Gürses Ahmet, Şahin Elif
Department of Chemistry Education, K.K. Education Faculty, Ataturk University, Erzurum 25240, Turkey.
Nano Science and Nano Engineering Department, Ataturk University, Erzurum 25240, Turkey.
Polymers (Basel). 2024 Dec 21;16(24):3578. doi: 10.3390/polym16243578.
The main purpose of this study is to prepare a melamine aniline formaldehyde foam, an MAF copolymer, with lower water sensitivity and non-flammability properties obtained by the condensation reaction of melamine, aniline, and formaldehyde. In addition, the preparation of MAFF composites with organoclay reinforcement was determined as a secondary target in order to obtain better mechanical strength, heat, and sound insulation properties. For the synthesis of foams, the microwave irradiation technique, which offers advantages such as faster reactions, high yields and purities, and reduced curing times, was used together with the heating technique and the effect of organoclay content on the structural and textural properties of foams and both heat insulation and mechanical stability was investigated. Virgin melamine formaldehyde foam, MFF, melamine aniline formaldehyde foam, MAFFF, and melamine aniline formaldehyde-organoclay nanocomposite foams prepared with various organoclay contents, MAFOCFs, were characterized by HRTEM, FTIR, SEM, and XRD techniques. From spectroscopic and microscopic analyses, it was observed that organoclay flakes could be exfoliated without much change in the resin matrix with increasing clay content. In addition, it was determined that aniline formaldehyde, which is thought to enter the main polymer network as a bridge, caused textural changes in the polymeric matrix, and organoclay reinforcement also affected these changes. Although the highest compressive strength was obtained in MAFOCF5 foam with high organoclay content (0.40 MPa), it was determined that the compressive strengths in the nanocomposites were generally quite high despite their low bulk densities. In the prepared nanocomposite with 0.30% organoclay content (MAFOCF2), 0.33 MPa compressive strength and 0.051 thermal conductivity coefficient were measured. For virgin polymers and composites, bulk density, thermal conductivity, and compressive strength values were determined in the order of magnitude as MFF > MAFOCF1 > MAFOCF5 > MAFOCF6 > MAFF > MAFOCF3 > MAFOCF2 > MAFOCF4; MFF > MAFF > MAFOCF6 > MAFOCF5 > MAFOCF1 > MAFOCF4 > MAFOCF3 > MAFOCF2 and MAFOCF5 > MAFOCF4 > MAFOCF2 > MAFF > MAFOCF6 > MFF > MAFOCF1 > MAFOCF3. As a result, both compressive strength and thermal conductivity values indicate that nanocomposite foam with 0.20 wt% organoclay content can be a promising new insulation material.
本研究的主要目的是制备一种三聚氰胺苯胺甲醛泡沫(一种MAF共聚物),其通过三聚氰胺、苯胺和甲醛的缩合反应获得,具有较低的水敏感性和不燃性。此外,为了获得更好的机械强度、隔热和隔音性能,将制备有机粘土增强的MAFF复合材料确定为次要目标。对于泡沫的合成,采用了微波辐射技术,该技术具有反应更快、产率和纯度高以及固化时间缩短等优点,并与加热技术一起使用,研究了有机粘土含量对泡沫结构和织构性能以及隔热和机械稳定性的影响。用不同有机粘土含量制备的纯三聚氰胺甲醛泡沫(MFF)、三聚氰胺苯胺甲醛泡沫(MAFFF)和三聚氰胺苯胺甲醛 - 有机粘土纳米复合泡沫(MAFOCFs)通过高分辨率透射电子显微镜(HRTEM)、傅里叶变换红外光谱(FTIR)、扫描电子显微镜(SEM)和X射线衍射(XRD)技术进行了表征。从光谱和显微镜分析中观察到,随着粘土含量的增加,有机粘土薄片可以在树脂基体中剥离而变化不大。此外,据确定,被认为作为桥梁进入主聚合物网络的苯胺甲醛导致了聚合物基体的织构变化,并且有机粘土增强也影响了这些变化。尽管在高有机粘土含量的MAFOCF5泡沫中获得了最高抗压强度(0.40 MPa),但确定纳米复合材料的抗压强度尽管其堆积密度低但总体上相当高。在制备的有机粘土含量为0.30%的纳米复合材料(MAFOCF2)中,测量到抗压强度为0.33 MPa,导热系数为0.051。对于纯聚合物和复合材料,堆积密度、导热系数和抗压强度值的大小顺序为MFF > MAFOCF1 > MAFOCF5 > MAFOCF6 > MAFF > MAFOCF3 > MAFOCF2 > MAFOCF4;MFF > MAFF > MAFOCF6 > MAFOCF5 > MAFOCF1 > MAFOCF4 > MAFOCF3 > MAFOCF2以及MAFOCF5 > MAFOCF4 > MAFOCF2 > MAFF > MAFOCF6 > MFF > MAFOCF1 > MAFOCF3。结果表明,抗压强度和导热系数值均表明有机粘土含量为0.20 wt%的纳米复合泡沫可能是一种有前途的新型隔热材料。
