Ablation properties of zinc borate and aluminum hypophosphite filled silicone rubber composites

Zhang, Hao; Yan, Liwei; Wang, Yuan; Zhou, Shengtai; Liang, Mei; Zou, Huawei; Chen, Yang

doi:10.1002/app.50804

Cited by 5 publications

(3 citation statements)

References 53 publications

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“…20−22 Unfortunately, most flame retardants could not promote the promotion of the interaction between the charred layer and the nether virgin insulation materials, implying the flaming gas scouring could make the charred layer peel out from the substrate easily which may lead to further erosion of the substrate and thermal protection failure in severe cases. 23,24 Therefore, structural modification of elastomers is a more ideal method to obtain the expected flame-retardant properties. Benefiting from the adjustability of substituents and controllability of combination properties in the structural design and preparation of polyphosphazene, it is significant to consider that utilizing PBPP's structural modification balances the lowtemperature resistance and ablation properties of PDAP.…”

Section: Introductionmentioning

confidence: 99%

“…Drawing on the improving ablation resistance techniques of traditional organic rubber insulation materials, the ablation performance of the traditional EHSM can be effectively improved by the flame-retardant modification of the structure and addition of flame retardants . Like ammonium polyphosphate, boron compounds, and polyhedral oligomeric siloxanes, these flame-retardant fillers could promote the carbonization of organic cracking fragments by retarding oxidation and enhance the strength and density of the charred layer via ceramic reactions, which would help to improve the ablation performance of insulating materials. − Unfortunately, most flame retardants could not promote the promotion of the interaction between the charred layer and the nether virgin insulation materials, implying the flaming gas scouring could make the charred layer peel out from the substrate easily which may lead to further erosion of the substrate and thermal protection failure in severe cases. , Therefore, structural modification of elastomers is a more ideal method to obtain the expected flame-retardant properties. Benefiting from the adjustability of substituents and controllability of combination properties in the structural design and preparation of polyphosphazene, it is significant to consider that utilizing PBPP’s structural modification balances the low-temperature resistance and ablation properties of PDAP.…”

Section: Introductionmentioning

confidence: 99%

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Effects of Fluorinated Side Groups on the Insulation Performances of Polyphosphazenes with Organic Fiber Reinforcement

Zheng,

Wang,

Liu

et al. 2024

ACS Appl. Polym. Mater.

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Poly(diaryloxy)phosphazene (PDAP) possesses good ablative resistance properties, owing to unique charred layers formed during ablation, showing promising applications in aerospace thermal protection. However, the high glass-transition temperature (T g ) of PDAP insulations limits the application in elastomeric heat-shielding materials (EHSMs) that is a need for meeting the growing requirements of solid rocket motors such as low-temperature storage and application. In this work, we focused on improving the low-temperature resistance and ablation resistance of polyphosphazene composites. A class of ablativeresistant poly(octafluoropentyloxy/butoxy/aryloxy)phosphazene (PFBAP) with low T g was prepared by introducing flexible octafluoropentyloxy side groups into poly(butoxy/aryloxy)phosphazene (PBPP). The results showed that the octafluoropentyloxy side groups could improve the thermal oxidative stability, flame retardancy, and interfacial interaction of polyphosphazene. Compared with PBPP composites, the values of linear ablation rate, mass ablation rate, and charring ablation rate of PFBAP 2 (containing 11.86% octafluoropentyloxy side groups) composites were reduced by 65, 34, and 25%, respectively. The study on the ablation mechanism of PFBAP composites shows that the introduction of fluorinated side groups can not only improve the charring degree of insulations during ablation but also exert a flame-retardant effect in the gaseous phase, resulting in a denser and more coherent charred layer. This work demonstrates a way to develop lowtemperature and ablation-resistant polyphosphazene materials for potential thermal protection in the aerospace industry.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Effects of Fluorinated Side Groups on the Insulation Performances of Polyphosphazenes with Organic Fiber Reinforcement

Zheng,

Wang,

Liu

et al. 2024

ACS Appl. Polym. Mater.

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“…Among the various polymers, silicone rubber (SR) has been evidenced as a promising flexible TPS material because SR retains the inherent properties of the polymer at room temperature, and its remarkable flexibility offers the possibility of large deformation while providing excellent ablation resistance by ceramization at high temperatures. − In addition, it tends to exhibit a higher oxidation resistance and superior heat resistance than the other rubbers due to its unique structure with −Si–O– bonds in the backbone, which makes it a reliable choice for external thermal protection applications. − However, pure SR has difficulty in forming a stable char layer and requires improved possibilities for survival in representative heat flux environments. , Although high elongation at break and flexibility make large deformation possible, they also lack the ability to deform adaptively in response to the environment. Exploring the way of self-adaptive deformation and ablation resistance strengthening and the synergistic enhancement mechanism can provide novel strategies and material systems for dynamic thermal protection of high-speed morphing aircraft.…”

Section: Introductionmentioning

confidence: 99%

Flexible Thermal Protection Polymeric Materials with Self-Sensing and Self-Adaptation Deformation Abilities

Chi

Cai

Yan

et al. 2023

ACS Appl. Mater. Interfaces

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Based on the strategy of killing two birds with one stone, we introduce thermally expandable microspheres into a silicone rubber matrix to fabricate temperature-responsive controllable deformation materials, which exhibit intelligent deformation properties as well as enhanced thermal protection performance, for dynamic thermal protection in the next-generation morphing aircrafts. The formation of hollow structures endows the material with intelligent thermal management ability and makes the thermal conductivity controllable, meeting the requirements of rapid deformation and excellent thermal insulation. The dimensions of the material adaptively expand with increasing temperature, and a constant 50N force can be provided to ensure reliable sealing. Moreover, benefiting from the synergistic effect of the hollow structure and zinc borate in the ceramization process of the silicone rubber, the 10 mm thick material can reduce the temperature from 2000 to 63 °C, and the mass ablation rate is only 4.8 mg/s. To broaden the application of our material, a sensor with a sandwich structure composed of different functional layers is designed. It is pleasantly surprising to observe that the sensor can provide real-time remote warning of fire and overheating sites with a response time as short as 1 s. This synergistic strategy opens a new possibility to fabricate intelligent thermal protection materials.

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Catalytic Graphitized Silicone Rubber Coatings with Highly Graphitized Ceramic Layer and Superior Ablation Resistance

Chen

Liu

Huang

et al. 2022

Macro Materials & Eng

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The strength of the ceramic layer formed during ablation of the silicone rubber composite is closely related to its resistance to ablation. Increasing the content of graphitic carbon in the ceramic layer plays a key role in enhancing the strength of ceramic layer. In this study, series of catalytically graphitized mesophase pitch‐modified silicone rubber composites with excellent ablation performance are prepared. And the average linear ablation rate of the composite is reduced to a maximum of 0.046 mm s‐1, which is 44.0% lower than that of the sample without catalyst named 5MP. XRD characterization proves that the addition of transition metal catalysts increases the content of graphitic carbon in the ceramic layers after ablation. The strength of ceramic layer of the 0.13Fe2O3 reached 12.09 MPa, which is 60.3% higher than that of the 5MP. The transition metal catalyst effectively increases the content of graphitic carbon in the ceramic layers, and the strengths of the ceramic layers are significantly improved, thereby greatly improving the ablation performance of the composites.

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Ablation properties of zinc borate and aluminum hypophosphite filled silicone rubber composites

Cited by 5 publications

References 53 publications

Effects of Fluorinated Side Groups on the Insulation Performances of Polyphosphazenes with Organic Fiber Reinforcement

Effects of Fluorinated Side Groups on the Insulation Performances of Polyphosphazenes with Organic Fiber Reinforcement

Flexible Thermal Protection Polymeric Materials with Self-Sensing and Self-Adaptation Deformation Abilities

Catalytic Graphitized Silicone Rubber Coatings with Highly Graphitized Ceramic Layer and Superior Ablation Resistance

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