Analysis-driven design of vascular antennas embedded in multifunctional composites

D. J. Hartl; G. J. Frank; G. H. Huff; J. W. Baur

Analysis-driven design of vascular antennas embedded in multifunctional composites

D. J. Hartl, G. J. Frank, G. H. Huff, J. W. Baur

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution

Abstract

Research on structurally embedded microvascular systems in laminated structures continues to provide new insights into the areas of thermal transport and self-healing. At the same time, the number of studies considering uses of non-toxic liquid metal (LM) alloys for reconfigurable electronics is also increasing. This work benefits from these efforts and proposes a concept for a reconfigurable Structurally Embedded Vascular Antenna (SEVA). A set of fully coupled multi-physical engineering models of the driven antenna consider the electromagnetic, fluid, thermal, and mechanical responses. A full-wave electromagnetic model (frequency domain) is used to assess antenna Radio Frequency (RF) performance and compute dissipative heat generation (dielectric and resistive). The full field heat source data is then passed to a conjugate heat transfer model, which accounts for the thermal coupling between the solid composite and flowing fluid based on the LM pumping pressure. Finally, a representative volume element representing a local region of the highest temperature is used to compute mechanical knockdown ratios relative to a similar panel with no microvascular network. The entire modeling framework is implemented using a combination of COMSOL, Matlab, Abaqus FEA, and Python tools and libraries. It is shown that the increased resistive heating that results from the use of LM can be offset by the action of circulating the liquid metal such that heat is continuously removed from the system. A simulation process management framework is used to automate design of experiment (DOE) and multi-objective optimization studies. Because of the high computational cost associated with performing the multi-physical computational analysis, a surrogate model-based optimization approach is employed to explore the design space associated with this concept and to arrive at SEVA configurations that simultaneously maximize antenna effectiveness and structural strength.

Original language	English (US)
Title of host publication	Proceedings of the American Society for Composites - 31st Technical Conference, ASC 2016
Editors	Barry D. Davidson, Michael W. Czabaj, James G. Ratcliffe
Publisher	DEStech Publications Inc.
ISBN (Electronic)	9781605953168
State	Published - 2016
Event	31st Annual Technical Conference of the American Society for Composites, ASC 2016 - Williamsburg, United States Duration: Sep 19 2016 → Sep 21 2016

Publication series

Name	Proceedings of the American Society for Composites - 31st Technical Conference, ASC 2016

Other

Other	31st Annual Technical Conference of the American Society for Composites, ASC 2016
Country/Territory	United States
City	Williamsburg
Period	9/19/16 → 9/21/16

All Science Journal Classification (ASJC) codes

Ceramics and Composites

Cite this

Hartl, D. J., Frank, G. J., Huff, G. H., & Baur, J. W. (2016). Analysis-driven design of vascular antennas embedded in multifunctional composites. In B. D. Davidson, M. W. Czabaj, & J. G. Ratcliffe (Eds.), Proceedings of the American Society for Composites - 31st Technical Conference, ASC 2016 (Proceedings of the American Society for Composites - 31st Technical Conference, ASC 2016). DEStech Publications Inc..

Hartl, D. J. ; Frank, G. J. ; Huff, G. H. et al. / Analysis-driven design of vascular antennas embedded in multifunctional composites. Proceedings of the American Society for Composites - 31st Technical Conference, ASC 2016. editor / Barry D. Davidson ; Michael W. Czabaj ; James G. Ratcliffe. DEStech Publications Inc., 2016. (Proceedings of the American Society for Composites - 31st Technical Conference, ASC 2016).

@inproceedings{af32a11c12604f18aca7a11c24bbbf72,

title = "Analysis-driven design of vascular antennas embedded in multifunctional composites",

abstract = "Research on structurally embedded microvascular systems in laminated structures continues to provide new insights into the areas of thermal transport and self-healing. At the same time, the number of studies considering uses of non-toxic liquid metal (LM) alloys for reconfigurable electronics is also increasing. This work benefits from these efforts and proposes a concept for a reconfigurable Structurally Embedded Vascular Antenna (SEVA). A set of fully coupled multi-physical engineering models of the driven antenna consider the electromagnetic, fluid, thermal, and mechanical responses. A full-wave electromagnetic model (frequency domain) is used to assess antenna Radio Frequency (RF) performance and compute dissipative heat generation (dielectric and resistive). The full field heat source data is then passed to a conjugate heat transfer model, which accounts for the thermal coupling between the solid composite and flowing fluid based on the LM pumping pressure. Finally, a representative volume element representing a local region of the highest temperature is used to compute mechanical knockdown ratios relative to a similar panel with no microvascular network. The entire modeling framework is implemented using a combination of COMSOL, Matlab, Abaqus FEA, and Python tools and libraries. It is shown that the increased resistive heating that results from the use of LM can be offset by the action of circulating the liquid metal such that heat is continuously removed from the system. A simulation process management framework is used to automate design of experiment (DOE) and multi-objective optimization studies. Because of the high computational cost associated with performing the multi-physical computational analysis, a surrogate model-based optimization approach is employed to explore the design space associated with this concept and to arrive at SEVA configurations that simultaneously maximize antenna effectiveness and structural strength.",

author = "Hartl, {D. J.} and Frank, {G. J.} and Huff, {G. H.} and Baur, {J. W.}",

year = "2016",

language = "English (US)",

series = "Proceedings of the American Society for Composites - 31st Technical Conference, ASC 2016",

publisher = "DEStech Publications Inc.",

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booktitle = "Proceedings of the American Society for Composites - 31st Technical Conference, ASC 2016",

address = "United States",

note = "31st Annual Technical Conference of the American Society for Composites, ASC 2016 ; Conference date: 19-09-2016 Through 21-09-2016",

}

Hartl, DJ, Frank, GJ, Huff, GH & Baur, JW 2016, Analysis-driven design of vascular antennas embedded in multifunctional composites. in BD Davidson, MW Czabaj & JG Ratcliffe (eds), Proceedings of the American Society for Composites - 31st Technical Conference, ASC 2016. Proceedings of the American Society for Composites - 31st Technical Conference, ASC 2016, DEStech Publications Inc., 31st Annual Technical Conference of the American Society for Composites, ASC 2016, Williamsburg, United States, 9/19/16.

Analysis-driven design of vascular antennas embedded in multifunctional composites. / Hartl, D. J.; Frank, G. J.; Huff, G. H. et al.
Proceedings of the American Society for Composites - 31st Technical Conference, ASC 2016. ed. / Barry D. Davidson; Michael W. Czabaj; James G. Ratcliffe. DEStech Publications Inc., 2016. (Proceedings of the American Society for Composites - 31st Technical Conference, ASC 2016).

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution

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AU - Frank, G. J.

AU - Huff, G. H.

AU - Baur, J. W.

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N2 - Research on structurally embedded microvascular systems in laminated structures continues to provide new insights into the areas of thermal transport and self-healing. At the same time, the number of studies considering uses of non-toxic liquid metal (LM) alloys for reconfigurable electronics is also increasing. This work benefits from these efforts and proposes a concept for a reconfigurable Structurally Embedded Vascular Antenna (SEVA). A set of fully coupled multi-physical engineering models of the driven antenna consider the electromagnetic, fluid, thermal, and mechanical responses. A full-wave electromagnetic model (frequency domain) is used to assess antenna Radio Frequency (RF) performance and compute dissipative heat generation (dielectric and resistive). The full field heat source data is then passed to a conjugate heat transfer model, which accounts for the thermal coupling between the solid composite and flowing fluid based on the LM pumping pressure. Finally, a representative volume element representing a local region of the highest temperature is used to compute mechanical knockdown ratios relative to a similar panel with no microvascular network. The entire modeling framework is implemented using a combination of COMSOL, Matlab, Abaqus FEA, and Python tools and libraries. It is shown that the increased resistive heating that results from the use of LM can be offset by the action of circulating the liquid metal such that heat is continuously removed from the system. A simulation process management framework is used to automate design of experiment (DOE) and multi-objective optimization studies. Because of the high computational cost associated with performing the multi-physical computational analysis, a surrogate model-based optimization approach is employed to explore the design space associated with this concept and to arrive at SEVA configurations that simultaneously maximize antenna effectiveness and structural strength.

AB - Research on structurally embedded microvascular systems in laminated structures continues to provide new insights into the areas of thermal transport and self-healing. At the same time, the number of studies considering uses of non-toxic liquid metal (LM) alloys for reconfigurable electronics is also increasing. This work benefits from these efforts and proposes a concept for a reconfigurable Structurally Embedded Vascular Antenna (SEVA). A set of fully coupled multi-physical engineering models of the driven antenna consider the electromagnetic, fluid, thermal, and mechanical responses. A full-wave electromagnetic model (frequency domain) is used to assess antenna Radio Frequency (RF) performance and compute dissipative heat generation (dielectric and resistive). The full field heat source data is then passed to a conjugate heat transfer model, which accounts for the thermal coupling between the solid composite and flowing fluid based on the LM pumping pressure. Finally, a representative volume element representing a local region of the highest temperature is used to compute mechanical knockdown ratios relative to a similar panel with no microvascular network. The entire modeling framework is implemented using a combination of COMSOL, Matlab, Abaqus FEA, and Python tools and libraries. It is shown that the increased resistive heating that results from the use of LM can be offset by the action of circulating the liquid metal such that heat is continuously removed from the system. A simulation process management framework is used to automate design of experiment (DOE) and multi-objective optimization studies. Because of the high computational cost associated with performing the multi-physical computational analysis, a surrogate model-based optimization approach is employed to explore the design space associated with this concept and to arrive at SEVA configurations that simultaneously maximize antenna effectiveness and structural strength.

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M3 - Conference contribution

AN - SCOPUS:85013955096

T3 - Proceedings of the American Society for Composites - 31st Technical Conference, ASC 2016

BT - Proceedings of the American Society for Composites - 31st Technical Conference, ASC 2016

A2 - Davidson, Barry D.

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PB - DEStech Publications Inc.

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ER -

Hartl DJ, Frank GJ, Huff GH, Baur JW. Analysis-driven design of vascular antennas embedded in multifunctional composites. In Davidson BD, Czabaj MW, Ratcliffe JG, editors, Proceedings of the American Society for Composites - 31st Technical Conference, ASC 2016. DEStech Publications Inc. 2016. (Proceedings of the American Society for Composites - 31st Technical Conference, ASC 2016).

Analysis-driven design of vascular antennas embedded in multifunctional composites

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