Phosphorus Containing Rubber Seed oil as a Flame Retardant Plasticizer for Polyvinyl Chloride

The application of phthalate plasticizers has been restricted around the world due to their poor migration and potential harm to the human body.Hence,producing functional bio-based plasticizers via exploiting clean and reusable resources meets the satisfaction of current demands.In this study,flame-retardant rubber seed oil-based plasticize(FRP)was prepared via epoxidation reaction and ring opening addition reactions,which was used as a flame-resistant plasticizer for polyvinyl chloride to replace petroleum-based phthalate plasticizer.When DOP was replaced with FRP,the torque of PVC blends increased from 11.4 to 18.4 N⋅m,the LOI value increased from 24.3%for PVC-FRP-0%to 33.1%for PVC-FRP-20.The THR value diminished from 39 MJ/m^(2)(pertaining to PVC-FRC-0)to 22 MJ/m^(2)Tg increased from 23°C to 47°C,the weight loss of plasticized PVC blends significantly reduced from 22.6%to 2.8%in leaching tests.The study provided a new way to prepare flame retardant plasticizer using rubber seed oil as raw material.

Synthesis and Characterization of Phenyl Camellia oleifera Seed Oil Ester Plasticizing PVC

Plasticizers are essential additives in the processing of polyvinyl chloride(PVC),with phthalate plasticizers being widely used.However,these conventional plasticizers have been shown to be harmful to human health and environmentally unfriendly,necessitating the exploration of eco-friendly bio-based alternatives.In this study,Camellia oleifera seed oil,a specialty resource in China,was utilized as a raw material and reacted with 4,4′-Methylenebis(N,N-diglycidylaniline)(AG-80)to synthesize Phenyl Camellia seed Oil Ester(PCSOE).PCSOE was employed as a plasticizer to prepare modified PVC films with varying concentrations,with the conventional plasticizer dioctyl phthalate(DOP)serving as a control.Experimental results demonstrate that PSCOE-plasticized PVC films exhibit enhanced hydrophilicity,tensile strength,and thermal stability compared to DOP-modified PVC films.The contact angle of PSCOE-plasticized PVC films ranges from 66.26°to 78.48°,which is generally lower than the contact angle of DOP-modified PVC films at 78.40°,indicating improved hydrophilicity due to the modification with PCSOE.The tensile strength of PSCOE-plasticized PVC films ranges from 17.73 to 20.17 MPa,all surpassing the value of 16.41 MPa for DOP-modified PVC films.Moreover,the temperatures corresponding to 5%,10%,and 50%weight loss for PVC samples modified with PCSOE are higher than those for DOP.Hence,PCSOE presents a viable alternative to DOP as a plasticizer for PVC materials.

纺膜参数对PVC中空纤维膜结构与性能的影响

以聚氯乙烯(PVC)和醋酸纤维素(CA)为膜材料,采用非溶剂致相分离(NIPS)法,通过改变纺膜参数制备了PVC中空纤维膜.结果表明:所制得的中空纤维膜具有致密皮层,断面为海绵孔与指状孔共存结构,纯水通量可达314 L/(m^(2)·h),BSA截留率可达95.0%,断裂强度22 MPa.此外,细中空纤维膜可在0.6 MPa压力以下稳定运行,并可对自来水中的有机物深度脱除49.30%.

裂纹-孔洞缺陷下PVC涂层织物类膜材的撕裂行为

膜结构节点和边界处往往需要通过膜面开孔来实现关键部位的连接,孔洞边缘的应力集中会影响膜面的撕裂行为。为探究聚氯乙烯(polyvinyl chloride,PVC)涂层织物类膜材中孔洞对裂纹扩展行为的影响,开展了含有裂纹-孔洞缺陷的PVC涂层织物类膜材的单轴拉伸试验,分析了裂纹扩展全过程和撕裂机理,提出了适用于含裂纹-孔洞多缺陷PVC涂层织物类膜材撕裂强度的预测模型,并验证了模型的适用性。研究结果表明:含裂纹-孔洞缺陷的PVC涂层织物类膜材在中心撕裂过程中存在裂纹端扩展和孔端再扩展两阶段;定义了裂纹端临界撕裂荷载、裂纹端峰值撕裂荷载、孔端临界撕裂荷载和孔端峰值撕裂荷载4项撕裂特征指标,以衡量含裂纹-孔洞缺陷膜材的抗撕裂性能;孔洞的存在导致试样在孔端再扩展阶段的承载力提升,但随着孔洞尺寸增大,孔端的承载力提升效应减弱,裂纹端峰值撕裂荷载逐渐变为控制试样破坏的极限荷载;所提出的二次函数-指数函数应力场模型能有效地预测膜材的裂纹端临界撕裂应力和孔端临界撕裂应力。

Plasticizing Effect of Camellia oleifera Seed-Oil-Based Plasticizer on PVC Material Modification

In this study,as the plasticizer,Camellia oleifera seed-oil-based cyclohexyl ester(COSOCE)was prepared by the reaction of cyclohexene oxide and refined C.oleifera seed oil(RCOSO)obtained by acidification hydrolysis after saponification.In addition,the structure of the target product was confirmed by Fourier transform infrared(FTIR)spectroscopy,nuclear magnetic resonance(NMR)spectroscopy,and Raman spectroscopy.COSOCE was used as plasticizer-modified polyvinyl chloride(PVC)membranes.The structure of the COSOCE-modified PVC membranes were characterized by Raman spectroscopy and scanning electron microscopy(SEM).The properties of the COSOCE-modified PVC membrane were characterized by contact angle measurements,universal testing machine,thermogravimetric analysis(TGA),and differential scanning calorimetry(DSC).The results revealed that(1)The COSOCE-modified PVC membranes exhibit a good microscopic morphology.Combined with energy-dispersive X-ray spectroscopy(EDS)and contact angle measurement results,the COSOCE-modified PVC membranes are confirmed to be a hydrophilic material.(2)The modified PVC membrane with 60%COSOCE exhibited the best mechanical properties.The tensile strength reached 23.56±2.94 MPa.(3)COSOCE-modified PVC material exhibited better thermal stability,with a loss rate of less than 75%at the end of the first decomposition stage.Compared with that of the dioctyl-phthalate(DOP)-modified PVC membrane,the initial decomposition temperature of PVC was increased by 1.17°C–8.17°C,and the residual rate was increased by 0.67%–5.75%.The carbon–carbon double bond in the COSOCE molecular structure can remove the free radicals generated during the degradation of PVC material and slow down the decomposition rate of PVC.In addition,the double bond can be cross-linked partially with the PVC molecular chain containing the conjugated polyene structure,thereby increasing the movement resistance of the PVC molecular chain segment.Hence,COSOCE can replace DOP as a PVC plasticizer.

Synergistic Modification of PVC with Nitrogen-Containing Heterocycle and Tung-Oil Based Derivative for Enhanced Heat Stabilization and Plasticization Behavior

The additives present in polyvinyl chloride(PVC)materials are the major source of organic by-products during PVC degradation.The thermal stabilizer and plasticizer are the main additives that endow PVC with the required properties during its processing.However,these two additives easily migrate when samples are obtained by physical mixing of the additives with PVC.This causes the reduction of PVC sample efficacy and the increase in the formation of organic by-products in the radiolysis process.In this work,two kinds of grafted PVC samples(tungoil derivative grafted PVC and Atz grafted PVC,abbreviated as P-GT4 and P-AZ3)were synthesized by chemical grafting of 3-amino-1,2,4-triazole(Atz)and tung-oil derivative on PVC,respectively.These two PVC samples were then blended at different mass ratios to obtain hybrid PVC materials with excellent plasticization,thermal stability and migration resistance ability.Differential scanning calorimetry(DSC),discoloration,Congo red test and thermogravimetric analysis(TGA)showed that when the mass ratio of P-GT4 to P-AZ3 in the mixed PVC resin was 1:3,the resulting P1:3-GT4-AZ3(P4)presented the best plasticization and thermal stability.The kinetics of thermal decomposition showed that the activation energy of P4 was much higher than that of the reference material[PVC/DOTP/CaSt2/ZnSt2,PVC/CZ41 for short]at mass lossα=20%and 80%.In addition,the leaching test showed that P4 material possessed excellent migration resistance ability.

加工型ACR的合成及在PVC中的应用

针对聚氯乙烯(PVC)/CaCO_(3)在混炼过程中存在的塑化困难、共混时间较长、不完全塑化等加工难点以及制品表面粗糙、无光泽等市场痛点,以叔十二烷基硫醇(TDDM)为链转移剂,设计并合成了一种加工型丙烯酸酯类共聚物(ACR-P)。探究了TDDM和ACR-P的添加量对PVC/CaCO_(3)/ACR-P复合材料力学性能、流变性能、微观形貌及塑化效果的影响。结果表明,随着TDDM添加量的增加,ACR-P特性黏度逐渐下降,PVC/CaCO_(3)/ACR-P复合材料的拉伸强度和储能模量明显提高,塑化时间大幅缩短,同时冲击强度略有增加。当TDDM添加质量分数为0.8%时,PVC/CaCO_(3)/ACR-P复合材料的拉伸强度达到52.79 MPa,与PVC/CaCO_(3)相比,提高了50.27%;塑化时间由71 s缩至32 s。ACR-P添加量的增加显著地影响了PVC/CaCO_(3)/ACR-P复合材料的力学性能和加工性能,当ACR-P添加量为10份时,复合材料的拉伸强度达到61.12 MPa,与PVC/CaCO_(3)相比,提高了87.6%;塑化时间由115 s缩至25 s。动态热机械分析测试显示PVC/ACR-P复合材料只有一个玻璃化转变峰,说明PVC树脂和ACR-P两相是一个相容体系。从扫描电子显微镜可以观察到PVC/CaCO_(3)复合材料中两相界面清晰,ACR-P的引入使复合材料的界面变得模糊,这表明复合材料的相容性得到改善,力学性能和加工性能得到提升。

Mo-MOF对软质PVC材料的阻燃及抑烟性能

采用熔融共混的方法将含钼离子的有机框架材料(Mo-MOF)添加到软质聚氯乙烯(PVC)材料中,利用极限氧指数(LOI)测试仪、NBS烟箱、锥形量热仪、拉伸强度测试仪等研究了材料的阻燃、抑烟及力学性能。测试结果表明,与软质PVC相比,当Mo-MOF的添加量为3%时,材料的LOI值由26.8%提高至30.3%,最大烟密度由918.5降低至471.2,总烟释放量(TSP)由25.23 m^(2)降低至12.02 m^(2),分别降低了48.7%及52.3%。此外,与PVC/MoO_(3)对比可知,当钼离子含量相同时,PVC/3%Mo-MOF材料的最大烟密度由774.0降低至471.2,TSP值由17.55 m^(2)降低至12.02 m^(2),分别降低了39.1%与31.5%。与MoO_(3)相比,Mo-MOF在PVC中的相容性及分散性更佳,在燃烧过程中形成了具有高比表面积的纳米级氧化钼,对PVC材料的阻燃及抑烟性能更佳。同时,随着Mo-MOF含量的增加,PVC材料的拉伸强度和断裂伸长率均得到了一定程度的提高。

Thermogravimetric characteristics and different kinetic models for medical waste composition containing polyvinyl chloride-transfusion tube

Thermogravimetric study of medical transfusion tube(MTT) waste containing polyvinyl chloride(PVC) was carried out using the thermogravimetric analyser(TGA) with N2, at different heating rates of 5, 10, 20, 30, 50 °C/min. The purpose is to obtain pyrolysis characteristics and kinetic parameters of medical waste. The experimental results indicate that the pyrolysis behavior of the MTT sample is in agreement with its main ingredient of PVC, appearing two stair stepping stages. The influence of the additives in MTT on pyrolysis behavior was also revealed, which could improve MTT pyrolysis at lower temperature in the first stage, and cause obvious unsmoothness and asymmetry of the second DTG peak. Four n-order kinetic models of Coats-Redfern, Ozawa, Kissinger and Freeman-carroll were used to get the kinetic parameters. Furthermore, a novel "two-step four-reaction model" was established to simulate the whole continuous process. The different methods and the kinetic parameters thus obtained were discussed and compared with each other in literatures. The reasons of deviation among kinetic values were tried to be elucidated. The new established model could more satisfactorily describe the pyrolysis process of MTT, being more mechanistic and conveniently serving for the engineering.

Preparation and Properties of Polyvinyl Chloride/Carbon Nanotubes Composite

Chemically functionalized carbon nanotubes were combined with PVC to enhance both toughness and strength by simply mixing long alkyl chain modified multi-wall carbon nanotubes (abbreviated as MWNTs) or Ester-functionalized soluble MWNTs (abbreviated as eMWNTs) with PVC in Tetrahydrofuran (THF)/Cyclohexanone (CH) solution to obtain good dispersity solution. The MWNTs modified with 1-Bromohexadecane can effectively increase the intermolecular force with PVC by hydrogen bond. The obtained nanocomposite has a regular shape with homogeneously dispersed particles. PVC/2 wt% eMWNTs has been proved to possess excellent thermal stability. The intermolecular force between eMWNTs and PVC endows the as-fabricated nanocomposite with enhanced toughness and strength, indicating that our method is promising for wide use in PVC/eMWNTs nanocomposition.

氯化石蜡/DOTP复合增塑体系在PVC中的应用

为得到低成本的PVC增塑剂配方,对氯化石蜡(CP-52)和对苯二甲酸二辛酯(DOTP)在聚氯乙烯(PVC)中的协同增塑性能进行研究,对比氯化石蜡复配前后,PVC制片的性能变化,包括热稳定性能、耐热老化性能、力学性能和增塑剂的耐迁移性能。结果表明,由于氯化石蜡具有耐挥发和阻燃性较好的特点,CP-52/DOTP复合增塑体系增塑的PVC制片具有较好的热稳定性能,其耐热老化性能和耐挥发性能均提高。另外,复配氯化石蜡后,可以显著提高PVC制片的力学性能,当复配比例为40%时,断裂伸长率和拉伸强度提高最显著,分别为0-CP-52/DOTP试片的1.92倍和2.28倍。复配氯化石蜡后,对PVC制片的耐迁移性能也有提高,在无水乙醇和石油醚中,当复配比例为50%时,PVC制片的质量损失率分别降低了6.87%和17.16%(6 h)。在食品模拟液中的耐迁移性能也得到提升,在正己烷中,当复配比例为50%时,PVC制片的质量损失率降低了14.97%。最后,对CP-52/DOTP复合增塑体系提出对应的增塑机理。

丙烯酸酯接枝共聚PVC树脂在PVC加工领域的应用

介绍了一种新型丙烯酸酯类接枝共聚PVC树脂(AGR树脂)增韧的机制、优势及在PVC加工领域中的应用。

Linear extrapolation for prediction of tensile creep compliance of polyvinyl chloride

The universal creep equation is successful in relating the creep （ε） to the aging time （te）, coefficient of retardation time （β）, and intrinsic time （t0）. This relation was used to treat the creep experimental data for polyvinyl chloride （PVC） specimens at a given stress and different aging times. The βgs found by the “polynomial fitting” method in this work instead of the “middle-point” method reported in the literature. The unified master line was constructed with the treated data and curves according to the universal equation. The master line can be used to predict the long-term creep behavior and lifetime by extrapolating.

聚乙烯蜡对硬质PVC塑化性能的影响

采用转矩流变仪研究了2种聚乙烯蜡(聚合级聚乙烯蜡和副产蜡)用量对硬质聚氯乙烯(PVC)塑化性能的影响,并分析在一定加工温度、转速下,聚乙烯蜡的种类和用量与硬质PVC最小转矩、凝胶化转矩、熔体转矩和塑化时间的关系,为硬质PVC润滑剂配方设计提供试验参数。结果表明:2种聚乙烯蜡在丙烯酸酯类树脂(ACR)增韧硬质PVC和氯化聚乙烯(CPE)增韧硬质PVC 2个配方体系中使用时均具有较好的效果,可以有效降低硬质PVC制品加工过程中的最小转矩、凝胶化转矩和熔体转矩,同时导致塑化时间延长,表现出典型的外润滑剂效果。用户可以根据聚合级聚乙烯蜡和副产蜡的加工温度和用量对硬质PVC塑化性能的影响,设计出最佳的试验配方。

新型氢化二聚酸乙二醇醚酯的合成及其增塑PVC性能

以氢化二聚酸和乙二醇醚(乙二醇甲醚、二乙二醇甲醚、三乙二醇甲醚、四乙二醇甲醚)为原料,通过直接酯化法,制备出具有不同乙氧基官能团数目的新型氢化二聚酸乙二醇醚酯(HDA-2n,n=1,2,3,4)增塑剂。利用^(1)H NMR、^(13)C NMR和FTIR确定产物结构,并对HDA-2n增塑后聚氯乙烯(PVC)制品的微观形貌、力学、热稳定、耐迁移、耐挥发等性能进行表征分析。结果表明,HDA-2n的增塑性能随着乙氧基官能团数目的增加而提高;与邻苯二甲酸二辛酯(DOP)增塑后的PVC制品相比,含有乙氧基官能团数目最多的氢化二聚酸(四乙二醇甲醚)酯(HDA-8)增塑PVC后制品的断裂伸长率提高125%,拉伸强度提高11.29MPa,在正己烷中的迁移性降低了14.25%,70℃下的挥发性降低了5.29%,初始热分解温度(T_(5%))提高了27.2℃。

多功能植物油基增塑剂制备及增塑PVC研究进展

植物油基增塑剂因具有原料来源广、结构可调、增塑性能优良、无毒和可生物降解等优点,被认为是最具应用前景的生物基环保增塑剂。然而,植物油基增塑剂结构中长链烷基比例过高,导致其与聚氯乙烯(PVC)相容性较差,通常作为辅助增塑剂使用,应用价值未得到有力彰显。近年来,国内外学者对植物油基增塑结构进行化学改性,开发了系列多功能植物油基增塑剂(如增容、耐热、阻燃、耐迁移等),实现了植物油基增塑剂的“提质增效”。该文从植物油分子结构设计出发,通过分子模拟、微观和宏观分析手段相结合的方式对植物油基增塑剂的改性研究进行归纳、分析和总结,建立了增塑剂结构和增塑后PVC制品性能的“构效”关系,旨在为高性能、多功能植物油基增塑剂的结构设计和工业化生产提供理论依据。

Fire's effect on chloride ingress related durability of concrete structure

This paper describes the effects of fire on durability of reinforced concrete structures, and points out that fire not only damages the chemical composition and physical structure of concrete by high temperature, but also leads to an additional risk due to the generation of polyvinyl chloride (PVC) combustion gases. A mathematical model is proposed to calculate chloride ingress profiles in fire damaged concrete, so as to explore the service life prediction of the structure. Rapid Chloride Migration (RCM) test was carried out to determine the chloride diffusion coefficients for the application of the mathematical model. Finally, the detected results of a reported case testified to the validity of the mathematical model.

新型栲胶聚丙氧基醚酯的合成及增塑PVC性能

以工业级杨梅栲胶粗品为原料,通过环氧丙烷醚化和脂肪酸(乙酸、丁酸和油酸)直接酯化的方式,构建增塑性能高、抗迁移性能好的栲胶聚丙氧基醚酯增塑剂(TEPEA、TEPEB和TEPEO)。利用凝胶渗透色谱仪、核磁共振氢谱、傅里叶变换红外光谱对栲胶聚丙氧基多元醇和栲胶聚丙氧基醚酯的分子量和结构进行表征,并对栲胶聚丙氧基醚酯增塑剂增塑后聚氯乙烯(PVC)制品(PVC/TEPEA、PVC/TEPEB和PVC/TEPEO)的表观形貌、力学性能、耐低温性能、耐挥发性能和耐溶剂迁移性能进行测试。此外,通过合成低分子量栲胶聚丙氧基乙酸酯(LTEPEA),并将其增塑后的PVC制品(PVC/LTEPEA)与PVC/TEPEA、PVC/TEPEB和PVC/TEPEO进行综合性能差异比较,研究丙氧基对栲胶基增塑剂综合性能的影响。结果表明,栲胶聚丙氧基醚酯增塑后PVC制品的综合性能与其结构中丙氧基聚合度及酯基上的烷基碳链长度有关;丙氧基聚合度大且酯基上碳链最短的栲胶聚丙氧基乙酯(TEPEA)增塑后的PVC制品的增塑、耐挥发和抗迁移性能均优于传统石油基邻苯二甲酸二辛酯(DOP)增塑后的PVC制品(PVC/DOP),表明TEPEA可作为主增塑剂替代有毒的DOP。

环保型增塑剂在PVC加工中应用研究进展

本文概述了环保型增塑剂在聚氯乙烯(PVC)塑料加工中的应用研究进展情况,主要包括柠檬酸酯类增塑剂、环氧类增塑剂、聚酯类增塑剂等。环保及安全化已成为增塑剂行业发展的显著趋势,开发新型绿色环保增塑剂替代邻苯二甲酸酯成为行业研究重点,具有积极的环境、社会及经济效益。