, a Bio-Inspired Design approach was taken to answer this question, primarily since the hexagonal lattice is so commonly found in wasp and bee nests, including the well-known bee’s honeycomb that inspired these panel designs to begin with. Whereas prior honeycomb panel design has primarily focused on the hexagonal shape of the unit cell, in this work we examine the relationship between the various parameters constituting the hexagonal cell itself, specifically the wall thickness and the corner radius, and also examine out-of-plane features that have not been previously translated into panel design. This work reports findings from a study of insect nests across 70 species using 2D and 3D measurements with optical microscopy and X-ray tomography, respectively. Data from these biological nests were used to identify design parameters of interest, which were then translated into design principles. These design principles were implemented in the design of honeycomb panels manufactured with the Selective Laser Sintering process and subjected to experimental testing to study their effects on the mechanical behavior of these panels. Dissertation/Thesis Goss, Derek Lee (Author) Bhate, Dhruv (Advisor) Lewis, Sharon (Committee member) Nam, Changho (Committee member) Arizona State University (Publisher) Design Biology Additive Manufacturing Bio-Inspired Honeycomb Sandwich Panel eng 77 pages Masters Thesis Manufacturing Engineering 2020 Masters Thesis http://hdl.handle.net/2286/R.I.57296 http://rightsstatements.org/vocab/InC/1.0/ 2020
collection NDLTD
language English
format Dissertation
sources NDLTD
topic Design
Biology
Additive Manufacturing
Bio-Inspired
Honeycomb
Sandwich Panel
spellingShingle Design
Biology
Additive Manufacturing
Bio-Inspired
Honeycomb
Sandwich Panel
Bio-Inspired Design of Next Generation Honeycomb Sandwich Panel Cores
description abstract: Honeycomb sandwich panels have been used in structural applications for several decades in various industries. While these panels are lightweight and rigid, their design has not evolved much due to constraints imposed by available manufacturing processes and remain primarily two-dimensional extrusions sandwiched between facings. With the growth in Additive Manufacturing, more complex geometries can now be produced, and advanced design techniques can be implemented into end use parts to obtain further reductions in weight, as well as enable greater multi-functionality. The question therefore is: how best to revisit the design of these honeycomb panels to obtain these benefits? In this work, a Bio-Inspired Design approach was taken to answer this question, primarily since the hexagonal lattice is so commonly found in wasp and bee nests, including the well-known bee’s honeycomb that inspired these panel designs to begin with. Whereas prior honeycomb panel design has primarily focused on the hexagonal shape of the unit cell, in this work we examine the relationship between the various parameters constituting the hexagonal cell itself, specifically the wall thickness and the corner radius, and also examine out-of-plane features that have not been previously translated into panel design. This work reports findings from a study of insect nests across 70 species using 2D and 3D measurements with optical microscopy and X-ray tomography, respectively. Data from these biological nests were used to identify design parameters of interest, which were then translated into design principles. These design principles were implemented in the design of honeycomb panels manufactured with the Selective Laser Sintering process and subjected to experimental testing to study their effects on the mechanical behavior of these panels. === Dissertation/Thesis === Masters Thesis Manufacturing Engineering 2020
author2 Goss, Derek Lee (Author)
author_facet Goss, Derek Lee (Author)
title Bio-Inspired Design of Next Generation Honeycomb Sandwich Panel Cores
title_short Bio-Inspired Design of Next Generation Honeycomb Sandwich Panel Cores
title_full Bio-Inspired Design of Next Generation Honeycomb Sandwich Panel Cores
title_fullStr Bio-Inspired Design of Next Generation Honeycomb Sandwich Panel Cores
title_full_unstemmed Bio-Inspired Design of Next Generation Honeycomb Sandwich Panel Cores
title_sort bio-inspired design of next generation honeycomb sandwich panel cores
publishDate 2020
url http://hdl.handle.net/2286/R.I.57296
_version_ 1719315824030777344

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