Joint effects of rotational extrusion and TiO<sub>2</sub> on performance and antimicrobial properties of extruded polypropylene copolymer pipes

ACS Appl. Mater. Interfaces

Wang

2017

Self Cite

Electromechanical sensors are indispensable components in functional devices and robotics application. However, the fabrication of the sensors still maintains a challenging issue that high percolation threshold and easy failure of conductive network are derived from uniaxial orientation of conductive fillers in practical melt processing. Herein, we reported a facile fabrication method to prepare a multiaxial low-density polyethylene (LDPE)/carbon fibers (CFs) tube with bidirectional controllable electrical conductivity and sensitive strain-responsive performance via rotation extrusion technology. The multidimensional helical flow is confirmed in the reverse rotation extrusion, and the CFs readily respond to the flow field leading to a multiaxial orientation in the LDPE matrix. In contrast to uniaxial LDPE/CF composites, which perform a "head to head" conjunction, multiaxial-orientated CF networks exhibit a unique multilayer structure in which the CFs with distinct orientation direction intersect in the interface, endowing the LDPE/CF composites with a low percolation threshold (15 wt %) to those of the uniaxial ones (∼35 wt %). The angles between two axes play a vital role in determining the density of the conductive networks in the interface, which is predominant in tuning the bending-responsive behaviors with a gauge factor range from 12.5 to 56.3 and the corresponding linear respond region from ∼15 to ∼1%. Such a superior performance of conductive LDPE/CF tube confirms that the design of multiaxial orientation paves a novel way to facile fabrication of advanced cost-effective CF-based smart materials, shedding light on promising applications such as smart materials and intelligent engineering monitoring.

Section: Results and Discussionsupporting

confidence: 84%

Facile Fabrication of Electrically Conductive Low-Density Polyethylene/Carbon Fiber Tubes for Novel Smart Materials via Multiaxial Orientation

ACS Appl. Mater. Interfaces

Wang

2017

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“…A typical two-phase structure was identified in the four PPR samples, where the holes represented the removed amorphous ethylene−propylene rubber phase in the PPR matrix by the etchant. 37 Because of the dense "cross-hatched" lamellar morphology, the α-crystals can be etched slightly with faint appearance, while the exposed lamellae of the loosely stacked β-crystals are deeper after selective etching. 38 The two crystals showed distinguishing morphologies in the SEM images.…”

Section: ■ Results and Discussionmentioning

confidence: 99%

High-Value Recycling of Isotactic Polypropylene-Based Plastic Waste as a Crystallization Promoter for High-Performance Polypropylene Random Copolymers

Wang

ACS Sustainable Chem. Eng.

et al. 2022

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Highly efficient recycling of nonrenewable resources is increasingly important at the global concern of resource crisis and environmental issue. Here, a new strategy for value-added application of isotactic polypropylene (iPP)-based plastic waste as a crystallization promoter was proposed, and cigarette packaging film (CPF) waste as a typical single-component iPP was used as a representative example to demonstrate the successful application. First, the CPF wastes were pulverized into ultrafine powders under three-dimensional shearing force generated by solid-state shear milling equipment. Then, the CPF powders as a crystallization promoter were incorporated into a polypropylene random copolymer (PPR) in the presence of a β-nucleator by utilizing high-chain stereoregularity and strong crystallization nature to cultivate rich β-crystals. Finally, the outstanding combination of strength and toughness of the as-prepared PPR sample was exemplified by the increases of 66 and 25.8% in elongation at break and impact strength over a pure PPR sample at the guarantee of mechanical strength. This simple blending approach also can be extended easily to the recycling of the other polypropylene-based waste plastics and thus is an important step toward solving global plastic pollution.

“…In our cases, the orientation of molecular chain, shish kebab crystal and the foreign fibrous TiO 2 eventually form a multilevel and multiscale helical structure. When heated to equilibrium melting point, the oriented molecular chains in the microtubes will relax back to coil state, resulting in obvious thermal shrinkage along orientation direction [41]. Therefore, thermal shrinkage experiments were conducted to investigate the molecular orientation in the prepared microtubes.…”

Section: Resultsmentioning

confidence: 99%

Polyethylene/TiO₂ Medical Tube with Comprehensive Mechanical Performances via Bio‐Mimic Multiscale Helical Structures

Shi

Vinyl Additive Technology

et al. 2019

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Microtubes with superior mechanical properties are highly desired in modern medical applications due to its convenience in drug delivery and micro invasive surgery. However, poor kink resistance is still a changeling issues because the high axial orientation is inevitable in conventional tube processing procedure. Herein, with combination of rotation extrusion technology and antibacterial titanium dioxide (TiO2) fibers, a bio‐mimic helical structure consisting of molecular chains, shish kebabs, and fibrous TiO2 was successfully manipulated. With assistance of helical structure, kink resistance was enhanced without sacrifice the flexibility. The hoop twist strength reached 15.7 MPa, 45% higher than the conventional ones, while axial compressive strength decreased from 9.4 to 7.9 MPa, exhibiting good flexibility. Moreover, further structural analysis demonstrated that the deviated molecular chains and shish kebabs played a predominating role in enhancing kink resistance of the PE tubes rather than rigid TiO2 fibers, which could provide more theoretical and experimental fundament for design of future medical tubes.