Recovery Technology of DMF from Wet Type Polyurethane Synthetic Leather Waste Gas

A new recovery technology is developed to recycle N,N-dimethyl formamide （DMF） in waste gas from wet type polyurethane synthetic leather industry. Given that the concentration of DMF in waste gas was as low as 325.6- 688.3 mg·m^-3, it was necessary to make sure two phases contact adequately and strengthen the mass transfer by increasing contact area and enhancing the turbulence. Therefore, two-stage countercurrent absorption and two-stage fog removing system were introduced into the technology. The top section of the absorption column was filled with structured wire-ripple stainless steel packing BX500, while the lower section with sting-ripple packing CB250Y. Total height of packing material was 6 m. In addition, there were both two-stage fog removing layer and high efficiency liquid distributor at the column top. All the operating parameters, including temperature, pressure, flow rate and liquid position, could be controlled by computers without manual operation, making sure the outlet gas achieved the national emission standard that the DMF concentration should be below 40 mg·m^-3. The whole equipment could recover 237.6 t of DMF each year, with the profit up to CNY 521×10^3.

Synthesis of Hyperbranched Polymers and Its Effect on Water Vapor Permeability of Microfiber Synthetic Leather

A series of hyperbranched poly(amine-ester)polyols were synthesized by the polycondensation of N,N-diethylol-3-amine-methylpropionate(prepared by Michael addition reaction of methyl acrylate with diethanolamine)as an AB2-type monomer with trimethylol propane as the core moiety,proceeding in one-step procedure in the melt with p-toluenesulfonic acid as catalyst.The obtained monomer and polymers were characterized by FTIR and 1H-NMR spectroscopy.The solubility and surface activity in aqueous solution of the polymers were also examined.The gas permeability,water vapor permeability,and moisture absorption of microfiber synthetic leather treated by hyperbranched polymer were studied.The optimum conditions were that the dosage of dye and hyperbranched polymer was 5% and 10%,respectively.The water vapor permeability and moisture absorption of microfiber synthetic leather reached to 0.525 4 mg/(10 cm2·24 h)and 0.046 7 mg/(10 cm2·24 h).Compared with blank samples,they increased by 15% and 35%,respectively.However,the dosage of hyperbranched polymer has little influence on gas permeability of microfiber synthetic leather.SEM results show that the fiber of microfiber synthetic leather treated by hyperbranched polymer is incompact.

Application of Cationic Waterborne Polyurethane as Impregnation Material for Microfiber Synthetic Leather Base

A cationic waterborne polyurethane(CWPU) was synthesized and utilized as impregnation material for manufacturing microfiber synthetic leather base,in an attempt to decrease environmental pollution associated with organic solvents and improve simulation degree relative to genuine leather.The alkali resistance of the CWPU and four manufacture methods were investigated.Meanwhile,the dyeing properties of the microfiber synthetic leather base were studied.It was found that the CWPU displayed enough alkali resistance to endure the alkali deweighting process for microfiber synthetic leather base manufacture.In terms of bending length,bending rigidity,compression elasticity ratio and specific compression elasticity ratio of the resulting base,coagulating the impregnated CWPU with sodium hydroxide before steam treatment was the optimal method.The extent of fiber splitting and the handle of the base from this method were both similar to conventional base filled with solvent-based polyurethane(SPU).The dyeing properties of the microfiber synthetic leather base filled with CWPU were also found superior to the one filled with either anionic waterborne polyurethane(AWPU) or SPU.

Wearable synthetic leather-based high-performance X-ray shielding materials enabled by the plant polyphenol-and hierarchical structure-facilitated dispersion

Effective protection against X-ray is the premise of utilizing the X-ray,thus it is critical to develop novel X-ray shielding materials with both low density and high X-ray attenuation efficiency.As the even distribution of high-Z element components is of great significance for increasing the attenuation efficiency of X-ray shielding materials,in this study,the microfiber membrane(MFM),a type of synthetic leather featuring hierarchical structure was chosen to provide large surface area for the dispersion of rare earth(RE)element.Meanwhile,plant polyphenol was utilized to achieve the stable loading and uniform dispersion of the Ce or Er into MFM.Benefiting from the assistance of polyphenol and hierarchical structure of MFM,the even dispersion of RE element was successfully realized.The resultant shielding materials displayed approximately 10%superior X-ray attenuation efficiency compared to that without polyphenol,and an averagely 9%increment in X-ray attenuation efficiency than that without hierarchical structure.Moreover,the obtained composite with a thickness of 2.8 mm displayed superior X-ray shielding performance compared to 0.25 mm lead sheet in 16-83 keV and retained an ultralow density of 1.4 g cm^(-3).Our research results would shed new light on the manufacture of high-performance X-ray shielding materials with excellent X-ray shielding performance.

合成革材料在球类运动用品中的差异与优势比较分析

球类运动是当下热门的运动种类,相关用品的材料制备是目前我国体育产业领域的重点方向之一。以篮球、足球、排球等球类运动为例,通过对球类运动用品进行分类,总结了不同球类运动用品的需求差异、性能差异,对球类、运动鞋、防护用品等相关运动用品合成革材料的制备原理和工艺分别进行分析,应用合成革制备球类运动产品,能够充分利用合成革材料种类丰富、可加工性强等优势,满足不同球类运动用品的个性化需求,作为传统天然皮革的有效替代物,合成革在球类运动用品加工领域具有极为广阔的应用前景。旨在为体育产业与合成革材料的融合提供借鉴。

体育服饰用超细纤维合成革针刺非织造基布的力学性能表征

为有效解决开纤处理后海岛超细纤维针刺非织造基布致密性低且针刺痕迹等一系列问题,以促使其在体育服饰用超细纤维合成革中广泛应用,本文基于针刺法将高收缩聚酯纤维掺入海岛超细纤维合成革非织造基布,以制备生成了超细纤维合成革针刺非织造基布,并对其力学性能进行了测试表征。结果发现,随着高收缩聚酯纤维掺入量增加,超细纤维合成革针刺非织造基布断裂强度与撕裂强度皆逐渐增大;透湿性与吸湿性先降低后升高;热收缩率逐步增高;耐磨性逐渐提升,且基布均匀度较好;弯曲长度与弯曲刚度皆逐渐增大,柔软度随之降低;以针刺非织造基布为原料制成的体育服饰用超细纤维合成革表面平整且光滑,底面平整且粗糙度适中,致密性较好,且断裂强度、撕裂强度、透湿性与吸水性均表现优异。

运动器材用水性聚氨酯合成革胶膜制备及其性能研究

为改善运动器材用水性聚氨酯合成革综合性能,本文以聚丙二醇2000与二月桂酸二丁基锡为原料,以硅烷偶联剂为改性剂制备了水性聚氨酯合成革胶膜,并对其性能进行了测试表征。结果表明,随着硅烷偶联剂用量增加,合成革用水性聚氨酯乳液由透明变为白色,粒径逐渐增大,黏度逐步增大,离心稳定性较好;随着硅烷偶联剂用量增加,水性聚氨酯合成革胶膜拉伸强度与断裂伸长率均先增后减,杨氏模量先缓慢增大后迅速增大,剥离强度先增后减,当用量为6 g时胶膜力学性能整体表现最优;随着硅烷偶联剂用量增加,水性聚氨酯合成革胶膜吸水率先减后增,水接触角逐渐增大,当用量为6 g时胶膜耐水性能整体表现最佳。

体育用品合成革用水性聚氨酯热熔胶研究

为顺应绿色环保理念,保障体育运动装备综合性能,优化体育用品用水性聚氨酯合成革的力学性能与粘接性能,制备环保型水性聚氨酯热熔胶以粘接、修补合成革具有非常重要的现实意义。据此,本文以甲苯二异氰酸酯、聚己二酸-1,4-丁二醇酯二醇等为原料制备了水性聚氨酯乳液,并以接枝剂甲基丙烯酸羟乙酯改性制备了体育合成革用水性聚氨酯热熔胶,同时对其性能进行了测试表征。结果发现,随着接枝剂甲基丙烯酸羟乙酯用量的增加,体育用品合成革用水性聚氨酯热熔胶拉伸强度与断裂伸长率随之增大,剥离强度与剪切强度逐步增大,水接触角逐渐增大,而吸水率明显下降,表明接枝剂甲基丙烯酸羟乙酯的掺入,可有效改善水性聚氨酯热熔胶的机械性能、粘接性能,以及耐水性与疏水性。

体育器械用生物基水性聚氨酯合成革的力学性能研究

以天然可再生高分子材料为原料制备水性聚氨酯,不仅可缩减石油基多元醇用量,还可赋予水性聚氨酯可生物降解性。因此,为顺应绿色环保政策、优化体育器械功能性,本文以可降解植物油蓖麻油为原料,制备了生物基水性聚氨酯合成革,并对其力学性能进行了测试分析。结果发现,掺入蓖麻油的体育器械原料合成革用生物基水性聚氨酯乳液具备良好的稳定性。随着蓖麻油用量的增加,体育器械用水性聚氨酯合成革胶膜厚度逐渐缩小,透光率逐渐下降,附着力与柔韧性未发生变化,吸水率逐渐降低,水接触角先增后减,拉伸强度逐渐提高,断裂伸长率逐渐降低,弹性模量逐渐增大。以蓖麻油改性制备的体育器械用生物基水性聚氨酯合成革力学性能均可达到行业标准相关要求。

足球鞋用有机硅改性聚氨酯合成革的制备方法及防污性能研究

由于足球鞋用聚氨酯合成革表面易于沾水与沾污,且去污难度较大,极易影响足球鞋功能性与应用性。因此,以有机硅类化合物针对聚氨酯合成革进行防水防油防污整理以提高其防污性能势在必行。据此,本文以有机硅改性制备了足球鞋用防污聚氨酯合成革,并对其防污性能进行了测试表征。结果发现,相较于未改性聚氨酯合成革,有机硅改性聚氨酯合成革的水接触角较大,表面能较小,吸水率较低;相较于未改性聚氨酯合成革,有机硅改性聚氨酯合成革的口红、咖啡、油性笔等残留污渍较轻,且表面触感相对较好。可见,有机硅端羟基聚硅氧烷的掺入可赋予聚氨酯合成革优异的防污性能。

体育领域用超纤革制备及其性能研究

为改善体育领域用超纤革综合应用性能,提高超纤革手感与质感,本文以高收缩纤维切片与聚酰胺切片混合制备了体育领域用高收缩聚酯纤维超纤革基布与成革,并与聚酯纤维超纤革基布与成革进行了性能对比分析。结果发现,体育领域用高收缩聚酯纤维超纤革力学性能与卫生性能存在显著性差异;相比聚酯纤维超纤革基布,高收缩聚酯纤维超纤革基布纤维间孔径较小;相较于聚酯纤维超纤革,高收缩聚酯纤维超纤革纵向与横向断裂强力偏低,而纵向与横向断裂伸长率较大,柔软度更大,透气率和透湿率更高,吸水量更大,表明其力学性能相对较优,且卫生性能整体更佳。

运动鞋用水性聚氨酯超细纤维合成革贝斯的制备及性能研究

为了有效解决运动鞋制造领域用溶剂型聚氨酯浸渍制备超细纤维合成革贝斯的污染问题与溶剂残留超标问题,本文基于水性聚氨酯以水为介质,且环保、无毒、不燃、气味小等特性,以浸渍工艺制备了运动鞋用水性聚氨酯超细纤维合成革贝斯,并对其性能进行了测试表征。结果发现,随着水性聚氨酯含量的增加,浸渍合成革贝斯减量、厚度与表观密度皆显著增大,柔软度明显变差,吸水度与透气性先降低后升高,透水汽性变化不显著,拉伸强度与断裂伸长率变化不明显,撕裂强度减小;相较于溶剂型聚氨酯浸渍,水性聚氨酯浸渍超细纤维合成革贝斯减量率相对偏低,力学性能相对较差,厚度、表观密度、柔软度、吸水度、透气性及透水汽性皆显著提高;溶剂型聚氨酯浸渍超细纤维合成革贝斯表面纤维蓬松,手感良好,但孔洞较多,水性聚氨酯浸渍超细纤维合成革贝斯表面纤维呈束状,手感稍显粗糙,但孔洞较少,整体更显丰满。

塑胶跑道用超细纤维聚氨酯合成革的制备及性能测试

为改善塑胶跑道综合应用性能,优化超细纤维聚氨酯合成革物理机械性能,本文由聚氨酯树脂含浸无纺布制备了超细纤维聚氨酯合成革,并对其力学性能与卫生性能进行了测试表征。结果发现,随着聚氨酯浸渍率增加,超细纤维聚氨酯合成革基布表观密度增大,密实程度提高,而压缩弹性率先增加后减少;随着聚氨酯浸渍率增加,超细纤维聚氨酯合成革基布剥离强度逐渐升高,拉伸强度、断裂伸长率皆呈现先降低后升高再降低的曲线形态,而撕裂强度则表现为先降低后升高的态势;随着聚氨酯浸渍率增加,超细纤维聚氨酯合成革基布透气性与透水汽性持续性下降;超细纤维聚氨酯合成革基布的干擦与湿擦色牢度均可达到5,而于氢氧化钠溶液中不溶色,表明基布耐碱性良好。

超细纤维合成革透水汽性能的研究进展

超细纤维合成革(简称超纤革)是替代天然皮革的理想材料,但超纤革的透水汽性能与天然皮革相比仍存在差距,有待提升。文章概述了超纤革的制备过程,分析了超纤革的性能及其在透水汽性能方面的不足,并从超纤革的主要组分,即超纤革基布和聚氨酯树脂入手,探讨了超纤革透水汽性能研究的最新进展;总结了对超纤革基布的水解、增加活性基团和亲水剂等改性方法,阐述了对聚氨酯树脂的填料、接枝聚合和共混等改性措施,探讨了对超纤革的后整理改性选项,最后提出了超纤革透水汽性能研究的未来发展方向。

熔纺双组分超细纤维成型工艺及其应用研究进展

熔纺双组分超细纤维由于其原料和成型技术的组合多样性而备受青睐。然而,在现有的制备工艺中,熔纺双组分超细纤维存在如能耗大、难以细旦化和污染环境等问题,限制了其在实际生产和高质应用领域的进一步发展。并且在实际的生产过程中,不同的原料选择、组件使用及工艺调控等因素都对熔纺双组分超细纤维成型效果影响显著。因此,合理调控熔纺双组分超细纤维成型过程中各阶段影响因素对其综合性能进一步提升具有重大意义。为更全面理解熔纺双组分超细纤维的本质,本文以桔瓣型纤维和海岛型纤维为研究基体,探究了熔纺双组分超细纤维的纺丝成型机理及其影响因素;阐述了熔纺双组分超细纤维多样的开纤工艺(机械开纤、化学开纤和热能开纤);归结了熔纺双组分超细纤维在合成革、空气过滤和医疗卫生等材料领域的应用;最后对熔纺双组分超细纤维广阔的发展前景进行了展望。

聚乳酸基水性聚氨酯的制备及其在合成革中的应用研究

以聚乳酸二元醇(PLA⁃OH)和六亚甲基二异氰酸酯(HDI)为原料,2,2⁃二羟甲基丁酸(DMBA)为亲水扩链剂合成了亲水扩链剂含量不同的聚乳酸(PLA)基水性聚氨酯(PLA⁃WPU)乳液,制备了PLA⁃WPU胶膜和超细纤维合成革。结果表明,随DMBA含量的增加,PLA⁃WPU乳液粒径减小、固含量增大,PLA⁃WPU超细纤维合成革拉伸强度和最大负荷增大,水接触角减小。当DMBA含量为5.5%时,PLA⁃WPU乳液固含量达到35.4%,粒径为196.37 nm,PLA⁃WPU超细纤维合成革的拉伸强度提高到29.9 MPa,约为超细纤维基布的1.7倍,水接触角降低到73°。

功能化水性聚氨酯超纤革的制备研究进展

聚氨酯因其综合性能优异,被广泛应用于皮革、合成革、纺织等行业。然而传统的溶剂型聚氨酯存在有机溶剂挥发污染环境的问题,与可持续发展理念相悖。而且无溶剂型聚氨酯也因成本太高限制了其应用范围。因此,水性聚氨酯逐渐替代溶剂型聚氨酯并进一步实现高性能、高品质、功能化、多样化的合成革产品。本文从超纤革的制备和超纤革的功能化整理方面介绍超纤革的制备及应用研究进展。主要从基布、上浆、减量、染色4个方面阐述超纤革的制备,从纤维改性、聚氨酯改性以及超纤革功能化3个方面阐述超纤革的功能化整理,并对功能化水性聚氨酯超纤革目前发展存在的问题进行了总结以及对未来的发展趋势进行展望。

改善超纤革用非织造布力学性能的研究进展

力学性能作为超纤革用非织造布的一项重要性能,决定了超纤革的应用范围。超纤革用非织造布大多以海岛短纤或橘瓣长丝超细纤维为原料,经针刺或水刺加固等工序制备而成。文章主要从纤维原料、针刺工艺与水刺工艺3方面因素出发,分析纤维强度与断裂伸长率、纤维线密度、纤维长度、纤维卷曲度、针刺密度、针刺深度与水刺压力对非织造布力学性能的影响规律,为增强超细纤维合成革用非织造布的力学性能提供参考。

HSPET/PA6中空橘瓣型纺粘针刺超纤合成革基布的制备及性能分析

以高收缩聚酯(HSPET)/聚酰胺6(PA6)纺粘长丝针刺非织造布为基布,含浸水性聚氨酯(WPU)制备HSPET/PA6中空橘瓣型纺粘针刺超纤革基布(以下简称HSPET/PA6针刺革基布)。对比分析前开纤法及后开纤法两种工艺,以及聚乙烯醇(PVA)和WPU含浸量对HSPET/PA6针刺革基布性能的影响。结果表明:在相同的PVA、WPU含浸量下,前开纤法的力学性能优于后开纤法,但柔软度及透气透湿性能与后开纤法相比较差;两种工艺下制备的HSPET/PA6针刺革基布力学性能均随着PVA含浸量的增加先提升后下降,随着WPU含浸量的增加逐渐提升;柔软度和透气透湿性能随着PVA含浸量的增加先提升后下降,随着WPU含浸量的增加逐渐下降。

阻燃超细纤维合成革贝斯的制备及性能研究

为了解决添加型阻燃水性聚氨酯稳定性差的问题,以脂肪族多异氰酸酯、聚醚多元醇和阻燃含磷多元醇为原材料,通过预聚体法合成一系列具有阻燃性能的水性聚氨酯。将该阻燃水性聚氨酯应用于超细纤维合成革贝斯(超纤贝斯)的含浸工艺中,探讨其对超纤贝斯力学、品质、阻燃、热分解性能的影响。结果表明,随着含磷阻燃多元醇含量的增加,燃烧速率从115.00 mm/min降低至60.79 mm/min,极限氧指数从21.00%提高到24.20%。然后在超纤贝斯表面喷涂不同浓度的磷氮阻燃剂,经过测试发现,超纤贝斯在燃烧过程中出现自熄现象,极限氧指数提升到27.00%。与未经阻燃整理的超纤贝斯相比,经过阻燃整理超纤贝斯的热释放速率峰值、总释放热分别降低了42.29%,20.01%。通过扫描电镜和拉曼光谱分析可得,经过阻燃整理的炭层石墨化程度提高,结构更为致密,表明阻燃剂利用凝聚相阻燃机理发挥重要作用。