Thermal morphing anisogrid smart space structures: Part 1. Introduction, modeling, and performance of the novel smart structural application

Phoenix, Austin A.; Tarazaga, Pablo A.

doi:10.1177/1077546317715545

Journal of Vibration and Control

2017

DOI: 10.1177/1077546317715545

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Thermal morphing anisogrid smart space structures: Part 1. Introduction, modeling, and performance of the novel smart structural application

Austin A. Phoenix

Pablo A. Tarazaga

Abstract: To meet the requirements for the next generation of space missions, a paradigm shift is required from current structures that are static, heavy, and stiff to innovative structures that are adaptive, lightweight, versatile, and intelligent. The largest benefit provided by this new structural concept is in the ability to deliver high precision position stability. The conventional high precision structural design uses two decoupled systems to achieve positional stability. First, a high mass structure delivers the… Show more

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Cited by 4 publications

References 55 publications

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Adaptive Thermal Conductivity Metamaterials: Enabling Active and Passive Thermal Control

Phoenix

Wilson

2018

Journal of Thermal Science and Engineering Applications

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The novel adaptive thermal metamaterial developed in this paper provides a unique thermal management capability that can address the needs of future spacecraft. While advances in metamaterials have provided the ability to generate materials with a broad range of material properties, relatively little advancement has been made in the development of adaptive metamaterials. This metamaterial concept enables the development of materials with a highly nonlinear thermal conductivity as a function of temperature. Through enabling active or passive control of the metamaterials bulk effective thermal conductivity, this metamaterial that can improve the spacecraft's thermal management systems performance. This variable thermal conductivity is achieved through induced contact that results in changes in the F path length and the conductive path area. The contact can be generated internally using thermal strain from shape memory alloys, bimetal springs, and mismatches in coefficient of thermal expansion (CTE) or it can be generated externally using applied mechanical loading. The metamaterial can actively control the temperature of an interface by dynamically changing the bulk thermal conductivity controlling the instantaneous heat flux through the metamaterial. The design of thermal stability regions (regions of constant thermal conductivity versus temperature) into the nonlinear thermal conductivity as a function of temperature can provide passive thermal control. While this concept can be used in a wide range of applications, this paper focuses on the development of a metamaterial that achieves highly nonlinear thermal conductivity as a function of temperature to enable passive thermal control of spacecraft systems on orbit.

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Adaptive Thermal Conductivity Metamaterials: Enabling Active and Passive Thermal Control

Phoenix

Wilson

2018

Journal of Thermal Science and Engineering Applications

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Variable Thermal Conductivity Metamaterials Applied to Passive Thermal Control of Satellites

Phoenix

2023

Journal of Thermal Science and Engineering Applications

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Active materials, such as the proposed variable thermal conductivity metamaterial, enables new thermal designs and low-cost, low-power, passive thermal control. Thermal control of satellites conventionally requires active thermal control systems that are expensive, large, inefficient, energy-intensive, and unavailable for CubeSats. For CubeSats, the thermal system's primary design consideration is the high-temperature operation case. The thermal path is designed to reject as much heat as possible to prevent overheating. In other cases, such as during a power anomaly, the oversized thermal path results in rapid cooling, culminating in mission failure due to thermal limits on the electronics or batteries. Improving the thermal control of CubeSats can enable new thermally challenging missions, increase satellite longevity, and increase mission success rate by controlling and dynamic thermal environment. The materials available for thermal management are limited, but new engineered materials provide unique opportunities to change how satellites adapt to dynamic environmental and thermal loads. This paper investigates using an adaptive metamaterial designed to passively change its thermal conductivity as a function of temperature to meet the needs of the satellite. The thermal performance of a CubeSat is evaluated with a variable thermal conductivity metamaterial located in the critical thermal path from the satellite to the radiator. The system's performance using two metamaterial configurations is compared to a baseline copper thermal path. Multiple satellite thermal operation cases are investigated to determine the operation ranges, and the metamaterial's performance in various conditions is quantified.

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Thermal modeling and design of the anisogrid morphing structure for a modular optical telescope concept

Phoenix

2017

J. Astron. Telesc. Instrum. Syst

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Thermal morphing anisogrid smart space structures: Part 1. Introduction, modeling, and performance of the novel smart structural application

Cited by 4 publications

References 55 publications

Adaptive Thermal Conductivity Metamaterials: Enabling Active and Passive Thermal Control

Adaptive Thermal Conductivity Metamaterials: Enabling Active and Passive Thermal Control

Variable Thermal Conductivity Metamaterials Applied to Passive Thermal Control of Satellites

Thermal modeling and design of the anisogrid morphing structure for a modular optical telescope concept

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