含玄武岩纤维的增强环氧合成泡沫的制造和压缩性能

IF 2 4区 工程技术 Q3 ENGINEERING, CHEMICAL
Shuai Cao, Tao Jiang, Shanshan Shi, Xiaofan Gui, Ying Wang, Bo Tang, Lixue Xiang, Xuming Dai, Donghai Lin, Ning Zhong, Wenge Li, Jinhong Yu, Xinfeng Wu
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引用次数: 0

摘要

深海设备一般采用轻质耐压材料,以满足实际工作的要求。为了更好地勘探海洋资源,有必要研究用于采矿设备装载的轻质浮力材料。这些浮力材料不仅能为采矿设备提供足够的浮力,还能减少经济支出。本文以发泡聚苯乙烯(EPS)、环氧树脂(EP)和 HGMS 为原料,采用滚球法制备了空心玻璃微球增强环氧树脂空心球(HGMSs-EHSs)。环氧树脂合成泡沫(ESF)是以环氧树脂、固化剂、HGMS 和 HGMS-EHS 为原料,通过模塑方法混合制成的。通过添加玄武岩纤维(BF)在合成泡沫内部形成纤维网,制造出了玄武岩纤维(BF)增强的 ESF。结果表明,随着 HGMS-EHS 层数的增加,ESF 的密度和抗压强度也逐渐增加。随着 HGMS-EHS 堆叠体积分数的增加,ESF 的密度和抗压强度逐渐降低。随着 BF 长度和含量的增加,ESF 的密度和抗压强度逐渐增加。在上述影响因素范围内,ESF 的密度保持在 0.3 g/cm3 左右,密度较低。当 HGMS-EHS 的层数为 2 层、堆叠体积分数为 90%、BF 长度为 12 mm、BF 含量为 4% 时,BF-ESF 的密度为 0.316 g/cm3,抗压强度为 6.93 MPa。制备的浮力材料的抗压强度可满足在一定深度水域作业的抗压要求。其密度仅为 0.316 g/cm3,可提供足够的浮力来平衡设备的重力。与目前的研究相比,本文采用 BFs 作为增强相,制备出密度低、抗压强度高的固体浮力泡沫。实验结果表明,这种经济的纤维材料能有效提高浮力材料的抗压强度。这种浮力材料可能适合装载在开采海洋资源的小型设备上。这项工作为制备低密度固体浮力材料提供了参考。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Fabrication and Compression Properties of Reinforced Epoxy Syntactic Foam With Basalt Fiber

Fabrication and Compression Properties of Reinforced Epoxy Syntactic Foam With Basalt Fiber

Deep-sea equipment is generally made of lightweight and pressure-resistant materials in order to meet the requirements of the actual work. In order to explore marine resources better, it is necessary to research lightweight buoyancy materials for loading on mining equipment. These buoyancy materials contribute not only to providing adequate buoyancy to the mining equipment but also to reducing economic expenses. In this paper, hollow glass microspheres reinforced epoxy hollow spheres (HGMSs-EHSs) were prepared by the rolling ball method using expanded polystyrene (EPS), epoxy resin (EP), and HGMS as raw materials. Epoxy syntactic foam (ESF) was manufactured by blending EP, curing agent, HGMS, and HGMS-EHS with molding method. Basalt fiber (BF) reinforced ESF was fabricated by adding BFs to form a fiber network inside the syntactic foam. The results revealed that the density and compressive strength of ESF increased progressively with the number of HGMS-EHS layers. The density and compressive strength of ESF decreased prospectively with the increase of the stacking volume fraction of HGMS-EHS. The density and compressive strength of ESF increased gradually with the enlargement of the length and content of BF. In the range of influencing factors mentioned above, the density of ESF remains around 0.3 g/cm3, which has a low density. When the number of layers of HGMS-EHS was two, the stacking volume fraction was 90%, the length of BF was 12 mm, the content of BF was 4%, the density of BF-ESF was 0.316 g/cm3, and the compressive strength was 6.93 MPa. The compressive strength of prepared buoyancy material can meet the pressure resistance requirements for operations in waters of a certain depth. With a density of only 0.316 g/cm3, it provides sufficient buoyancy to balance the gravity of the equipment. Compared with the current study, in this paper, BFs were used as the reinforcing phase to prepare solid buoyancy foam with low density and high compressive strength. The experimental results demonstrate that this economical fiber material can effectively improve the compressive strength of buoyancy materials. This buoyancy material may be suitable for loading on small equipment for extracting marine resources. This work provides a reference for the preparation of low-density solid buoyancy materials.

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来源期刊
Advances in Polymer Technology
Advances in Polymer Technology 工程技术-高分子科学
CiteScore
5.50
自引率
0.00%
发文量
70
审稿时长
9 months
期刊介绍: Advances in Polymer Technology publishes articles reporting important developments in polymeric materials, their manufacture and processing, and polymer product design, as well as those considering the economic and environmental impacts of polymer technology. The journal primarily caters to researchers, technologists, engineers, consultants, and production personnel.
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