Experimental investigation on weak shock wave mitigation characteristics of flexible polyurethane foam and polyurea

In recent years,explosion shock wave has been considered as a signature injury of the current military conflicts.Although strong shock wave is lethal to the human body,weak shock wave can cause many more lasting consequences.To investigate the protection ability and characteristics of flexible materials and structures under weak shock wave loading,the blast wave produced by TNT explosive is loaded on the polyurethane foam with the density of 200.0 kg/m3(F-200)and 400.0 kg/m3(F-400),polyurea with the density of 1100.0 kg/m^(3)(P-1100)and structures composed of the two materials,which are intended for individual protection.Experimental results indicate that the shock wave is attenuated to weak pressure disturbance after interacting with the flexible materials which are not damaged.The shock wave protective capability of single-layer materials is dependent on their thickness,density and microscopic characteristics.The overpressure,maximum pressure rise rate and impulse of transmitted wave decrease exponentially with increase in sample thickness.For the same thickness,F-400 provides better protective capability than F-200 while P-1100 shows the best protective capability among the three materials.In this study,as the materials are not destroyed,F-200 with a thickness more than10.0 mm,F-400 with a thickness more than 4.0 mm,and P-1100 with a thickness more than 1.0 mm can attenuate the overpressure amplitude more than 90.0%.Further,multi-layer flexible composites are designed.Different layer layouts of designed structures and layer thickness of the single-layer materials can affect the protective performance.Within the research range,the structure in which polyurea is placed on the impact side shows the optimal shock wave protective performance,and the thicknesses of polyurea and polyurethane foam are 1.0 mm and 4.0 mm respectively.The overpressure attenuation rate reached maximum value of 93.3%and impulse attenuation capacity of this structure are better than those of single-layer polyurea and polyurethane foam with higher areal density.

Bio-Based Trivalent Phytate:A Novel Strategy for Enhancing Fire Performance of Rigid Polyurethane Foam Composites

Biomass phytic acid has potential flame retardant value as the main form of phosphorus in plant seeds.In this study,phytate-based flame retardants aluminum phytate(PA-Al)and iron phytate(PA-Fe)were synthesized and characterized.Subsequently,they were introduced into rigid polyurethane foam(RPUF)as flame retardants by one-step water-blown method.The results indicated that RPUF/PA-Fe30 exhibited the highest char residue of 22.1 wt%,significantly higher than 12.4 wt%of RPUF.Cone calorimetry analysis showed that the total heat release(THR)of RPUF/PA-Al30 decreased by 17.0%and total smoke release(TSR)decreased by 22.0%compared with pure RPUF,which were the lowest,demonstrating a low fire risk and good smoke suppression.Thermogravimetric analysis-Fourier transform infrared spectrometer(TG-FTIR)implied the release intensity of flammable gases(hydrocarbons,esters)and toxic gases(isocyanate,CO,aromatic compounds,HCN)of composites was significantly reduced after the addition of PA-Fe.The analysis of char residue indicated that the RPUF composites formed a dense char layer with a high degree of graphitization after the addition of PA-Al/PA-Fe,endowing RPUF composites with excellent mass&heat transmission inhibition effect and fire resistance in the combustion process.

基于光谱学分析的硬质聚氨酯泡沫/钢渣/次磷酸铝复合材料阻燃机理研究

硬质聚氨酯泡沫(RPUF)的优异性能使其在各领域被广泛应用,但本身的易燃性为其在应用过程中埋下了巨大的安全隐患。钢渣(SS)作为提炼铁精矿后排放的固体废弃物,因其综合利用效率低下而造成一系列环境污染问题。为提高RPUF火灾安全性和钢渣的附加值,将SS和次磷酸铝(AHP)引入到RPUF中,采用一步全水发泡法,制备一系列阻燃RPUF(FR-RPUF)复合材料。利用射线荧光光谱分析(XRF)探究了SS的化学成分,并系统研究了SS/AHP对FR-RPUF复合材料的微观形貌、热稳定性、阻燃性能以及气相产物的影响。XRF测试表明:钢渣的化学成分主要是CaO、SiO_(2)、Al_(2)O_(3)、Fe_(2)O_(3)、SO_(3)、MgO,以上金属氧化物能够作为协效剂促进聚合物成炭,并覆盖在材料表面阻隔燃烧热,在凝聚相达到阻燃目的。扫描电镜(SEM)测试表明:SS/AHP与RPUF基体的相容性较差导致FR-RPUF的泡孔出现不同程度的破损。阻燃测试表明:RPUF-1、RPUF-4、RPUF-5的极限氧指数分别为24.2 vol%、23.4 vol%、19.7 vol%,说明SS和AHP存在一定的协效阻燃作用,且RPUF/SS/AHP复合材料全部通过UL-94 V-0级别,满足外墙保温材料使用要求。热重-红外分析(TG-FTIR)测试表明:SS/AHP并未改变RPUF的降解过程,气相产物主要为碳氢化合物、羰基化合物、氨基甲酸酯、CO_(2)、异氰酸酯化合物、芳香族化合物、氰化氢、羰基化合物和酯类。对典型挥发性产物进一步分析发现,AHP和SS的加入促进RPUF基体早期降解。拉曼测试表明:当SS/AHP加入到RPUF后,RPUF-4的D峰与G峰的峰面积比(I_(D)/I_(G))值最小,表明SS/AHP的加入提高了FR-RPUF复合材料炭渣的致密性、石墨化程度。结合上述分析提出阻燃机理:首先AHP吸热分解,降低了火焰周围的温度,其分解的PO·自由基捕获游离的HO·抑制连锁反应,分解产生的焦磷酸铝与炭渣覆盖在基体表面,抑制了火焰和可燃气体的扩散。AHP分解产生的PH3遇氧气生成酸性物质(磷酸和聚磷酸),促进了RPUF脱水成炭,并且钢渣中的矿物成分会与磷酸或聚磷酸反应,形成致密炭层,与AHP共同发挥协效阻燃作用。研究为SS和AHP复配阻燃硬质聚氨酯泡沫材料提供理论依据和实验基础。

聚氨酯复合泡沫的制备以及应用前景展望

综述了聚氨酯复合泡沫的最新发展和突破。添加高性能纳米材料是目前研究聚氨酯泡沫方向的新趋势。聚氨酯复合泡沫的纳米添加剂包括碳纳米管、碳纤维、石墨烯、纳米金属单质、纳米金属氧化物和纳米金属合金材料等。主要综述了聚氨酯复合泡沫的类型、合成方法。此外,重点介绍了聚氨酯复合泡沫在吸波屏蔽、压阻传感、阻燃和减震阻尼等领域的前沿进展。

铜尾矿/聚磷酸铵阻燃聚氨酯的制备及研究

以聚磷酸铵(APP)/铜尾矿(CTS)为阻燃体系,采用一步全水发泡法制备硬质聚氨酯泡沫/聚磷酸铵/铜尾矿(RPUF/APP/CTS)复合材料。阻燃测试表明,RPUF-30APP的极限氧指数(LOI)达到24.0%,垂直燃烧测试达到V-0级别,其阻燃性明显提高。锥形量热测试表明,RPUF-30APP的热释放速率峰值(PHRR)由纯样的300.5 kW/m^(2)降低至139.4 kW/m^(2),下降幅度高达53.6%;总热释放(THR)由纯样的40.0 MJ/m^(2)下降至28.1 MJ/m^(2),降低幅度高达29.8%,表明APP/CTS体系明显降低复合材料燃烧过程中的热释放,其火灾安全性提高。炭渣分析表明,CTS/APP/RPUF复合材料燃烧过程中形成了致密的炭层,提高了复合材料的阻燃性能。该研究为CTS提供了一个新的应用领域,并为提高聚合物的防火安全性铺平了道路。

硬质聚氨酯泡沫/EG/MPP复合材料的制备及阻燃性能

将三聚氰胺聚磷酸盐(MPP)与可膨胀石墨(EG)进行复配,并采用一步法全水发泡法制备了硬质聚氨酯泡沫/可膨胀石墨/三聚氰胺聚磷酸盐(RPUF/EG/MPP)复合材料。在此基础上,采用热重分析(TG)、阻燃测试、微型量热(MCC)、扫描电镜(SEM)系统研究RPUF/EG/MPP复合材料的热稳定性、阻燃性、燃烧特性和炭渣微观形貌。研究表明,EG和MPP的加入可以明显提高RPUF/EG/MPP复合材料的热稳定性,40.6份MPP和20.3份EG的加入使得RPUF-2在800℃时,残炭率高达31.7%。阻燃测试表明,MPP和EG之间存在协效阻燃作用,其最大极限氧指数可达29.9%。微型量热测试表明,MPP和EG的加入可以有效降低RPUF复合材料燃烧过程中的热释放,提升其火灾安全性能。

水性脱模剂研究进展

近年来随着环保要求的提高,水性脱模剂逐渐成为现代工业生产的优选产品。对水性脱模剂的脱模机理、应用领域、制备方法及发展趋势进行了系统综述,重点阐述以树脂基复合材料型、水性混凝土型和聚氨酯发泡型为代表的水性脱模剂的制备和应用,并基于市场需求指出水性脱模剂的发展方向,以期为推动水性脱模剂的后期研发提供参考。

纤维含量对汽车内饰用夹层结构植物纤维增强PP复合材料性能的影响

分别以竹纤维(BF)/聚丙烯(PP)复合板、麻纤维(JF)/PP复合板为表层,聚氨酯(PUR)泡沫为芯层,经热压成型制备夹层结构植物纤维/PP复合材料,通过万能力学试验机、导热系数测定仪和驻波管吸声系数测试系统对不同纤维质量分数的夹层结构复合材料进行性能测试及表征。结果表明,PUR夹层结构BF/PP复合材料的力学性能与PUR夹层结构JF/PP复合材料接近,其导热系数≤0.044 W/(m·K),吸声性能良好,燃烧速度≤20.28 mm/min,满足主机厂对汽车内饰构件用材料的要求,且当植物纤维质量分数为40%时,PUR夹层结构植物纤维/PP复合材料的综合性能最佳。

基于改性竹粉/TPU复合发泡材料的制备及其发泡行为研究

以热塑性聚氨酯(TPU)为主基体,改性竹粉为填料,采用超临界发泡技术制备了鞋用TPU复合发泡材料。研究了不同改性竹粉含量对复合发泡材料形貌结构、热稳定性、熔体流动性、密度、发泡倍率的影响。结果表明,当添加改性竹粉后,复合发泡材料的微观泡孔形貌特征为闭孔结构;随着竹粉添加量的增加,并泡情况减少,孔径逐渐减小并逐渐趋于均一;在一定范围内,随着改性竹粉添加量的增加,复合材料的起始分解温度不变,熔点降低,熔融指数呈现上升趋势;当改性竹粉的添加量为5 phr时,复合发泡材料的密度最轻且达到0151 g/cm3,发泡倍率最大且达到855。

Durable flame-retardant,smoke-suppressant,and thermal-insulating biomass polyurethane foam enabled by a green bio-based system

Bio-based polyurethane foam has attracted increasing attentions due to eco-friendliness and fossil feedstock issues.However,the inherent flammability limits its application in different fields.Herein,we demonstrate a green bio-based flame-retardant system to fabricate polyurethane foam composite with durable flame retardancy,smoke suppression,and thermal insulation property.In this system,the green bio-based polyol(VED)with good reactivity and compatibility plays a role of flame retardant and EG acts as a synergistic filler.As a result,the LOI value of foam composite increased to 30.5 vol.%and it achieved a V-0 rating in the UL-94 vertical burning test.Additionally,the peak heat release rate(pHRR)and the total smoke production(TSP)decreased by 66.1%and 63.4%,respectively.Furthermore,the foam composite maintained durable flame retardancy after accelerated thermal aging test,whose thermal-insulating property was maintained even after being treated in high-humidity environment with 85%R.H.for a week.This work provides a facile strategy for durable flame retardancy and long-term thermal insulation performance,and creates opportunities for the practical applications of bio-based foam composites.

Polyurethane foam-supported three-dimensional interconnected graphene nanosheets network encapsulated in polydimethylsiloxane to achieve significant thermal conductivity enhancement

Polyurethane(PU)foams are widely used in thermal management materials due to their good flexibility.However,their low thermal conductivity limits the efficiency.To address this issue,we developed a new method to produce tannic acid(TA)-modified graphene nanosheets(GTs)-encapsulated PU(PU@GT)foams using the soft template microstructure and a facile layer-by-layer(L-B-L)assembly method.The resulting PU@GT scaffolds have ordered and tightly stacked GTs layers that act as three-dimensional(3D)highly interconnected thermal networks.These networks are further infiltrated with polydimethylsiloxane(PDMS).The through-plane thermal conductivity of the polymer composite reaches 1.58 W·m^(−1)·K^(−1) at a low filler loading of 7.9 wt.%,which is 1115%higher than that of the polymer matrix.Moreover,the mechanical property of the composite is~2 times higher than that of the polymer matrix while preserving good flexibility of the polymer matrix owing to the retention of the PU foam template and the construction of a stable 3D graphene network.This work presents a facile and scalable production approach to fabricate lightweight PU@GT/PDMS polymer composites with excellent thermal and mechanical performance,which implies a promising future in thermal management systems of electronic devices.

硬质聚氨酯泡沫材料制备与成型工艺的研究进展

硬质聚氨酯泡沫材料凭借其优秀的理化性能和机械性能,广泛应用于国民生产和国防军工等多个领域,具有不可替代的重要作用。同时,随着材料成型技术的进步,又发展出一些性能增强的新型硬质聚氨酯复合材料。本文综述了硬质聚氨酯泡沫材料的原料体系、成型工艺及阻燃聚氨酯泡沫、材料增强方法的最近研究进展,详细分析了异氰酸酯、多元醇和多种纤维和粒子增强材料对硬质聚氨酯泡沫性能的增强机理及影响规律。最后,对硬质聚氨酯泡沫材料的未来研究和发展方向进行了展望。

MPP阻燃硬质聚氨酯泡沫制备工艺

通过全水发泡技术制备硬质聚氨酯泡沫/三聚氰胺聚磷酸盐(RPUF/MPP)复合材料,并对其泡孔形貌、热稳定性、阻燃性能、烟释放特性进行研究,结果表明,RPUF/MPP复合材料初始分解温度与纯样相比,升高了18~26℃,热稳定性明显提升;50份MPP使复合材料极限氧指数达到24.4%,垂直燃烧达到UL 94 V-0级。RPUF/MPP50热释放速率峰值和总热释放仅为139 W/g和16.7 kJ/g,与纯样相比,分别降低了32.5%和28.3%。经过MPP改性,RPUF/MPP50最大烟密度及烟密度等级分别降低至32.10%和19.56。炭渣分析表明,MPP可以有效促进RPUF/MPP复合材料燃烧过程中致密炭层的形成,且炭层中石墨化成分比例明显提高,有利于其阻燃性能的提升。研究表明,MPP可以显著提升硬质聚氨酯泡沫火灾安全性能。

聚氨酯泡沫填充碳纤维三向织物复合材料薄壁管的吸能特性研究

本文对聚氨酯泡沫填充的碳纤维三向编织管进行吸能性能研究,采用准静态轴压的试验方法研究了三向编织管的破坏模式及不同经纬纱的叠层配比对复合管耐压性的影响,通过对压缩过程、经纬纱受力及破坏形貌的观察,分析经纬纱在吸能过程中的作用,并引入权重评价分析。结果发现:纬纱的增多可以显著提高总吸能与比吸能,但载荷效率明显下降;经纱增多可以提供横向束缚,且可以延长三向编织管的压缩行程,但比吸能有不同程度下降。不同经纬纱配比对交织点处破坏模式有着显著影响,其中C_(2)C_(2)与C_(3)C_(2)交织点几乎不参与压缩破坏;C_(2)C_(4)与C_(3)C_(4)参与破坏程度更高,且C_(3)C_(4)有着更为稳定的变形失效过程。

三维针织/机织聚氨酯基复合材料的力学性能

为解决间隔织物增强复合材料存在强度低、抗压性差的问题,选用经编间隔织物和玻璃纤维机织物作为增强体,聚氨酯泡沫作为基体,制备系列三维针织/机织聚氨酯基复合材料,并测试材料的拉伸、弯曲和压缩性能。结果表明:将经编间隔织物/玻璃纤维机织物以三维夹芯结构形式嵌入复合材料中,能够提高间隔织物增强复合材料的拉伸性能和压缩性能;在表面组织结构相同的情况下,经编间隔织物厚度大的三维针织/机织聚氨酯基复合材料的力学性能较好;在织物厚度相同的情况下,填充大六角形网孔的间隔织物的复合材料具有较好的力学性能。

阻燃硬质聚氨酯泡沫/羟基化氮化硼纳米复合材料的制备与性能

采用超声辅助液相剥离法成功制备了羟基化氮化硼纳米片(BNNS),并与聚醚多元醇(PMPO)分子链原位结合,制备了阻燃硬质聚氨酯泡沫/氮化硼纳米导热复合材料。结果显示,该方法制备的BNNS片层薄且表面含有较多官能团。相比未剥离的h-BN,羟基化BNNS改善了聚氨酯泡沫的微观孔隙结构。随着BNNS含量增加,复合材料的压缩强度先升高后逐渐降低。在0.5%~1%范围内,复合材料表现出最佳的热稳定性和协同阻燃性能。当BNNS含量为1.5%时,RPUF/BNNS复合材料的热导率提高了186.2%,达到0.063 W/(m·K)。

PUF复合材料裂纹的影响因素研究

大尺寸聚氨酯泡沫(PUF)复合材料成型过程中,易产生裂纹现象。通过PUF反应过程测试、模具发泡及线上工艺试验,系统研究了聚氨酯树脂配方、增强材料及主要成型工艺参数(速度、固化时间、固化温度等)对PUF复合材料产品裂纹的影响。研究表明:PUF复合材料成型过程产生的热应力和发泡压力过大,是产生裂纹现象的根本原因;调整聚氨酯填充系数为1.4~1.6,玻璃纤维质量分数45%~50%,固化时间60min,固化温度55℃,此条件下PUF复合材料成型工艺稳定,产品外观良好。

泡沫铝-聚氨酯复合结构的缓冲性能研究

研究了以泡沫铝为基体,以聚氨酯为增强体组合而成的泡沫铝-聚氨酯复合结构,其综合性能优于原组成材料而满足各种不同的要求。利用Ansys软件建立了泡沫铝-聚氨酯缓冲包装装置模型,通过分别填充体积比例为4.31%,8.04%及12.15%的泡沫铝,用Ansys对缓冲包装装置进行了应力分析,得到了装置各部分的变形情况,分析了装置的冲击吸振性能;仿真结果表明:在加速度达到7 800g时,该装置缓冲性能优于单体。

泡沫铝-聚氨酯复合材料的厚度对其缓冲性能的影响

采用泡沫铝填充量(体积分数)为12.15%的泡沫铝-聚氨酯复合材料,在7 800g的冲击加速度下,建立了3种厚度分别为6,8,12 mm的泡沫铝-聚氨酯的缓冲模型,用Ansys对各缓冲模型进行了应力分析,得到了各模型的变形情况,分析了不同厚度的缓冲模型的冲击吸振性能。结果表明:在一定厚度范围内,厚度越大,泡沫铝-聚氨酯复合结构模型受到冲击时产生的最大应力越大,最大变形量也越大。

混杂增强聚氨酯复合硬质泡沫塑料的研制

系统介绍混杂增强聚氨酯复合硬质泡沫塑料的制备情况,详细分析聚氨酯硬质泡沫塑料制备过程中的工艺问题,表征与分析其结构与性能,着重分析偶联剂对填充物增强性能的影响以及填充物含量对聚氨酯硬质泡沫塑料吸水性能的影响,介绍聚氨酯硬质泡沫塑料的应用,最后指出其发展前景。