Natural superabsorbent plastic materials based on a functionalized soy protein

A natural superabsorbent polymer (SAP) material based on an acylated soy protein was studied as a green alternative to non-biodegradable SAP. In order to obtain the natural SAPs, different amounts of succinic anhydride were used as acylating agent. Once the functionalized protein was obtained, it was mixed thoroughly with glycerol and then molded through a lab-scale injection molding device. Water uptake of samples obtained reached values much higher than those based on unacylated protein. Moreover, a greater extent of the acylation reaction led to higher water uptake values for the corresponding SAPs, probably related to their higher hydrophilic character. Water imbibing capacity measurements and thermogravimetrical analysis (TGA) seemed to confirm this. The presence of larger porous regions in acylated samples observed in SEM images could also play a role in their higher water uptake values.Furthermore, an increase in the extent of acylation reaction led to plastics with lower Young's modulus and higher extensibility.     

塑料镜片材料的发展动向

概述光学塑料的基本材料，讨论塑料镜片材料的主要品种及其应用，并着重分析影响塑料镜片材料性能的主要因素及其发展趋势。     

高效液相色谱法检测塑料食品接触材料中的双氰胺

建立了使用高效液相色谱法检测塑料食品接触材料中双氰胺的分析方法.采用4％乙酸提取样品、色谱柱分离、紫外检测器检测、外标法定量测定双氰胺残留.双氰胺在质量浓度为0.1 ～5.0 mg/L范围内线性良好,相关系数为0.9996.双氰胺的最低仪器检出限为5μg/L,方法的定量下限为0.40mg/kg,样品加标的回收率在94.4％ ～ 98.0％之间,相对标准偏差小于1.0％.该方法具有样品处理简单方便、灵敏度高、分析时间短等优点,可以满足塑料食品接触材料中双氰胺残留的测定,并为进出口塑料餐具中双氰胺残留量的检验提供依据.     

Polymer Multi-Block and Multi-Block+ Strategies for the Upcycling of Mixed Polyolefins and Other Plastics

Due to a continued rise in the production and use of plastic products, their end-of-life pollution has become a pressing global issue. One of the biggest challenges in plastics recycling is the separation of different polymers. Multi-block copolymers (MBCPs) represent an efficient strategy for the upcycling of mixed plastics via induced compatibilization, but this approach is limited by difficulties associated with synthesis and structural modification. In this contribution, several synthetic strategies are explored to prepare MBCPs with tunable microstructures, which were then used as compatibilizer additives to upcycle mixtures of polyolefins with other plastics. A multi-block⁺ strategy based on a reactive telechelic block copolymer platform was introduced, which enabled block extension during the in situ melt blending of mixed plastics, leading to better compatibilizing properties as well as better 3D printing capability. This strategy was also applicable to more complex ternary plastic blends. The polymer multi-block strategy enabled by versatile MBCPs synthesis and the multi-block⁺ strategy enabled by in situ block extension show exciting opportunities for the upcycling of mixed plastics.     

Intercomparison of slip flow velocity measurements of filled polymers by capillary extrusion rheometry

Slip flow can complicate both the measurement of the shear flow behaviour of polymers and the modelling of moulding processes. However, the understanding of the reliability of methods for measuring slip flow behaviour is limited. The results of an intercomparison on the measurement of slip flow behaviour by capillary extrusion rheometry of two polymer melts—a filled high-density polyethylene and a filled ethylene–vinyl acetate copolymer—are reported. Slip velocities were calculated, following the Mooney method, from the dependence of the shear stress–shear rate behaviour on the extrusion die diameter. Both compounds exhibited wall slip: in one case the slip velocity accounted for ≈80% of the total flow rate. Slip velocity results were typically within ≈±20% of the average values for the materials, although scatter up to ≈±40% was obtained for one material at high shear stresses. An analysis of slip velocity measurements indicated that uncertainties of 40–50% are typical (95% confidence level) although significantly higher uncertainties could result if testing conditions (primarily die diameters) are not optimised.