Reinforced Polyester(增强聚酯)研究综述
Reinforced Polyester 增强聚酯 - In this study, the neutron shielding capabilities of boron carbide (B4C)-reinforced polyester-matrix composite materials were investigated. [1] This study investigates the use of glass fiber-reinforced polyester (GRP) pipe powder (PP) for improving the bearing capacity of sandy soils. [2] This study presents the influence of fibre treatment and fibre loading on the mechanical, physical, crystalline, and thermal properties of pineapple leaf fibre (PALF) reinforced polyester (PE) composites. [3] This research examines the friction and dry wear behaviours of glass fibre-reinforced epoxy (GFRE) and glass fibre-reinforced polyester (GFRP) composites. [4] This work is to study the practical use of fly ash as a filler material in banana fiber-reinforced polyester (BFRP) composite. [5] Pineapple Leaf Fibre (PALF) Reinforced Polyester (PE) composites were fabricated by hand lay-up using randomly oriented PALF in PE matrix, compressed at 17 MPa by compression moulding. [6] This study aimed to investigate the antibiofouling activity of 3-(trimethoxysilyl)-propyl, alkyldimethylammonium chloride-based (SilQUAT)-treated glass fiber-reinforced polyester (GFRP) composite panels in model cooling tower system. [7]在这项研究中,研究了碳化硼(B4C)增强聚酯基复合材料的中子屏蔽能力。 [1] 本研究调查了使用玻璃纤维增强聚酯 (GRP) 管粉 (PP) 来提高沙土的承载能力。 [2] 本研究介绍了纤维处理和纤维负载对菠萝叶纤维 (PALF) 增强聚酯 (PE) 复合材料的机械、物理、结晶和热性能的影响。 [3] 本研究考察了玻璃纤维增强环氧树脂 (GFRE) 和玻璃纤维增强聚酯 (GFRP) 复合材料的摩擦和干磨损行为。 [4] 本工作旨在研究粉煤灰作为填充材料在香蕉纤维增强聚酯 (BFRP) 复合材料中的实际应用。 [5] 菠萝叶纤维 (PALF) 增强聚酯 (PE) 复合材料是通过在 PE 基体中使用随机取向的 PALF 手工铺层制造的,通过压缩成型在 17MPa 下压缩。 [6] 本研究旨在研究 3-(三甲氧基甲硅烷基)-丙基、烷基二甲基氯化铵基 (SilQUAT) 处理的玻璃纤维增强聚酯 (GFRP) 复合板在模型冷却塔系统中的抗生物污损活性。 [7]
Fiber Reinforced Polyester 纤维增强聚酯
Glass fiber reinforced polyester (GFRP) composite materials are widely used in various applications. [1] The present research aims at analyzing the influence of abaca fiber reinforced polyester composite on the dynamic mechanical analysis (DMA). [2] This paper presents the effect of accelerated salt spray (fog) exposure on commercially glass fiber reinforced polyester composite to determine the durability of the material. [3] The aim of the research work reported in this article is to fabricate water hyacinth fiber reinforced polyester composites and characterize its mechanical properties. [4] The main purpose of this paper is to study the tensile and flexural properties of untreated and treated palymra natural fiber reinforced polyester composites. [5] Glass fiber reinforced polyester composite materials are widely used in various areas due to their high specific strength, low weight, excellent elasticity, high corrosion resistance, and high ther. [6] This paper examined the dry-sliding wear behaviour using a pin-on-disc type of wear arrangement on carbon fiber reinforced polyester (CFRP) composites, which were fabricated with the help of die-casting technique. [7] The use of Glass Fiber Reinforced Polyester (GFRP) pipes in the industry increased considerably in the past decades. [8] A Johnson cook model associated with a ductile damage law is used to predict the failure mechanism of a random chopped glass fiber reinforced polyester. [9] However, the characterization of impact behavior with different fiber orientation such as 30°/60°, 0/90°, 30°/−45°, and 45°/−45° woven sisal fiber reinforced polyester composite was not studied vigorously. [10] In this study, it was aimed to investigate the usability of compounds in inorganic structure and the effect of these compounds used in composites on the mechanical properties of composites in order to give fire retardant properties to glass fiber reinforced polyester composites (CTP). [11] Glass fiber reinforced polyester composites are economic and high-performance composite materialsthat has gained a wide range of applications. [12] This work is an attempt to study the tribological performance of using treated betelnut fiber reinforced polyester (T-BFRP) and a Teflon composite at dry contact conditions. [13] The objective of this study is to characterize the mechanical properties of a novel Acacia tortilis fiber reinforced polyester composite using experimental methods. [14] The aim of this research is to investigate the effect of alkaline concentration treatment conditions on tensile strength and flexural strength properties of banana fiber reinforced polyester resin composite. [15] Pultruded sandwich rods were up to 26% lighter with regard to typical monolithic glass fiber reinforced polyester rods. [16] The sandwiches have a special core of 20 mm and skins made out of different materials (glass fiber reinforced polyester, steel and aluminium) with a thickness of 3 mm. [17] From this study, it has been asserted that by using the caryota fiber reinforced polyester composites, the traditional synthetic fiber can be replaced especially in automobile sector. [18] The effects of varying fiber content and fiber length on the mechanical properties of the Cyperus pangorei fiber reinforced polyester composites (CPFCs) such as tensile, flexural, and impact properties were studied. [19] In this article, the jute fiber reinforced polyester composite is synthesized by alkaline treatments and the mechanical properties are evaluated. [20] In order to investigate the wear behavior and tooth damage of Madar and Bauhinia Racemosa fibers reinforced polyester, the composite gears were fabricated with varying the fiber weight percentages of 5%, 10%, 15% and 20%. [21] This article aims to optimize the drilling process parameters using an integrated approach of the central composite design (CCD), the technique for order of preference by similarity to ideal solution (TOPSIS) and response surface method (RSM) to reduce delamination in the marine grade glass fiber reinforced polyester (GFRP) drilling. [22] In this work, a comparative failure analysis of aluminum (AA8011/AA8011) and glass fiber reinforced polyester (GFRP/GFRP) based similar and dissimilar joints is presented. [23] In order to investigate the wear behavior and service life of Madar and Bauhinia Racemosa fibers reinforced polyester, the composite gears were fabricated with varying the fiber weight percentages of 5%, 10%, 15% and 20%. [24] This work addresses the erosion performance of waste copper slag filled jute fiber reinforced polyester composites. [25] The present work investigated the erosion behavior of chemically treated jute fiber reinforced polyester composite. [26] The present study consists of assessment of the mechanical characteristics of Banana and Jute Fiber reinforced Polyester Composites. [27] In this paper, short jute fiber reinforced polyester composites were prepared by varying the fiber loading (0–40 wt. [28]玻璃纤维增强聚酯(GFRP)复合材料广泛用于各种应用。 [1] 本研究旨在分析蕉麻纤维增强聚酯复合材料对动态力学分析 (DMA) 的影响。 [2] 本文介绍了加速盐雾(雾)暴露对商用玻璃纤维增强聚酯复合材料的影响,以确定材料的耐久性。 [3] 本文报道的研究工作的目的是制备水葫芦纤维增强聚酯复合材料并表征其力学性能。 [4] 本文的主要目的是研究未经处理和处理过的palymra天然纤维增强聚酯复合材料的拉伸和弯曲性能。 [5] 玻璃纤维增强聚酯复合材料具有比强度高、重量轻、弹性好、耐腐蚀性强等优点,被广泛应用于各个领域。 [6] 本文研究了在压铸技术的帮助下制造的碳纤维增强聚酯 (CFRP) 复合材料上使用销盘式磨损布置的干滑动磨损行为。 [7] 在过去的几十年中,玻璃纤维增强聚酯 (GFRP) 管道在行业中的使用显着增加。 [8] 与延性损伤定律相关的 Johnson Cook 模型用于预测随机短切玻璃纤维增强聚酯的失效机制。 [9] 然而,对于30°/60°、0/90°、30°/-45°和45°/-45°剑麻纤维增强聚酯复合材料等不同纤维取向的冲击行为表征并未得到大力研究。 [10] 在这项研究中,旨在研究无机结构化合物的可用性以及这些化合物用于复合材料中对复合材料机械性能的影响,以赋予玻璃纤维增强聚酯复合材料 (CTP) 阻燃性能。 [11] 玻璃纤维增强聚酯复合材料是一种经济、高性能的复合材料,得到了广泛的应用。 [12] 这项工作试图研究使用处理过的槟榔纤维增强聚酯 (T-BFRP) 和 Teflon 复合材料在干接触条件下的摩擦学性能。 [13] 本研究的目的是使用实验方法表征新型玉米花相思纤维增强聚酯复合材料的机械性能。 [14] 本研究的目的是研究碱浓度处理条件对香蕉纤维增强聚酯树脂复合材料拉伸强度和弯曲强度性能的影响。 [15] 与典型的单片玻璃纤维增强聚酯棒相比,拉挤三明治棒的重量减轻了 26%。 [16] 三明治有一个 20 毫米的特殊芯和由不同材料(玻璃纤维增强聚酯、钢和铝)制成的表皮,厚度为 3 毫米。 [17] 从这项研究中,有人断言,通过使用石蜡纤维增强聚酯复合材料,可以替代传统的合成纤维,尤其是在汽车领域。 [18] 研究了不同纤维含量和纤维长度对香附纤维增强聚酯复合材料 (CPFC) 的拉伸、弯曲和冲击性能等力学性能的影响。 [19] 本文通过碱处理合成了黄麻纤维增强聚酯复合材料,并对其力学性能进行了评价。 [20] 为了研究 Madar 和紫荆花纤维增强聚酯的磨损行为和齿损伤,在 5%、10%、15% 和 20% 的不同纤维重量百分比下制造了复合齿轮。 [21] 本文旨在使用中心复合设计 (CCD)、与理想解决方案相似度优先排序技术 (TOPSIS) 和响应面法 (RSM) 的综合方法优化钻井工艺参数,以减少海洋等级的分层玻璃纤维增强聚酯 (GFRP) 钻孔。 [22] 在这项工作中,提出了铝(AA8011/AA8011)和玻璃纤维增强聚酯(GFRP/GFRP)基相似和异种接头的比较失效分析。 [23] 为了研究 Madar 和紫荆花纤维增强聚酯的磨损行为和使用寿命,在 5%、10%、15% 和 20% 的不同纤维重量百分比下制造了复合齿轮。 [24] 这项工作解决了废铜渣填充黄麻纤维增强聚酯复合材料的侵蚀性能。 [25] nan [26] nan [27] nan [28]
Fibre Reinforced Polyester 纤维增强聚酯
The investigation and comparative analysis of Chopped Strand Mat Glass Fibre Reinforced Polyester (CSMGFRP) composite laminates was conducted. [1] Findings: The impact strength of coir fibre reinforced polyester composite depends mainly on the fabrication parameters such as fibre-polyester content, soaking time, concentration of soaking agent and adhesive interaction between the fibre and reinforcement. [2] Purpose The purpose of this study is to develop jute-glass hybrid fibre reinforced polyester-based bio-composites using an indigenously developed pultrusion set-up and to present a detailed discussion on their mechanical characterization. [3] This research investigated the Cone calorimetric analysis of the fire retardant properties of cow horn ash particles (CHAp) bio-additives and aluminium trihydrate (AH) in banana peduncle fibre reinforced polyester composites. [4] This paper presents the determination of tensile, flexural, and acoustical properties of short oil palm frond (OPF) fibre reinforced polyester composites and issues that have to be controlled in order to improve those properties. [5] The Banana fibre reinforced polyester composite material is prepared by adopting Hand Lay-up method subjected to a Tensile and Impact tests and the results are analysed. [6] This study presents the evaluation of the mechanical, physical and dynamic mechanical properties of luffa-banana fibre reinforced polyester hybrid composites. [7] In this study, our aim is to analyze the influence of fibre treatments and different fibre loading on mechanical, physical and chemical properties of pineapple leaf fibre reinforced polyester composites (PALF/PE). [8] In present work, the DMA of banana, pineapple leaf and glass fibre reinforced polyester composites i. [9] Based on the standards IEC 60060-1 (High-voltage test techniques) and IEC 60270 (High-voltage test techniques - Partial discharge -PD-measurements) tests were carried out on high voltage industrial frequency and lightning impulse on glass fibre reinforced polyester –GFRP-pole samples, in order to determine PD and breakdown voltage; contrasting with the results obtained by insulation coordination determining the suitability of the insulating material; the data obtained was processed and analyzed using MATLAB software, digital filters and the fast Fourier transform (FFT). [10] Based on the standards IEC 60060-1 (High-voltage test techniques) and IEC 60270 (High-voltage test techniques - Partial discharge -PD-measurements) tests were carried out on high voltage industrial frequency and lightning impulse on glass fibre reinforced polyester –GFRP-pole samples, in order to determine PD and breakdown voltage; contrasting with the results obtained by insulation coordination determining the suitability of the insulating material; the data obtained was processed and analyzed using MATLAB software, digital filters and the fast Fourier transform (FFT). [11] In this study, mechanical characteristics of Borassus flabellifer fruit fibre reinforced polyester composites with varying weight percentages of the carbonized eggshell bio-fillers were analyzed for its tensile, flexural and impact strength. [12] Short Phragmites Karka fibre reinforced polyester composites were fabricated using hand layup technique and tensile properties were evaluated. [13] In the present investigation ballistic performance of Kevlar29 fibre reinforced polyester composite (KPC) is analysed. [14] The samples of randomly oriented Roselle and Sisal fibre reinforced polyester composites were prepared for the laboratory tests. [15]对短切原丝毡玻璃纤维增强聚酯(CSMGFRP)复合层压板进行了调查和比较分析。 [1] 研究结果:椰壳纤维增强聚酯复合材料的冲击强度主要取决于 关于纤维-聚酯含量、浸泡时间、浓度等制造参数 纤维和增强材料之间的浸泡剂和粘合剂相互作用。 [2] 目的 本研究的目的是使用本地开发的拉挤成型装置开发黄麻玻璃混合纤维增强聚酯基生物复合材料,并对其机械特性进行详细讨论。 [3] 本研究调查了牛角灰颗粒 (CHAp) 生物添加剂和三水合铝 (AH) 在香蕉花梗纤维增强聚酯复合材料中的阻燃性能的锥形量热分析。 [4] 本文介绍了短油棕叶 (OPF) 纤维增强聚酯复合材料的拉伸、弯曲和声学性能的测定,以及为了改善这些性能而必须控制的问题。 [5] 采用手糊法制备香蕉纤维增强聚酯复合材料,进行拉伸和冲击试验,并对结果进行分析。 [6] 本研究对丝瓜络纤维增强聚酯杂化复合材料的力学、物理和动态力学性能进行了评估。 [7] 在本研究中,我们的目的是分析纤维处理和不同纤维负载对菠萝叶纤维增强聚酯复合材料 (PALF/PE) 的机械、物理和化学性能的影响。 [8] 在目前的工作中,香蕉、菠萝叶和玻璃纤维增强聚酯复合材料的 DMA i。 [9] 根据 IEC 60060-1(高压测试技术)和 IEC 60270(高压测试技术-局部放电-PD-测量)标准,对玻璃纤维增强聚酯的高压工业频率和雷电脉冲进行了测试—— GFRP-pole 样品,以确定 PD 和击穿电压;与通过绝缘配合获得的结果进行对比,确定绝缘材料的适用性;使用 MATLAB 软件、数字滤波器和快速傅里叶变换 (FFT) 对获得的数据进行处理和分析。 [10] 根据 IEC 60060-1(高压测试技术)和 IEC 60270(高压测试技术-局部放电-PD-测量)标准,对玻璃纤维增强聚酯的高压工业频率和雷电脉冲进行了测试—— GFRP-pole 样品,以确定 PD 和击穿电压;与通过绝缘配合获得的结果进行对比,确定绝缘材料的适用性;使用 MATLAB 软件、数字滤波器和快速傅里叶变换 (FFT) 对获得的数据进行处理和分析。 [11] 在这项研究中,分析了不同重量百分比的碳化蛋壳生物填料的Borassus flabellifer 水果纤维增强聚酯复合材料的拉伸、弯曲和冲击强度的力学特性。 [12] 短芦苇 Karka 纤维增强聚酯复合材料是使用手工铺层技术制造的,并评估了拉伸性能。 [13] 在本研究中,Kevlar29 纤维增强聚酯复合材料 (KPC) 的弹道性能进行了分析。 [14] nan [15]
Fabric Reinforced Polyester
To this end, three rotational and feed speeds and three BSD tool diameters were selected (L27) for drilling 155 g/m2 density jute fabric reinforced polyester biocomposites. [1] The present work deals with the mechanical characterization of a woven jute fabrics reinforced polyester resin composite. [2] All these repair procedures were conducted on the glass fabric reinforced polyester blades manufactured by Hand lay-up technique. [3] In particular, dynamic mechanical analysis (DMA) of fique fabric reinforced polyester matrix composites disclosed improved viscoelastic behavior in association with change in the glass transition temperature. [4]为此,选择了三种旋转和进给速度以及三种 BSD 工具直径 (L27) 用于钻孔 155 g/m2 密度黄麻织物增强聚酯生物复合材料。 [1] 目前的工作涉及机织黄麻织物增强聚酯树脂复合材料的机械特性。 [2] 所有这些修复程序都是在通过手糊技术制造的玻璃纤维增强聚酯刀片上进行的。 [3] 特别是,纤维织物增强聚酯基复合材料的动态力学分析 (DMA) 揭示了与玻璃化转变温度变化相关的改进的粘弹性行为。 [4]
Glas Reinforced Polyester
The technique was also able to highlight differences in performance between two different liners, pultruded glass reinforced polyester resin and a flexible glass fibre sheet, with the latter showing improved resistance. [1] For example, the tribological properties of polyester composites reinforced with woven glass reinforced polyester have been compared with seed oil palm reinforced polyester. [2] Hand lay-up technique was used for processing carbon; glass reinforced polyester resin composites (non-hybrid) and carbon-glass/polyester hybrid composites with various fiber configurations. [3]该技术还能够突出两种不同衬里(拉挤玻璃增强聚酯树脂和柔性玻璃纤维板)之间的性能差异,后者显示出更高的阻力。 [1] 例如,用编织玻璃增强聚酯增强的聚酯复合材料的摩擦学性能已与种子油棕增强聚酯进行了比较。 [2] 碳处理采用手糊工艺;玻璃增强聚酯树脂复合材料(非混合)和具有各种纤维配置的碳-玻璃/聚酯混合复合材料。 [3]
Fiberglas Reinforced Polyester
This article shows the results of the comparative analysis developed between a “conventional” transmission line supported on steel towers, and a compact line supported on fiberglass reinforced polyester poles (FRP), concerning its behavior against lightning-impact. [1] The first identified sources include epoxy resin, fiberglass reinforced polyester as well as PVC materials (pipes …). [2]本文展示了支撑在钢塔上的“传统”输电线路与支撑在玻璃纤维增强聚酯杆 (FRP) 上的紧凑型线路之间关于其抗雷击性能的比较分析结果。 [1] 第一个确定的来源包括环氧树脂、玻璃纤维增强聚酯以及 PVC 材料(管道……)。 [2]
reinforced polyester composite 增强聚酯复合材料
This research investigates the stress mechanics of reinforced polyester composites when exposure to a sudden impact force, using experimental and analytical methods based on impact and Linear Elastic Fracture Mechanics (LEFM) test procedures. [1] The present research aims at analyzing the influence of abaca fiber reinforced polyester composite on the dynamic mechanical analysis (DMA). [2] Wear studies are carried out using a pin-on-disc wear tester for treated sansevieria cylindrica fiber-reinforced polyester composites. [3] Therefore, this extension of the previous work presents additional results on Izod and tensile tests of 1 and 2 wt% CNC-reinforced polyester composites, together with a comparative cost analysis with fiberglass. [4] In the present work tensile, flexural, impact and hardness properties of Prosopis juliflora bark (PJb), jute fiber (JF) and kenaf fiber (KF) reinforced polyester composites are expressed for the first time. [5] This paper presents the effect of accelerated salt spray (fog) exposure on commercially glass fiber reinforced polyester composite to determine the durability of the material. [6] Findings: The impact strength of coir fibre reinforced polyester composite depends mainly on the fabrication parameters such as fibre-polyester content, soaking time, concentration of soaking agent and adhesive interaction between the fibre and reinforcement. [7] In this contribution, response surface methodology (RSM) was employed to investigate and optimize the effect of varied treatment factors (sodium hydroxide concentration (NaOH) and soaking time (ST)) of the alkali treatment of Ampelocissus cavicaulis natural fiber (ACNF) on the tensile strength (TS) of alkali treated ACNF reinforced polyester composite. [8] The aim of the research work reported in this article is to fabricate water hyacinth fiber reinforced polyester composites and characterize its mechanical properties. [9] The aim of this study is to explore thermal conductivity, specific heat capacity, and thermal diffusivity of Borassus fruit fiber (BFF) reinforced polyester composites. [10] This research investigated the Cone calorimetric analysis of the fire retardant properties of cow horn ash particles (CHAp) bio-additives and aluminium trihydrate (AH) in banana peduncle fibre reinforced polyester composites. [11] The main purpose of this paper is to study the tensile and flexural properties of untreated and treated palymra natural fiber reinforced polyester composites. [12] The mechanical properties of CNTs–GNPs reinforced polyester composite are lower than the composites reinforced only with CNTs. [13] Glass fiber reinforced polyester composite materials are widely used in various areas due to their high specific strength, low weight, excellent elasticity, high corrosion resistance, and high ther. [14] In this study, characterization processes have been done by synthesizing the nano-aerosil-reinforced polyester composite. [15] In the new trend of research on the fabrication of boat structure using natural fiber hybrid with kevlar/fiberglass-reinforced composite, the result of tensile, bending, and impact strength showed that glass fiber-reinforced polyester composite gave high strength with increasing glass fiber contents. [16] In the present study fiber hybrid (bamboo fiber and Musa acuminata stem fibers (MASF) were reinforced polyester composite, for enhancing mechanical properties. [17] In this study, the influence of hybridizing sisal on the wear behavior of coconut sheath (CS) fiber-reinforced polyester composites was investigated. [18] However, the characterization of impact behavior with different fiber orientation such as 30°/60°, 0/90°, 30°/−45°, and 45°/−45° woven sisal fiber reinforced polyester composite was not studied vigorously. [19] In this study, it was aimed to investigate the usability of compounds in inorganic structure and the effect of these compounds used in composites on the mechanical properties of composites in order to give fire retardant properties to glass fiber reinforced polyester composites (CTP). [20] Glass fiber reinforced polyester composites are economic and high-performance composite materialsthat has gained a wide range of applications. [21] This paper presents the determination of tensile, flexural, and acoustical properties of short oil palm frond (OPF) fibre reinforced polyester composites and issues that have to be controlled in order to improve those properties. [22] The objective of this study is to characterize the mechanical properties of a novel Acacia tortilis fiber reinforced polyester composite using experimental methods. [23] The main objective of the work was to develop cotton fiber-reinforced polyester composites (CFPCs) with different weight concentrations of fly-ash fillers using the hand layup compression molding process, and study the influence of different concentrations of fillers on the wear response of CFPCs under the effect of different operating parameters. [24] This work was conducted to study one pipe lining, namely the reinforced polyester composite, under artificial aging; this was done to provide a better understanding of the material’s performance under operating conditions, where it is regularly exposed to degrading factors such as heat and water. [25] The Banana fibre reinforced polyester composite material is prepared by adopting Hand Lay-up method subjected to a Tensile and Impact tests and the results are analysed. [26] This study has been conducted to investigate the flexural strength of Borassus Flabellifer Fiber/BFF reinforced polyester composite joint under static condition. [27] From this study, it has been asserted that by using the caryota fiber reinforced polyester composites, the traditional synthetic fiber can be replaced especially in automobile sector. [28] The results have shown that the two-parameter Weibull distribution describes the fatigue life probability distributions of jute-reinforced polyester composite material with highly significant statistical correlation coefficients. [29] The effects of varying fiber content and fiber length on the mechanical properties of the Cyperus pangorei fiber reinforced polyester composites (CPFCs) such as tensile, flexural, and impact properties were studied. [30] % fique fabric-reinforced polyester composite. [31] In this article, one of the most advanced generalized learning-based technologies, support vector machine (SVM) which could read the underlying unseen effect of input factors on response, is applied for regression model developing of drilling response—Fd on glass fiber-reinforced polyester composite. [32] ABSTRACT This study investigated the mechanical and wear properties of heat-treated pultruded kenaf fiber-reinforced polyester composites (PKFPCs) using pultrusion technique. [33] In this study, our aim is to analyze the influence of fibre treatments and different fibre loading on mechanical, physical and chemical properties of pineapple leaf fibre reinforced polyester composites (PALF/PE). [34] In this article, the jute fiber reinforced polyester composite is synthesized by alkaline treatments and the mechanical properties are evaluated. [35] In present work, the DMA of banana, pineapple leaf and glass fibre reinforced polyester composites i. [36] In the present work, an effort has been made to improve the mechanical properties of natural fiber-reinforced polyester composite using nanoclay. [37] Then the fiber is kept at room temperature up to 7 years and is used to fabricate hybrid sacred grass fiber-reinforced polyester composites that are characterized to assess mechanical properties and durability. [38] In this study, mechanical characteristics of Borassus flabellifer fruit fibre reinforced polyester composites with varying weight percentages of the carbonized eggshell bio-fillers were analyzed for its tensile, flexural and impact strength. [39] Short Phragmites Karka fibre reinforced polyester composites were fabricated using hand layup technique and tensile properties were evaluated. [40] In the present investigation ballistic performance of Kevlar29 fibre reinforced polyester composite (KPC) is analysed. [41] The present work is to study the mechanical properties of human hair-reinforced polyester composites with blast furnace slag variation. [42] This work addresses the erosion performance of waste copper slag filled jute fiber reinforced polyester composites. [43] ABSTRACT This paper investigated the tribological behavior of natural fiber-reinforced polyester composites. [44] The present work investigated the erosion behavior of chemically treated jute fiber reinforced polyester composite. [45] ABSTRACTThis paper depicts the mechanical behaviour of new class of multi-phase composites consisting of glass fibre-reinforced polyester composite filled with Al2O3 particles, Glass fibre-reinforc. [46] Aluminum wire mat reinforced polyester composite has been studied as an al-ternative structural material. [47] The present study consists of assessment of the mechanical characteristics of Banana and Jute Fiber reinforced Polyester Composites. [48] %) reinforced polyester composites. [49] In this paper, short jute fiber reinforced polyester composites were prepared by varying the fiber loading (0–40 wt. [50]本研究使用基于冲击和线性弹性断裂力学 (LEFM) 测试程序的实验和分析方法,研究增强聚酯复合材料在受到突然冲击力时的应力力学。 [1] 本研究旨在分析蕉麻纤维增强聚酯复合材料对动态力学分析 (DMA) 的影响。 [2] 磨损研究是使用针盘磨损测试仪对处理过的虎尾兰纤维增强聚酯复合材料进行的。 [3] 因此,对先前工作的扩展提供了 1 和 2 wt% CNC 增强聚酯复合材料的悬臂梁式和拉伸试验的额外结果,以及与玻璃纤维的比较成本分析。 [4] 在本研究中,首次表达了牧豆树皮(PJb)、黄麻纤维(JF)和红麻纤维(KF)增强聚酯复合材料的拉伸、弯曲、冲击和硬度性能。 [5] 本文介绍了加速盐雾(雾)暴露对商用玻璃纤维增强聚酯复合材料的影响,以确定材料的耐久性。 [6] 研究结果:椰壳纤维增强聚酯复合材料的冲击强度主要取决于 关于纤维-聚酯含量、浸泡时间、浓度等制造参数 纤维和增强材料之间的浸泡剂和粘合剂相互作用。 [7] 在这项贡献中,采用响应面法 (RSM) 来研究和优化不同处理因素(氢氧化钠浓度 (NaOH) 和浸泡时间 (ST)) 对酸橙天然纤维 (ACNF) 的碱处理对碱处理 ACNF 增强聚酯复合材料的拉伸强度 (TS)。 [8] 本文报道的研究工作的目的是制备水葫芦纤维增强聚酯复合材料并表征其力学性能。 [9] 本研究的目的是探索Borassus水果纤维(BFF)增强聚酯复合材料的导热性、比热容和热扩散率。 [10] 本研究调查了牛角灰颗粒 (CHAp) 生物添加剂和三水合铝 (AH) 在香蕉花梗纤维增强聚酯复合材料中的阻燃性能的锥形量热分析。 [11] 本文的主要目的是研究未经处理和处理过的palymra天然纤维增强聚酯复合材料的拉伸和弯曲性能。 [12] CNTs-GNPs 增强的聚酯复合材料的力学性能低于仅用 CNTs 增强的复合材料。 [13] 玻璃纤维增强聚酯复合材料具有比强度高、重量轻、弹性好、耐腐蚀性强等优点,被广泛应用于各个领域。 [14] 在这项研究中,通过合成纳米气溶胶增强的聚酯复合材料进行了表征过程。 [15] 在使用天然纤维混杂与凯夫拉尔/玻璃纤维增强复合材料制造船结构的研究新趋势中,拉伸、弯曲和冲击强度的结果表明,玻璃纤维增强聚酯复合材料随着玻璃纤维含量的增加而具有较高的强度. [16] 在本研究中,混合纤维(竹纤维和Musa acuminata 茎纤维(MASF)是增强的聚酯复合材料,用于提高机械性能。 [17] 在本研究中,研究了混杂剑麻对椰子鞘 (CS) 纤维增强聚酯复合材料磨损行为的影响。 [18] 然而,对于30°/60°、0/90°、30°/-45°和45°/-45°剑麻纤维增强聚酯复合材料等不同纤维取向的冲击行为表征并未得到大力研究。 [19] 在这项研究中,旨在研究无机结构化合物的可用性以及这些化合物用于复合材料中对复合材料机械性能的影响,以赋予玻璃纤维增强聚酯复合材料 (CTP) 阻燃性能。 [20] 玻璃纤维增强聚酯复合材料是一种经济、高性能的复合材料,得到了广泛的应用。 [21] 本文介绍了短油棕叶 (OPF) 纤维增强聚酯复合材料的拉伸、弯曲和声学性能的测定,以及为了改善这些性能而必须控制的问题。 [22] 本研究的目的是使用实验方法表征新型玉米花相思纤维增强聚酯复合材料的机械性能。 [23] 该工作的主要目的是利用手糊压塑工艺开发具有不同重量浓度粉煤灰填料的棉纤维增强聚酯复合材料 (CFPCs),并研究不同浓度填料对 CFPCs 磨损响应的影响。在不同操作参数的影响下。 [24] 本工作研究了人工老化下的一种管道内衬,即增强聚酯复合材料;这样做是为了更好地了解材料在操作条件下的性能,在操作条件下,它经常暴露于热和水等降解因素。 [25] 采用手糊法制备香蕉纤维增强聚酯复合材料,进行拉伸和冲击试验,并对结果进行分析。 [26] 本研究旨在调查Borassus Flabellifer Fiber/BFF增强聚酯复合材料接头在静态条件下的抗弯强度。 [27] 从这项研究中,有人断言,通过使用石蜡纤维增强聚酯复合材料,可以替代传统的合成纤维,尤其是在汽车领域。 [28] 结果表明,两参数威布尔分布描述了黄麻增强聚酯复合材料的疲劳寿命概率分布,具有显着的统计相关系数。 [29] 研究了不同纤维含量和纤维长度对香附纤维增强聚酯复合材料 (CPFC) 的拉伸、弯曲和冲击性能等力学性能的影响。 [30] % fique 织物增强聚酯复合材料。 [31] 在本文中,最先进的基于广义学习的技术之一,支持向量机(SVM),它可以读取输入因素对响应的潜在看不见的影响,应用于钻孔响应的回归模型开发——玻璃纤维增强的 Fd聚酯复合材料。 [32] 摘要 本研究采用拉挤成型技术研究了热处理拉挤红麻纤维增强聚酯复合材料 (PKFPCs) 的机械性能和磨损性能。 [33] 在本研究中,我们的目的是分析纤维处理和不同纤维负载对菠萝叶纤维增强聚酯复合材料 (PALF/PE) 的机械、物理和化学性能的影响。 [34] 本文通过碱处理合成了黄麻纤维增强聚酯复合材料,并对其力学性能进行了评价。 [35] 在目前的工作中,香蕉、菠萝叶和玻璃纤维增强聚酯复合材料的 DMA i。 [36] 在目前的工作中,已经努力提高使用纳米粘土的天然纤维增强聚酯复合材料的机械性能。 [37] 然后将纤维在室温下保存长达 7 年,并用于制造混合圣草纤维增强聚酯复合材料,以评估机械性能和耐久性。 [38] 在这项研究中,分析了不同重量百分比的碳化蛋壳生物填料的Borassus flabellifer 水果纤维增强聚酯复合材料的拉伸、弯曲和冲击强度的力学特性。 [39] 短芦苇 Karka 纤维增强聚酯复合材料是使用手工铺层技术制造的,并评估了拉伸性能。 [40] 在本研究中,Kevlar29 纤维增强聚酯复合材料 (KPC) 的弹道性能进行了分析。 [41] 目前的工作是研究人发增强聚酯复合材料随高炉渣变化的力学性能。 [42] 这项工作解决了废铜渣填充黄麻纤维增强聚酯复合材料的侵蚀性能。 [43] nan [44] nan [45] nan [46] nan [47] nan [48] nan [49] nan [50]
reinforced polyester resin 增强聚酯树脂
8% in the tensile strength at the 1% w/w composite compared to the unreinforced polyester resin. [1] The results from the study revealed that all the hybrid composites have improved properties over the unreinforced polyester resin and polyester sample reinforced with only wood charcoal at 5 wt% reinforcement concentration. [2] By incorporating varying percentages of waste fiberglass in bamboo mat, reinforced polyester resin panels the mechanical characteristics of the composites including tensile strength, hardness and flexural strength have been evaluated. [3] This study investigated the effect of adding kaolin micro-filler (KF) on the mechanical properties of Luffa Fiber (LCF) reinforced polyester resin. [4] The technique was also able to highlight differences in performance between two different liners, pultruded glass reinforced polyester resin and a flexible glass fibre sheet, with the latter showing improved resistance. [5] The aim of this research is to observe the acoustic performance of absorber-based biomass fiber-reinforced polyester resins that were experimentally associated with the design of tailed cavity resonator inclusion, i. [6] The present work deals with the mechanical characterization of a woven jute fabrics reinforced polyester resin composite. [7] The aim of this research is to investigate the effect of alkaline concentration treatment conditions on tensile strength and flexural strength properties of banana fiber reinforced polyester resin composite. [8] The present work deals with the three body abrasive wear behavior of sansevieria cylindrica fiber (SCF) and E-glass fiber (EGF) reinforced polyester resin (PR) composites. [9] Based on other research about empty fruit bunch (EFB), there is no research about empty fruit bunch reinforced polyester resin. [10] Hand lay-up technique was used for processing carbon; glass reinforced polyester resin composites (non-hybrid) and carbon-glass/polyester hybrid composites with various fiber configurations. [11]与未增强的聚酯树脂相比,1% w/w 复合材料的拉伸强度提高了 8%。 [1] 研究结果表明,所有混合复合材料的性能均优于未增强的聚酯树脂和仅用 5 wt% 增强浓度的木炭增强的聚酯样品。 [2] 通过在竹垫、增强聚酯树脂面板中加入不同百分比的废玻璃纤维,已经评估了复合材料的机械特性,包括拉伸强度、硬度和弯曲强度。 [3] 本研究调查了添加高岭土微填料 (KF) 对丝瓜纤维 (LCF) 增强聚酯树脂力学性能的影响。 [4] 该技术还能够突出两种不同衬里(拉挤玻璃增强聚酯树脂和柔性玻璃纤维板)之间的性能差异,后者显示出更高的阻力。 [5] 本研究的目的是观察基于吸声体的生物质纤维增强聚酯树脂的声学性能,这些树脂在实验上与尾腔谐振器夹杂物的设计相关,即。 [6] 目前的工作涉及机织黄麻织物增强聚酯树脂复合材料的机械特性。 [7] 本研究的目的是研究碱浓度处理条件对香蕉纤维增强聚酯树脂复合材料拉伸强度和弯曲强度性能的影响。 [8] 目前的工作涉及虎尾兰纤维 (SCF) 和 E 玻璃纤维 (EGF) 增强聚酯树脂 (PR) 复合材料的三体磨料磨损行为。 [9] 在其他空果串(EFB)研究的基础上,还没有关于空果串增强聚酯树脂的研究。 [10] 碳处理采用手糊工艺;玻璃增强聚酯树脂复合材料(非混合)和具有各种纤维配置的碳-玻璃/聚酯混合复合材料。 [11]
reinforced polyester hybrid
The mechanical attributes of coir fibre, rice husk and boiled egg shell are reinforced polyester hybrid composites were examined first time. [1] The present work is concentrated on coconut coir fiber and Rice husk reinforced polyester hybrid composites. [2] This study presents the evaluation of the mechanical, physical and dynamic mechanical properties of luffa-banana fibre reinforced polyester hybrid composites. [3] This chapter reviews recent work on natural fiber–reinforced polyester hybrid composites. [4] The comparative study reveals that the solar parabolic trough collector with its facets made of woven jute/glass fibre-reinforced polyester hybrid composite material yields γmax = 0. [5]首次研究了椰壳纤维、稻壳和煮鸡蛋壳增强聚酯杂化复合材料的力学性能。 [1] 目前的工作主要集中在椰子椰壳纤维和稻壳增强的聚酯杂化复合材料上。 [2] 本研究对丝瓜络纤维增强聚酯杂化复合材料的力学、物理和动态力学性能进行了评估。 [3] 本章回顾了最近关于天然纤维增强聚酯杂化复合材料的工作。 [4] 比较研究表明,太阳能抛物槽式集热器的刻面由编织黄麻/玻璃纤维增强聚酯混合复合材料制成,γmax=0。 [5]
reinforced polyester matrix
Functional and morphological characterization of wood charcoal/periwinkle shell (WC/PWS) particles hybrid reinforced polyester matrix composites was successfully developed. [1] In particular, dynamic mechanical analysis (DMA) of fique fabric reinforced polyester matrix composites disclosed improved viscoelastic behavior in association with change in the glass transition temperature. [2] The investigated test article consists of E-glass fibres (40% volume fraction) reinforced polyester matrix. [3] Both fique fabric and aligned fibers in amounts of 10, 20 and 30 vol% were used to reinforced polyester matrix composite. [4]成功开发了木炭/长春花壳(WC/PWS)颗粒杂化增强聚酯基复合材料的功能和形态表征。 [1] 特别是,纤维织物增强聚酯基复合材料的动态力学分析 (DMA) 揭示了与玻璃化转变温度变化相关的改进的粘弹性行为。 [2] 所研究的测试物品由 E 玻璃纤维(40% 体积分数)增强的聚酯基体组成。 [3] 10、20 和 30 vol% 的纤维织物和排列纤维均用于增强聚酯基复合材料。 [4]