Simultaneously Enhancing the Fire Retardancy and Heat Resistance of Stereo-Complex-Type Polylactic Acid

Liu, Yanlin; Zhang, Xiuqin; Zhang, Jing; Dong, Zhou; Cui, Tongyan; Wang, Shuilian; Wang, Rui

doi:10.1021/acsomega.1c07025

Cited by 6 publications

(2 citation statements)

References 23 publications

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“…Introduction of SDS caused the PLA/PEG@SDS hybrid polymer system to show different degrees of decrease at different stages of T 5wt% , T 50wt% , and T 95wt% . Additionally, the decomposition temperature of this polymer decreased, indicating that SDS can reduce the thermal stability of PLA 32 …”

Section: Resultsmentioning

confidence: 99%

“…Additionally, the decomposition temperature of this polymer decreased, indicating that SDS can reduce the thermal stability of PLA. 32 Figure 2b shows the relationship between the angular frequency and the complex viscosity of PLA with increasing temperature, where a decrease in the viscosity of the composite is observed with increasing die temperature, which is characteristic of a "shear thinning" fluid. This trend can be ascribed to the fact that higher temperatures create more free volume in the macromolecule, which leads to higher motility and better flow of the melt.…”

Section: Resultsmentioning

confidence: 99%

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Preparation of PLA/PEG@SDS microfibers‐based nonwovens via melt‐blown process parameters: Wound dressings with enhanced water wetting performance

Wang

Zhang

Cao

et al. 2023

J of Applied Polymer Sci

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Polylactic acid (PLA) melt‐blown nonwovens are promising materials for medical and healthcare applications due to their properties such as softness, breathability, biodegradability, and biocompatibility. However, their widespread commercial application has been limited by their poor mechanical properties and insufficient hydrophilicity limit. To address these limitations, we prepared polylactic acid/polyethylene glycol@sodium dodecyl sulfate (PLA/PEG@SDS) microfibers‐based nonwovens using a melt‐blown process. The average fiber diameter of PLA/PEG@SDS microfibers nonwovens could be tuned from 1 to 13.9 μm by regulating the die temperature or hot air pressure. In addition, increasing the die temperature from 210°C to 225°C resulted in a 140.3% and 124.8% increase in the breaking resistance along the mechanical direction (MD) and transverse direction (CD), respectively. Meanwhile, the increase in the breaking resistance was observed between the hot air pressure and the mechanical strength of the PLA/PEG@SDS microfibers‐based nonwovens. Notably, the prepared samples exhibited a short wetting time of 3.438 s, a fast water absorption rate of 68.401%·s−1, and an excellent liquid water diffusion of 5.86 mm s−1. These results suggest that the PLA/PEG@SDS microfibers nonwovens prepared using melt‐blown process demonstrate efficient wetting performance, which paves the way for the industrial production of medical‐grade materials such as wound dressings.

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Section: Resultsmentioning

confidence: 99%

Section: Resultsmentioning

confidence: 99%

Preparation of PLA/PEG@SDS microfibers‐based nonwovens via melt‐blown process parameters: Wound dressings with enhanced water wetting performance

Wang

Zhang

Cao

et al. 2023

J of Applied Polymer Sci

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Improving fire safety of thermoplastic poly(ether ester) elastomer by black phosphorus nanosheets and aluminum diethylphosphinate system

Zhang,

Li,

Liu

et al. 2024

Vinyl Additive Technology

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Thermoplastic poly(ether ester) elastomer (TPEE) is a highly flammable material with severe melt‐dropping, which greatly limits its range of applications. Here, black phosphorus nanosheets (BPs) and aluminum diethylphosphinate (ADP) were used to improve the fire safety of TPEE for the first time. Results demonstrated that ADP/BPs as a synergistic combination exhibits good dispersity and excellent flame retardancy, also has minimal negative effects on the mechanical performances of the TPEE composites. By comparing TPEE/ADP‐22 and TPEE/ADP‐10/BPs‐4, the introduction of BPs significantly reduced the addition of ADP while keeping the material at the higher vertical burning grade, ~54.5% reduction in ADP usage. Compared with neat TPEE, TPEE/ADP‐10/BPs‐4 fulfilled V‐0 level, avoided dripping, and the limiting oxygen index value increased to 34.0%. Moreover, TPEE/ADP‐10/BPs‐4 performed the best in cone calorimetry test, both the peak heat release rate and total heat release reduced the largest, by 44.2% and 25.3%, respectively. The detailed studies of the flame‐retardant mechanism found that ADP/BPs showed the fire‐retardant impact of the condensed phase and gaseous phase. This work expands BPs in the flame‐retardant application and could facilitate to prepare the anti‐dripping flame‐resistant TPEE.Highlights BPs as an efficient flame retardant were added into TPEE for the first time. ADP/BPs as a synergistic combination has an excellent fire‐retardant effect. The introduction of BPs significantly reduced the addition of ADP. TPEE/ADP‐10/BPs‐4 showed the highest FPI and the lowest FGI. ADP/BPs has lowest negative effects on the mechanical performances of matrix.

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Synergistic effect of stereo-complexation and interfacial compatibility in ammonium polyphosphate grafted polylactic acid fibers for simultaneously improved toughness and flame retardancy

Zheng,

Li,

Chen

et al. 2024

International Journal of Biological Macromolecules

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Simultaneously Enhancing the Fire Retardancy and Heat Resistance of Stereo-Complex-Type Polylactic Acid

Cited by 6 publications

References 23 publications

Preparation of PLA/PEG@SDS microfibers‐based nonwovens via melt‐blown process parameters: Wound dressings with enhanced water wetting performance

Preparation of PLA/PEG@SDS microfibers‐based nonwovens via melt‐blown process parameters: Wound dressings with enhanced water wetting performance

Improving fire safety of thermoplastic poly(ether ester) elastomer by black phosphorus nanosheets and aluminum diethylphosphinate system

Synergistic effect of stereo-complexation and interfacial compatibility in ammonium polyphosphate grafted polylactic acid fibers for simultaneously improved toughness and flame retardancy

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