膨胀型阻燃剂和有机蒙脱土协同阻燃聚丙烯的研究

采用熔融插层法制备了聚丙烯/膨胀型阻燃剂/有机蒙脱土（PP/IFR/OMMT）阻燃复合材料。探讨了OMMT对PP膨胀阻燃体系的影响,通过X射线衍射(XRD)、极限氧指数、热重分析(TG)、力学性能测试对阻燃复合材料的阻燃性、热稳定性及力学性能进行了研究。结果表明,PP高分子链插层进入OMMT层间,形成了插层型复合材料。OMMT与IFR具有明显的协同阻燃性。OMMT添加量为2份时,复合材料的极限氧指数达到31 %,较单独添加IFR时高出30 %;与纯PP相比,复合材料残炭率明显提高。随着OMMT含量的增加,复合材料的拉伸强度、弯曲强度和冲击强度均呈现先上升后下降的趋势,当OMMT含量为3份、IFR含量为22份时,复合材料的拉伸强度、弯曲强度和冲击强度达到最大值。     

无卤阻燃改性增强尼龙6性能的研究

采用自制的无卤阻燃剂（IFR）对30％玻纤增强尼龙6复合材料进行阻燃改性,研究了IFR的不同加入量对复合材料阻燃性能、力学性能以及热性能的影响。结果表明：当IFR加入量为25％时．阻燃复合材料的极限氧指数（LOI）达到31,阻燃级别为V-0级,而拉伸强度为78．86MPa,冲击强度为5．06kJ／m^2,材料综合性能比较优异。热重分析（TGA）数据表明,IFR的加入,改变了复合材料的热分解行为,改善了成炭效果。     

反应加工制备植物纤维增强聚乳酸复合材料的表征及性能研究

通过反应加工的方法,在制备剑麻纤维增强聚乳酸复合材料的过程中引入硫代磷酸三苯基异氰酸酯(TPTI)进行反应,实现纤维和聚乳酸之间的链接,以达到增强复合材料界面性能进而提升复合材料力学性能的目的。利用该方法制备了纤维质量分数为20%,不同含量TPTI的剑麻纤维增强聚乳酸复合材料,通过红外光谱、差示扫描量热仪(DSC)、扫描电镜(SEM)和力学测试研究TPTI的引入对复合材料微观结构和力学性能的影响。研究发现,当TPTI含量为0. 6%时复合材料的界面性能最好,此时力学性能也最佳,拉伸强度达到60. 38 MPa,弯曲强度达到89. 23 MPa,缺口冲击强度达到4. 32 k J/m~2,相比PLA/SF分别提高了31%、18. 4%和14. 7%。     

取向长剑麻纤维增强聚乳酸层压复合材料力学性能的研究

通过溶液浸渍法制备剑麻纤维预浸渍料,然后通过热压成型的方法制备了纤维含量(质量分数)分别为10%、20%、30%和40%的取向长剑麻纤维增强聚乳酸层压复合材料,同时制备了随机取向的短剑麻纤维增强聚乳酸复合材料。研究了不同的纤维含量对取向长剑麻纤维增强聚乳酸层压复合材料力学性能的影响。结果表明,当纤维含量为40%时,复合材料的力学性能最好。其拉伸强度、弯曲强度以及冲击强度比纯聚乳酸分别提高了1.90、1.29以及15.69倍,比短纤维剑麻纤维增强聚乳酸分别提高了4.47、2.27以及10.73倍,达到了164.76、202.88 MPa以及36.72 k J/m~2。     

香蕉纤维的表面改性及其增强环氧树脂复合材料的性能研究

采用硅烷偶联剂(A-174)偶联、高锰酸钾接枝和乙酰化包覆等3种方法对香蕉纤维进行表面改性,制备了改性香蕉纤维增强环氧树脂复合材料,测试其拉伸、弯曲、压缩、冲击等力学性能。结果表明,偶联、接枝、包覆等表面改性均能明显改善香蕉纤维与基体树脂的相容性,提高复合材料的力学性能,其中偶联改性的效果最好。当改性香蕉纤维含量为10wt%时,与未改性的香蕉纤维比较,复合材料的拉伸强度、弯曲强度、压缩强度分别提高了1.8、1.0、2.6倍;随着纤维含量的增加,复合材料的力学性能明显提高。     

剑麻纤维/玄武岩纤维混杂增强聚乳酸复合材料的力学性能研究

混杂纤维增强复合材料由于可以综合利用各种纤维的优点,极大地提高复合材料的性能,拓展复合材料的适用范围。采用剑麻纤维和玄武岩纤维混杂增强聚乳酸制备复合材料,研究了纤维含量和铺层顺序对混杂纤维复合材料力学性能的影响。结果表明,剑麻纤维作为芯层、玄武岩纤维作为表层时混杂复合材料具有较好力学性能。当纤维质量分数为40%时,其拉伸强度和冲击强度比纯聚乳酸分别提高了2.83倍、41.47倍,达到了267.29 MPa和183.46k J/m~2;纤维含量为30%时,其弯曲强度比纯聚乳酸提高4.07倍,达到354.16 MPa。     

麻纤维增强完全可降解复合材料的制备及性能研究

以亚麻落麻纤维、聚乳酸纤维为原料,采用非织造结合模压成型工艺制备了完全可降解复合材料.研究了增强纤维体积分数及纤维长度对复合材料弯曲、冲击性能的影响,采用扫描电镜(SEM)研究了复合材料中纤维与树脂之间的界面结合状况.结果表明:材料的弯曲、冲击强度均随纤维长度的增加而增大,当纤维长度为72mm时,体积分数为40%的材料具有最好的弯曲性能,纵横向弯曲强度分别为55.15、42.02MPa;体积分数为50%的材料具有最好的冲击性能,纵横向冲击强度分别为19.714、14.012kJ/m2;裁切断口处的SEM表明增强纤维与基体树脂之间存有一定数量的空隙,两相之间的界面结合强度有待进一步改善.     

废弃混纺纤维/聚乳酸复合材料的制备及力学性能研究

以废弃涤/棉(65/35)混纺纤维作为增强材料,聚乳酸颗粒作为基体材料制备复合材料,并且采用正交及单因素试验对其成型工艺进行优化。结果表明:最优成型工艺条件为涤/棉混纺纤维质量分数40%、热压温度180℃、热压压力12 MPa,该条件下的复合材料的拉伸强度和弯曲强度分别是59.56 MPa和48.75 MPa。     

喷嘴结构对FDM制备玻璃纤维增强聚乳酸复合材料性能的影响

研究了3D打印喷嘴流道直径、流道结构等对熔融沉积成型(FDM)制备的玻璃纤维增强聚乳酸复合材料性能的影响。结果表明,当直喷嘴直径为1 mm时,复合材料的拉伸强度和弯曲强度最大,分别为46、28.5 MPa;而发散型喷嘴直径为1 mm时,复合材料的拉伸强度和弯曲强度分别达到了48.5、32.5 MPa,后者比前者分别提高了7.78%和18.2%。偏光显微镜和扫描电子显微镜结果分析表明,发散型喷嘴保留了较长的玻璃纤维长度,并有利于纤维的取向。     

柔韧棉秆皮纤维/PLA复合材料的制备与性能

采用抄造与热压相结合的方法,制备了薄且柔韧的棉秆皮纤维/聚乳酸(PLA)复合材料。该复合材料是由聚乳酸包覆、填充的棉秆皮纤维网,具有较好的柔韧性。研究了棉秆皮纤维与聚乳酸质量比和热压时间对复合材料结构、拉伸性能和弯曲刚度的影响。结果表明,棉秆皮纤维与PLA质量比为1/1,热压15 min(温度190℃)为最佳条件。该条件制得的复合材料厚(0. 126±0. 006) mm,干、湿态下的拉伸强度分别为12. 15、4. 88 MPa,断裂伸长率分别为1. 55%、1. 5%,杨氏模量分别为1 126、508 MPa,弯曲刚度为0. 35 N·cm2/cm。该研究为纤维增强热塑性复合材料的制备方法提供了新的思路,也有利于提高废弃棉秆皮的利用率。     

含淀粉膨胀阻燃剂对聚丙烯的性能影响研究

采用淀粉与磷酸三聚氰胺复配成膨胀型阻燃剂,制备了膨胀阻燃聚丙烯(PP),利用热重分析法(TG)与差示扫描量热法(DSC)比较了纯PP和阻燃PP的热稳定性及成炭性,研究了阻燃剂对PP阻燃性能和力学性能的影响。结果表明,当阻燃剂用量为35份时,阻燃PP的拉伸强度为17.1 MPa,断裂伸长率为23.5%,弯曲弹性模量为1.62 GPa,弯曲强度为36.36 MPa,氧指数达到26%。     

壳聚糖改性聚乳酸的阻燃性能分析

为解决聚乳酸(PLA)易燃、熔滴等问题,以绿色天然高聚物壳聚糖为原料,采用甲磺酸、五氧化二磷、三聚氰胺对其改性,得到了一种绿色环保型阻燃剂———MPCS,与三聚氰胺聚磷酸盐(MPP)复配,形成了膨胀型阻燃剂(IFR)。将IFR、α-磷酸锆(α-ZrP)和PLA用转矩流动仪熔融共混制备了阻燃聚乳酸复合材料。采用傅立叶红外光谱(FT-IR)、X射线粉末衍射(XRD)对MPCS的结构进行了表征;用垂直燃烧法(UL-94)、锥形量热测试(CCT)、热重分析(TGA)及电子扫描电镜(SEM)研究了聚乳酸复合材料的阻燃性能及其阻燃机理。结果表明,当添加3%α-ZrP和22%IFR时,PLA复合材料的阻燃性能达到UL-94V-0级且无熔融滴落;由于α-ZrP具有片层阻隔作用和催化成炭作用,α-ZrP能提高PLA/IFR复合材料的阻燃效果,降低热释放量和烟密度。     

A novel lanthanum-based phosphorus-containing flame retardant agent and its application in polylactic acid

Currently, intumescent flame retardants (IFR) are often used in the flame retardant modification of polylactic acid (PLA). Due to the high loading, it will weaken the mechanical properties of PLA. In this study, lamellar lanthanum-based DOPO derivative (La@DDP) is prepared by solution method, and it acts as a flame retardant agent was added into PLA with IFR. The results show that PLA composite passes the UL94 V-0 rating with a limiting oxygen index (LOI) of 32.0, in the addition of 4.5 wt% IFR and 1.5 wt% La@DDP. Moreover, the peak heat release rate (PHRR) and total heat release (THR) of the PLA composite reduces by 31.0% and 23.2% compared to pure PLA, respectively. IFR/La@DDP agents assign the PLA composite with excellent thermal stability and carbon-forming ability. Through the analysis of residual char, the synergistic flame retardant mechanism between IFR and La@DDP in PLA composite is discussed. Notably, the tensile strength and elongation at break of the PLA composites are only reduced by 4.03% and 9.51% compared to pure PLA. This work provides a novel lanthanum-based flame retardant agent for designing PLA composites with good fire safety and mechanical properties, and it will broaden the application range of PLA.     

机械力改性芦苇纤维及其对聚乳酸复合材料的阻燃性能研究

采用机械力化学法对芦苇纤维（RF）进行磷酰化改性,并将改性后的磷酰化芦苇纤维（MPRF）与聚乳酸（PLA）共混制备复合材料,研究了MPRF对复合材料热稳定性、阻燃性、燃烧性能以及力学性能的影响。结果表明,磷元素成功接枝到芦苇纤维表面,800 ℃时的残余质量增加;随着MPRF添加量的提高,PLA复合材料的阻燃性能随着MPRF的加入而逐渐增加,当MPRF添加量为40 %（质量分数,下同）时,其弯曲强度和拉伸强度可达266.9 MPa和44.7 MPa,极限氧指数为24.6 %;最大热释放峰值下降到366.9 kW/m²,与PLA相比下降了39.3 %,有效降低复合材料的火灾危险性。     

Effect of polyethylene glycol on mechanical properties of bamboo fiber-reinforced polylactic acid composites

The bamboo fiber (BF)-reinforced polylactic acid (PLA) composites were prepared using the twin-screw extruder and injection molding. Thermal gravimetric analyzer results indicated the thermal stability of BF/PLA composites decreased with increasing BF content. Differential scanning calorimeter and X-ray diffraction curves showed that BF played a role as a nucleating agent, but the crystallinity of composite materials decreased with the increasing BF content. The melt flow rate of composites reduced with the increase in BF content, resulting in a poorer processing property. The processability of the composites was improved with the addition of high molecular polyethylene glycol (PEG). Mechanics performance test showed that tensile strength and bending strength of composites increased at low loading with the BF content increased then decreased when the loading continued to increase. The tensile strength of the composite materials reached 65.46 MPa when alkali-treated BF (ABF) content was 20 wt %. The flexural strength of the composites reached 97.94 MPa when ABF content was 10 wt %. Impact performance has also been improved. PEG-20000 was the best plasticizer among the PEG-6000,PEG-10000, and PEG-20000. When the component of PEG was 10 wt %, the elongation increased by 56%. The scanning electron microscopy (SEM) result showed that the fracture of the composites was smooth, most ABF were wrapped in matrix and distribution of ABF in PLA matrix was more uniform. It means that interfacial compatibility of bamboo fiber and PLA improved after BF modified by alkali. High molecular weight PEG enhance melt flow ability of polymer, result in fibers were further enclosed in the PLA matrix and increase properties of composites. © 2019 Wiley Periodicals, Inc. J. Appl. Polym. Sci. 2019 , 136, 47709.     

The intumescent flame‐retardant biocomposites of poly(lactic acid) containing surface‐coated ammonium polyphosphate and distiller's dried grains with solubles (DDGS)

This work aims to develop the poly(lactic acid) (PLA) biocomposites with high flame‐retardant performance, which can be applied in electronic and electrical devices as well as automotive parts. First, an intumescent flame retardant composed of ammonium polyphosphate (APP) as the acid source and the blowing agent, and the distiller's dried grains with solubles (DDGS) as the natural charring agent was designed. The surfaces of DDGS and APP were coated by degradable polymeric flame‐retardant resorcinol di(phenyl phosphate) (RDP), and the coating effects were analyzed. And then the flame‐retardant biocomposites of PLA with RDP‐coated DDGS (C‐DDGS) and RDP‐coated APP (C‐APP) were prepared. The limited oxygen index value of the biocomposites with loading of 15 wt% C‐DDGS and 15 wt% C‐APP reached 32.0%, and UL‐94 V‐0 was attained. The biocomposites also had good mechanical properties and the tensile strength of this sample reached about 57 MPa. Finally, the char residues after burning were analyzed and the flame‐retardant mechanism was discussed.     

Polylactic acid (PLA)/banana fiber (BF) biodegradable green composites

In this study, polylactic acid (PLA)/banana fiber (BF) composites were prepared by melt blending method. The BF was conjugated onto PLA chains through the use of a coupling agent and chemical modification. Consequently, the thermal stability and mechanical properties of the PLA were dramatically elevated through the incorporation of BF. Mechanical tests showed that the tensile and flexural strengths of the composites markedly increased with the fiber content, reaching 78.6 and 65.4 MPa when reinforced with 40 phr fiber, approximately 2 and 1.66 times higher, produced by pristine PLA. However, the impact strengths of composites are somewhat decreased with the increased content of fibers. The addition of 40 phr BF into the composite increased the HDT of pure PLA from 62 °C to 139 °C; an improvement of about 122%. Apart from enhancing the mechanical properties and thermal stability, the incorporation of BF can reduce the production cost of materials while meeting the demands of environmental protection agencies.     

Improvement of the flame retardancy of plasticized poly(lactic acid) by means of phosphorus‐based flame retardant fillers

The aim of this study is to improve the flame resistance and toughness of poly(lactic acid) (PLA) with the addition of low amount of flame retardant fillers and plasticizer simultaneously. Poly(ethylene glycol) (PEG) was used as plasticizer for PLA. Ammonium polyphosphate, boron phosphate, and tri‐phenyl phosphate (TPP) were used as flame retardant additives. Among these flame retardant additives, boron phosphate was synthesized from its raw materials by using microwave heating technique. Characterization of PLA/PEG‐based flame retardant composites was performed by conducting tensile, impact, differential scanning calorimeter, thermal gravimetric analysis, scanning electron microscope, limiting oxygen index, and UL‐94 vertical burning tests. Mechanical tests showed that the highest tensile strength, impact strength, and elongation at break values were obtained with the addition of ammonium polyphosphate and TPP into PLA/PEG matrix, respectively. Scanning electron microscopy analysis of the composites exhibited that the more homogeneous filler distribution in the matrix was observed for TPP containing composite. The best flame retardancy performance was also provided by TPP when compared with the other flame retardant additives in the plasticized PLA‐based composites.     

白炭黑改性膨胀阻燃剂对PP/POE燃烧及力学性能的影响

采用白炭(黑SiO2)作为协效阻燃剂,与膨胀阻燃(剂IFR)复配阻燃聚丙烯/乙烯-辛烯共聚物(PP/POE)复合材料,观察其用量对复合体系燃烧及力学性能的影响。结果表明:当SiO2/IFR/PP/POE为1/9/3.3/20时,体系的阻燃效果较好,垂直燃烧实验达到了UL 94 V-0级,拉伸强度提高很大,冲击强度略微降低,体系的综合性能最佳。