纺织空调废弃物粉尘填充聚氨酯硬质泡沫复合材料的性能研究

IF 2.1 4区材料科学 Q3 MATERIALS SCIENCE, COMPOSITES

Plastics, Rubber and Composites Pub Date : 2021-10-25 DOI:10.1080/14658011.2021.1993677

E. B. Özkan Buzğan, G. Kaya, M. Kertmen, H. G. Türksoy

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引用次数: 1

摘要

研究了纺织空调粉尘填充聚氨酯(PU)硬质泡沫材料的形态、力学性能和保温性能。纺织空调粉尘是在短纤维纺纱过程中产生的。它由棉纤维杂质组成，如棉铃、叶片和短纤维，产生巨大的环境负荷。这种粉尘被用作填料并分散在高达40%重量的聚氨酯中。随着填料比例的增加，泡沫的细胞尺寸减小，细胞密度增加，其中粉尘在细胞形成过程中充当异质成核位点。粉尘在聚氨酯泡沫中聚集，导致细胞壁不规则，细胞形成不均匀，细胞破裂较多。在较高的粉尘含量(40% wt.)下，抗弯强度和模量下降。纤维素基粉尘的低绝热性和泡沫细胞的破坏结构/均匀性导致粉尘填充聚氨酯硬质泡沫复合材料的热导率不稳定/较低。

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Properties of textile air conditioner waste dust-filled polyurethane rigid foam composites

ABSTRACT This paper investigates the morphology, mechanical and thermal insulation properties of textile air conditioner dust-filled polyurethane (PU) rigid foams. Textile air conditioner dust occurs during the spinning process of staple fibres. It consists of cotton fibre impurities as boll, leaf, and short fibres that generate a vast environmental load. This dust is used as a filler and dispersed in polyurethane up to 40% wt. The cell -size of foams decreased and cell -density increased by the increase in filler ratios in which the dust acted as a heterogeneous nucleation site during cell formation. The dust agglomerated in polyurethane foam and induced irregular cell wall and hence non-uniform cell formation and many broken cells. The flexural strength and modulus decreased in higher dust content (40% wt.). The lower thermal insulation of cellulose-based dust and damaged structure/uniformity of foam cells resulted in an unstable/lower thermal conductivity of dust-filled polyurethane rigid foam composites.

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来源期刊

Plastics, Rubber and Composites 工程技术-材料科学：复合

CiteScore

4.10

自引率

0.00%

发文量

审稿时长

4 months

期刊介绍： Plastics, Rubber and Composites: Macromolecular Engineering provides an international forum for the publication of original, peer-reviewed research on the macromolecular engineering of polymeric and related materials and polymer matrix composites. Modern polymer processing is increasingly focused on macromolecular engineering: the manipulation of structure at the molecular scale to control properties and fitness for purpose of the final component. Intimately linked to this are the objectives of predicting properties in the context of an optimised design and of establishing robust processing routes and process control systems allowing the desired properties to be achieved reliably.