Asad Asad scite author profile

Protective textiles used for military applications must fulfill a variety of functional requirements, including durability, resistance to environmental conditions and ballistic threats, all while being comfortable and lightweight. In addition, these textiles must provide camouflage and concealment under various environmental conditions and, thus, a range of wavelengths on the electromagnetic spectrum. Similar requirements may exist for other applications, for instance hunting. With improvements in infrared sensing technology, the focus of protective textile research and development has shifted solely from providing visible camouflage to providing camouflage in the infrared (IR) region. Smart textiles, which can monitor and react to the textile wearer or environmental stimuli, have been applied to protective textiles to improve camouflage in the IR spectral range. This study presents a review of current smart textile technologies for visible and IR signature control of protective textiles, including coloration techniques, chromic materials, conductive polymers, and phase change materials. We propose novel fabrication technology combinations using various microfabrication techniques (e.g., three-dimensional (3D) printing; microfluidics; machine learning) to improve the visible and IR signature management of protective textiles and discuss possible challenges in terms of compatibility with the different textile performance requirements.

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Printing with mechanically interlocked extrudates using a custom bi-extruder for fused deposition modelling

Khondoker

Asad

Sameoto

2018

RPJ

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Purpose This paper aims to target to print functionally gradient materials (FGM) devices made of immiscible polymers in multi-material fused deposition modelling (FDM) systems. The design is intended to improve adhesion of dissimilar thermoplastics without the need for chemical compatibilization so that filaments from many different sources can be used effectively. Therefore, there is a need to invent an alternative solution for printing multiple immiscible polymers in an FDM system with the desired adhesion. Design/methodology/approach In this study, the authors have developed a bi-extruder for FDM systems which can print two thermoplastics through a single nozzle with a static intermixer to enhance bonding between input materials. The system can also change the composition of extrudates continuously. Findings The uniqueness of this extruder is in its easy access to the internal channel so that a static intermixer can be inserted, enabling deposition of mechanically interlocked extrudates composed of two immiscible polymers. Without this intermixer, the bi-extruder extrudes with simple side-by-side co-extrusion having no mechanical interlocking. The bi-extruder was characterized by printing objects using pairs of materials including polylactic acid, acrylonitrile butadiene styrene and high impact polystyrene. Microscope images of the cross-sections of the extrudates confirm the ability of this bi-extruder to control the composition as desired. It was also found that the mechanically interlocked extrudates composed of two immiscible polymers substantially reduces adhesion failures within and between filaments. Originality/value In this study, the first-ever FDM extruder with a mechanical blending feature next to the nozzle has been designed and used to successfully print FGM objects with improved mechanical properties.

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Removal of trace organic contaminants by melamine-tuned highly cross-linked polyamide TFC membranes

et al. 2020

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Direct Micropatterning of Phase Separation Membranes Using Hydrogel Soft Lithography

Asad

Sadrzadeh

Sameoto

2019

Adv Materials Technologies

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In this work a novel method is presented to directly apply microscale patterns on the membrane surface using hydrogel facilitated phase separation (HFPS). The hydrogel mold initiates phase separation spontaneously when it contacts the polymer solution and this guarantees that location of the dense skin layer is on the patterned side. In this fashion, the active surface area of a membrane is larger than the equivalent flat surface and subsequently enhances water flux without changing the membrane surface chemistry. The morphological properties of the HFPS membranes show similarity to the nonsolvent induced phase separation ones; however, a pore enlarging is noticed in the HFPS membranes due to the slow demixing rate of the solvent/nonsolvent in the phase separation process. The permeation results show that the HFPS patterned membrane doubles the pure water permeate flux when compared to the HFPS unpatterned membrane. This increase is attributed to the combined effect of enhanced surface area and a slight increase in the average pore size of the membrane. Moreover, fouling experiments with bovine serum albumin solution show a 78% increment in the flux for the patterned membrane after 100 min of operation, demonstrating the advantage of using microstructured membrane for filtration applications.

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Asad Asad

Overview of membrane technology

Smart Textiles for Visible and IR Camouflage Application: State-of-the-Art and Microfabrication Path Forward

Printing with mechanically interlocked extrudates using a custom bi-extruder for fused deposition modelling

Removal of trace organic contaminants by melamine-tuned highly cross-linked polyamide TFC membranes

Direct Micropatterning of Phase Separation Membranes Using Hydrogel Soft Lithography

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