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使用高速氧燃料炬对碳酚醛和碳化硅涂层碳复合材料进行热消融实验。

Thermal Ablation Experiments of Carbon Phenolic and SiC-Coated Carbon Composite Materials Using a High-Velocity Oxygen-Fuel Torch.

作者信息

Chinnaraj Rajesh Kumar, Kim Young Chan, Choi Seong Man

机构信息

Department of Aerospace Engineering, Jeonbuk National University, Jeonju 54896, Republic of Korea.

出版信息

Materials (Basel). 2023 Feb 24;16(5):1895. doi: 10.3390/ma16051895.

DOI:10.3390/ma16051895
PMID:36903009
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC10003895/
Abstract

For future spacecraft TPS (heat shield) applications, ablation experiments of carbon phenolic material specimens with two lamination angles (0° and 30°) and two specially designed SiC-coated carbon-carbon composite specimens (with either cork or graphite base) were conducted using an HVOF material ablation test facility. The heat flux test conditions ranged from 3.25 to 11.5 MW/m, corresponding to an interplanetary sample return re-entry heat flux trajectory. A two-color pyrometer, an IR camera, and thermocouples (at three internal locations) were used to measure the specimen temperature responses. At the 11.5 MW/m heat flux test condition, the 30° carbon phenolic specimen's maximum surface temperature value is approximately 2327 K, which is approximately 250 K higher than the corresponding value of the SiC-coated specimen with a graphite base. The 30° carbon phenolic specimen's recession value is approximately 44-fold greater, and the internal temperature values are approximately 1.5-fold lower than the corresponding values of the SiC-coated specimen with a graphite base. This indicates that increased surface ablation and a higher surface temperature relatively reduced heat transfer to the 30° carbon phenolic specimen's interior, leading to lower internal temperature values compared to those of the SiC-coated specimen with a graphite base. During the tests, a phenomenon of periodic explosions occurred on the 0° carbon phenolic specimen surfaces. The 30° carbon phenolic material is considered more suitable for TPS applications due to its lower internal temperatures, as well as the absence of abnormal material behavior as observed in the 0° carbon phenolic material.

摘要

对于未来航天器的热防护系统(隔热罩)应用,使用高超声速燃烧风洞材料烧蚀试验设施,对具有两种层压角度(0°和30°)的碳酚醛材料试样以及两种特殊设计的碳化硅涂层碳 - 碳复合材料试样(软木或石墨基体)进行了烧蚀实验。热流测试条件范围为3.25至11.5兆瓦/平方米,对应于行星际样本返回再入热流轨迹。使用双色高温计、红外热像仪和热电偶(在三个内部位置)来测量试样的温度响应。在11.5兆瓦/平方米的热流测试条件下,30°碳酚醛试样的最大表面温度值约为2327K,比具有石墨基体的碳化硅涂层试样的相应值高约250K。30°碳酚醛试样的烧蚀值大约大44倍,内部温度值比具有石墨基体的碳化硅涂层试样的相应值低约1.5倍。这表明表面烧蚀增加和表面温度较高相对减少了向30°碳酚醛试样内部的热传递,导致其内部温度值低于具有石墨基体的碳化硅涂层试样。在测试过程中,0°碳酚醛试样表面出现了周期性爆炸现象。由于其较低的内部温度以及没有观察到0°碳酚醛材料中出现的异常材料行为,30°碳酚醛材料被认为更适合用于热防护系统应用。

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