Rayhan Khan scite author profile

Rayhan Khan

4Publications

18Citation Statements Received

21Citation Statements Given

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Affiliations

Florida International University, North Carolina State University, University of Miami

Publications

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Simulation of Needle-Fabric Interactions in Sewing Operations

Khan

Hersh

Grady

1970

Textile Research Journal

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The nature of the forces involved when a sewing needle penetrates a fabric have been studied on an Instron in an attempt to identify some of the factors which influence the needle-fabric interaction leading to heat generation. The measurements were made at velocities three to four orders of magnitude lower than actual sewing velocities. Four major variables considered were needle velocity, needle diameter, needle surface finish, and number of fabric layers. The influence of these factors on the maximum penetration force and on the energy required to drive the needle into and out of fabric has been studied. All these factors and their interactions (except needle velocity in some cases) affect the maxi mum penetration force of the needle and the energy of penetration. The effect of needle velocity over the range covered, even when significant, was minor (of the order of about 10%). The needle diameter affects the maximum penetration force and energy of penetration to a much greater extent. They are found to increase at a greater than linear rate with in creasing needle diameter. In one fabric, these parameters increased with the third or fourth power of the diameter. Whereas certain special high-emissivity needle-surface finishes have been found to reduce temperatures of needles during sewing, more energy is expended when these needles pass through fabrics than is expended with regular-finished needles. In a series of exploratory experiments, no differences in behavior were observed for a variety of needle-point shapes (twist point, diamond point, and standard ball point) or for tests using sewing threads compared with tests made without sewing threads. The bulged eye needle was effective in reducing energy buildup, compared with ball-point needles. The maximum penetration force and energy of penetration were found to increase linearly with increasing numbers of fabric layers. Wherever feasible, attempts are made to relate observed penetration energy measurements with expected needle heating characteristics and with results reported in the literature.

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Adhoc mobile power connectivity using a wireless power transmission grid

Gaire

Vital

Khan

et al. 2021

Sci Rep

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Wireless charging of devices has significant outcomes for mobile devices, IoT devices and wearables. Existing technologies consider using Point to Point type wireless transfer from a transmitter Tx (node that is sending Power) to a receiver Rx (node that receives power), which limits the area of coverage for devices. As a result, existing systems are forced to use near field coupling to charge such devices. Fundamental limitation is also that such methods limit charging to a small hotspot. In partnership with Wireless Electrical Grid LANs (WiGL pronounced “wiggle”), we demonstrate patented Ad-hoc mesh networking method(s) to provide wireless recharging at over 5 feet from the source, while allowing significant lateral movement of the receiver on the WiGL (Wireless Grid LAN or local area network). The transmitter network method leverages a series of panels, operating as a mesh of transmitters that can be miniaturized or hidden in walls or furniture for an ergonomic use. This disruptive technology holds the unique advantage of being able to provide recharging of moving targets similar to the cellular concept used in WiLAN, as opposed to prior wireless charging attempts, which only allow a hotspot-based charging. Specifically, we demonstrate the charging of a popular smartphone using the proposed system in the radiating near field zone of the transmitter antennas, while the user is free to move in the space on the meshed network. The averaged received power of 10 dBm is demonstrated using 1W RF-transmitter(s), operating in the 2.4 GHz ISM band. The proposed hardware consists of antennas arrays, rectennas, power management and USB 2.0 interfaces for maintaining a voltage between 4.2 and 5.3 V and smooth charging. We also show extending the wireless grid coverage with the use of multiple transmitting antennas, and mechanical beam-steering even further an increased coverage using the proposed system.

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Origami-Enabled Frequency Reconfigurable Dipole Antenna

Khan

Zekios

Bhardwaj

et al. 2019

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Aperture-Array & Lens+FPA Multi-Beam Digital Receivers at 28 GHz on Xilinx ZCU 1275 RF SoC

Pulipati

Khan

Bhardwaj

et al. 2020

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Rayhan Khan

Simulation of Needle-Fabric Interactions in Sewing Operations

Adhoc mobile power connectivity using a wireless power transmission grid

Origami-Enabled Frequency Reconfigurable Dipole Antenna

Aperture-Array & Lens+FPA Multi-Beam Digital Receivers at 28 GHz on Xilinx ZCU 1275 RF SoC

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