Your search keyword '"Van Thanh Dau"' showing total 3 results

1. Low-Cost Graphite on Paper Pressure Sensor for a Robot Gripper with a Trivial Fabrication Process

Author

Jarred Fastier-Wooller, Toan Dinh, Van Thanh Dau, Hoang-Phuong Phan, Fuwen Yang, and Dzung Viet Dao

Subjects

graphite on paper, paper switch, resistive pressure sensor, Chemical technology, TP1-1185

Abstract

A flexible pressure sensor with a rudimentary, ultra-low cost, and solvent-free fabrication process is presented in this paper. The sensor has a graphite-on-paper stacked paper structure, which deforms and restores its shape when pressure is applied and released, showing an exceptionally fast response and relaxation time of ≈0.4 ms with a sensitivity of −5%/Pa. Repeatability of the sensor over 1000 cycles indicates an excellent long-term stability. The sensor demonstrated fast and reliable human touch interface, and successfully integrated into a robot gripper to detect grasping forces, showing high promise for use in robotics, human interface, and touch devices.

Published

2018

2. Development of PZT Actuated Valveless Micropump

Author

Fathima Rehana Munas, Gehan Melroy, Chamitha Bhagya Abeynayake, Hiniduma Liyanage Chathuranga, Ranjith Amarasinghe, Pubudu Kumarage, Van Thanh Dau, and Dzung Viet Dao

Subjects

PZT, dual diaphragm, nozzle jet, microfluidics, micropump, Chemical technology, TP1-1185

Abstract

A piezoelectrically actuated valveless micropump has been designed and developed. The principle components of this system are piezoelectrically actuated (PZT) metal diaphragms and a complete fluid flow system. The design of this pump mainly focuses on a cross junction, which is generated by a nozzle jet attached to a pump chamber and the intersection of two inlet channels and an outlet channel respectively. During each PZT diaphragm vibration cycle, the junction connecting the inlet and outlet channels with the nozzle jet permits consistencies in fluidic momentum and resistances in order to facilitate complete fluidic path throughout the system, in the absence of any physical valves. The entire micropump structure is fabricated as a plate-by-plate element of polymethyl methacrylate (PMMA) sheets and sandwiched to get required fluidic network as well as the overall device. In order to identify the flow characteristics, and to validate the test results with numerical simulation data, FEM analysis using ANSYS was carried out and an eigenfrequency analysis was performed to the PZT diaphragm using COMSOL Multiphysics. In addition, the control system of the pump was designed and developed to change the applied frequency to the piezoelectric diaphragms. The experimental data revealed that the maximum flow rate is 31.15 mL/min at a frequency of 100 Hz. Our proposed design is not only for a specific application but also useful in a wide range of biomedical applications.

Published

2018

3. Transient Characteristics of a Fluidic Device for Circulatory Jet Flow

Author

Hoa Thanh Phan, Thien Xuan Dinh, Phong Nhu Bui, and Van Thanh Dau

Subjects

transient characteristics, circulatory flow, 3D simulation, OpenFOAM, confined space, Chemical technology, TP1-1185

Abstract

In this paper, we report on the design, simulation, and experimental analysis of a miniaturized device that can generate multiple circulated jet flows. The device is actuated by a lead zirconate titanate (PZT) diaphragm. The flows in the device were studied using three-dimensional transient numerical simulation with the programmable open source OpenFOAM and was comparable to the experimental result. Each flow is verified by two hotwires mounted at two positions inside each consisting chamber. The experiment confirmed that the flow was successfully created, and it demonstrated good agreement with the simulation. In addition, a prospective application of the device as an angular rate sensor is also demonstrated. The device is robust, is minimal in size, and can contribute to the development of multi-axis fluidic inertial sensors, fluidic amplifiers, gas mixing, coupling, and analysis.

Published

2018