Electro-Thermal Parameters of Graphene Nano-Platelets Films for De-Icing Applications

Lahbacha, Khitem; Sibilia, Sarah; Trezza, Gianmarco; Giovinco, Gaspare; Bertocchi, Francesco; Chiodini, Sergio; Cristiano, Francesco; Maffucci, Antonio

doi:10.3390/aerospace9020107

Cited by 7 publications

(7 citation statements)

References 38 publications

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“…Note that the solution of model (2)-(3) required a preliminary estimation of the emissivity ε of the tested strips. This was carried out according to the procedure described in [26] and also applied in [27]. Specifically, the emissivity was identified by varying its value until an agreement was reached between the temperature values measured by the IR camera and those given by the contact thermocouples placed on the surface of the strip.…”

Section: Methodology For Estimating the Thermal Conductivity And Diff...mentioning

confidence: 99%

“…The measurement procedure to impose (7) was carried on until steady conditions were almost reached (at least ten minutes in the present study). Note that the dependence on T of the electrical resistance ΔR n of the nth sub-strip was estimated on the basis of the procedure reported in [27,39].…”

Section: Methodology For Estimating the Thermal Conductivity And Diff...mentioning

confidence: 99%

“…In [26,27] these materials have been studied and it has been assessed a technique to evaluate their temperaturedependent electrical conductivity and their thermal emissivity. In this paper, the study is extended to the thermal conductivity and to the thermal diffusivity in order to give a complete analysis and characterization of these GNP-based strips.…”

Section: Introductionmentioning

confidence: 99%

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Characterization of the thermal conductivity and diffusivity of graphene nanoplatelets strips: a low-cost technique

2023

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This paper proposes a new technique to characterize the thermal conductivity and diffusivity of thin strips made by graphene nanoplatelets. The evaluation of these parameters is essential for a reliable design of thermal and electrothermal applications of graphene and is usually performed by means of assessed but expensive techniques such as those based on Raman effects and laser flash. The technique proposed here is simpler and less demanding in terms of equipment, and combines the results of an experimental characterization of the strip heated by the Joule effect obtained with Infra-Red camera, with those provided by an electro-thermal model. Specifically, the evaluation of the thermal conductivity and diffusivity is the result of the analysis of the transient behavior of the measured and simulated solutions. The methodology is here successfully validated by applying it to commercial graphene strips and benchmarking against the thermal parameters provided by the manufacturers. Then, a complete characterization is provided for commercial strips based on different formulations of graphene nanoplatelets and binders such as polyurethane, epoxy resin, and boron nitride. For these materials, the values of thermal conductivity and diffusivity are found in the ranges (50-450) W/(m·K) and (0.5-3.5)·10-4 m2/s, respectively.

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Section: Methodology For Estimating the Thermal Conductivity And Diff...mentioning

confidence: 99%

Section: Methodology For Estimating the Thermal Conductivity And Diff...mentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Characterization of the thermal conductivity and diffusivity of graphene nanoplatelets strips: a low-cost technique

2023

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“…Electrically heated films composed of electromagnetic shielding materials such as MXenes and graphene are commonly employed to address deicing issues. − However, MXenes are relatively expensive, rendering them unsuitable for large-scale application. Traditional graphene electric heating films, characterized by their minimal mass (with film thicknesses attainable down to the order of tens of micrometers) and superior heating efficiency, are prevalently employed for deicing applications. − Nonetheless, this methodology predominantly relinquishes electromagnetic wave transmission capabilities to secure effective deicing outcomes. , Frequency Selective Surfaces (FSSs) have been extensively applied in the realm of wave-transmissive materials in recent years. , Through intricate pattern design that leverages their selective transmission properties, films with both heating and wave-transmission capabilities can be fabricated. However, an optimal electrical conductivity is a requisite for FSSs, whereas excessive conductivity in electric heating materials is typically undesirable.…”

Section: Introductionmentioning

confidence: 99%

A Tri-Layer Structural Film Containing Nickel Nanocoating for Electromagnetic Transmittance and Joule Heating

Zhao,

Xu,

et al. 2024

ACS Appl. Nano Mater.

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In the realm of military applications, the effective management of ice accumulation on strategic equipment without compromising the integrity of the electromagnetic signal transmission is a perennial challenge. To confront this issue, a revolutionary trilayered material composite known as MPE (metal-polyimide-electric heating layer) has been developed, demonstrating a sophisticated balance between deicing functionality and electromagnetic transparency. The MPE composite is ingeniously architected in a trilayer configuration, comprising a frequency-selective wave-transmissive stratum, an interjacent insulating dielectric interlayer, and an electric heating layer. The former is the result of a pioneering surface grafting modality of keratin, subsequently metallized with a nickel (Ni) coat via a chemical plating technique, which concurrently imparts the composite with a temperature-sensitivity range between −10 and 80 °C. The latter is formulated from a cyanate ester (CE) resin with organic conductive fillers, endowing the material with a high thermal threshold of up to 220 °C. Experimental evaluations of the MPE material have yielded a remarkable 88% transmissivity at the designated resonant frequency, a significant improvement over traditional graphene heating layer. This high level of performance, combined with the material's inherent deicing properties and the capacity for remote control via integrated sensing technology, positions the MPE as a substantial breakthrough for military operations.

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“…This would allow the use of such techniques for aircraft applications, where they are not currently used, due to the impact of the conventional heaters, in terms of weight for instance. The authors have investigated the electrothermal properties of graphene strips which may be proposed as heating elements for de-icing systems [ 29 , 30 , 31 ]. Similar results have recently been assessed in the literature [ 32 , 33 ].…”

Section: Introductionmentioning

confidence: 99%

A Capacitive Ice-Sensor Based on Graphene Nano-Platelets Strips

Sibilia,

Tari,

Bertocchi

et al. 2023

Sensors

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This paper investigates the possibility of realizing ice sensors based on the electrical response of thin strips made from pressed graphene nano-platelets. The novelty of this work resides in the use of the same graphene strips that can act as heating elements via the Joule effect, thus opening the route for a combined device able to both detect and remove ice. A planar capacitive sensor is designed and fabricated, in which the graphene strip acts as one of the armatures. The sensing principle is based on the high sensitivity of the planar capacitor to the change in electrical permittivity in the presence of ice, as shown in the experimental case study discussed here, can also be interpreted by means of a simple circuit and electromagnetic model. The properties of the sensor are analyzed, and the frequency range for its use as an ice detector has been established.

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Electro-Thermal Parameters of Graphene Nano-Platelets Films for De-Icing Applications

Cited by 7 publications

References 38 publications

Characterization of the thermal conductivity and diffusivity of graphene nanoplatelets strips: a low-cost technique

Characterization of the thermal conductivity and diffusivity of graphene nanoplatelets strips: a low-cost technique

A Tri-Layer Structural Film Containing Nickel Nanocoating for Electromagnetic Transmittance and Joule Heating

A Capacitive Ice-Sensor Based on Graphene Nano-Platelets Strips

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