scholarly journals Experimental testing of the effectiveness of novel hydrocyclones for separation of impurities in biofuels

2021 â—½  
Vol 2094 (5) â—½  
pp. 052045
Author(s):  
E A Petrovsky â—½  
K A Bashmur â—½  
O A Kolenchukov â—½  
V A Kachaeva â—½  
A Ye Sinitskaya
Keyword(s):  
Experimental Testing â—½  
Impurity Content â—½  
Energy Performance â—½  
Waste Cooking Oil â—½  
Purification Method â—½  
Mixture Separation â—½  
Good Energy â—½  
3D Printed â—½  
Separation Of Mixtures â—½  
Maximum Separation

Abstract This paper investigates the potential sources of renewable energy, in particular biofuels. Biofuels tend to contain multiple harmful impurities that need to be separated if the biofuel is to have good energy performance, and the systems that run on it to produce electricity or heat are to operate more reliably. The paper discusses use of hydrocyclones as the most productive and reliable biofuel purification method. It dwells upon the factors that negatively affect separation of mixtures in a hydrocyclone, which are attributable to the complex hydrodynamics of the flow in such a unit. In order to eliminate these factors, the authors hereof have developed two hydrocyclone designs. An experimental test bench was designed and made to test these designs. Parts of the units were 3D printed from an environmentally friendly material. For testing, we used a biodiesel made from waste cooking oil with an impurity content of 23%. Experiments showed a maximum separation rate of 94.2%. The proposed solutions did improve the effectiveness of biodiesel mixture separation. These designs can be effectively used to separate non-homogeneous mixtures.

Development of Wire Actuated Monolithic Soft Gripper Positioned by Robot Manipulator

2020 â—½  
Author(s):  
Rafael Barreto Gutierrez â—½  
Martin Garcia â—½  
Joan McDuffie â—½  
Courtney Long â—½  
Ayse Tekes
Keyword(s):  
Robot Manipulator â—½  
Compliant Mechanism â—½  
Experimental Testing â—½  
Service Robot â—½  
Servo Motor â—½  
Single Piece â—½  
Pick And Place â—½  
Grasping Force â—½  
3D Printed â—½  
The Right

Abstract This paper presents the design and development of a two fingered, monolithically designed compliant gripper mounted on a two-link robot. Rigid grippers traditionally designed by rigid links and joints might have low precision due to friction and backlash. The proposed gripper is designed as a single piece compliant mechanism consisted of several flexible links and actuated by wire through a servo motor. The gripper is attached to a two-link arm robot driven by three step motors. An additional servo motor can also rotate the base of the robot. While the robot is 3D printed using polylactic acid (PLA), the gripper is 3D printed in thermoplasticpolyurethane (TPU). Two force sensors are attached to the right and left ends of the gripper to measure grasping force. Experimental testing for grasping various objects having different sizes, shapes and weights is carried out to verify the robust performance of the proposed design. Through the experimentation, it’s been noted that the compliant gripper can successfully lift up objects at a maximum mass of 200 g and have a better performance if the objects’width is closer to the width of the gripper. The presented mechanism can be utilized as a service robot for elderly people to assist them pick and place objects or lift objects if equipped with necessary sensors.

scholarly journals Early age mechanical behaviour of 3D printed concrete: Numerical modelling and experimental testing

2018 â—½  
Vol 106 â—½  
pp. 103-116 â—½  
Author(s):  
R.J.M. Wolfs â—½  
F.P. Bos â—½  
T.A.M. Salet
Keyword(s):  
Numerical Modelling â—½  
Mechanical Behaviour â—½  
Experimental Testing â—½  
Early Age â—½  
3D Printed

scholarly journals Fresh and Hardened Properties of Extrusion-Based 3D-Printed Cementitious Materials: A Review

Sustainability â—½  
10.3390/su12145628 â—½  
2020 â—½  
Vol 12 (14) â—½  
pp. 5628
Author(s):  
Zhanzhao Li â—½  
Maryam Hojati â—½  
Zhengyu Wu â—½  
Jonathon Piasente â—½  
Negar Ashrafi â—½  
...  
Keyword(s):  
3D Printing â—½  
Experimental Testing â—½  
Design Procedure â—½  
Cementitious Materials â—½  
Material Point â—½  
Point Of View â—½  
Open Time â—½  
Potential Benefits â—½  
3D Printed â—½  
Hardened Properties

3D-printing of cementitious materials is an innovative construction approach with which building elements can be constructed without the use of formwork. Despite potential benefits in the construction industry, it introduces various engineering challenges from the material point of view. This paper reviews the properties of extrusion-based 3D-printed cementitious materials in both fresh and hardened states. Four main properties of fresh-state printing materials are addressed: flowability, extrudability, buildability, and open time, along with hardened properties, including density, compressive strength, flexural strength, tensile bond strength, shrinkage, and cracking. Experimental testing and effective factors of each property are covered, and a mix design procedure is proposed. The main objective of this paper is to provide an overview of the recent development in 3D-printing of cementitious materials and to identify the research gaps that need further investigation.

scholarly journals Numerical Simulation and Experimental Testing of Topologically Optimized PLA Cervical Implants Made by Additive Manufacturing Methodics

2018 â—½  
Vol 12 (2) â—½  
pp. 141-144
Author(s):  
Jozef Živčák â—½  
Radovan Hudák â—½  
Marek Schnitzer â—½  
Tomáš Kula
Keyword(s):  
Additive Manufacturing â—½  
Static Loading â—½  
Surgical Intervention â—½  
Experimental Testing â—½  
Axial Loading â—½  
Topological Optimization â—½  
Optimized Design â—½  
The Finite Element Method â—½  
3D Printed â—½  
Cervical Area

Abstract The article focuses on compressive axial loading experimental testing and simulations of topologically optimized design and additively manufactured cervical implants. The proposed platform design is based on anatomical and biomechanical requirements for application in the cervical area. Thanks to new ways of production, such as additive manufacturing, and new software possibilities in the field of structural analysis, which use the finite element method and analysis, it is possible to execute topological optimization of an implant in construction solution, which would be impossible to make by conventional methods. The contribution of this work lies in investigation of 3D printed PLA cervical implant usage in surgical intervention and creation of a numerical static loading modelling methodics and subsequent experimental confirmation of the modelling correctness.

scholarly journals Numerical assessment of directional energy performance for 3D printed midsole structures

10.3934/mbe.2021224 â—½  
2021 â—½  
Vol 18 (4) â—½  
pp. 4429-4449
Author(s):  
Ankhy Sultana â—½  
â—½  
Tsz-Ho Kwok â—½  
Hoi Dick Ng
Keyword(s):  
Energy Performance â—½  
Numerical Assessment â—½  
3D Printed

A 3D-printed metal column for micro gas chromatography

Lab on a Chip â—½  
10.1039/d0lc00540a â—½  
2020 â—½  
Vol 20 (18) â—½  
pp. 3435-3444
Author(s):  
Sooyeol Phyo â—½  
Sung Choi â—½  
Jaeheok Jang â—½  
Sun Choi â—½  
Jiwon Lee
Keyword(s):  
Gas Chromatography â—½  
Stationary Phase â—½  
Gas Mixture â—½  
Mixture Separation â—½  
Phase Coating â—½  
3D Printed â—½  
Pre Treatment

A square spiral 1 m-long column for gas mixture separation was 3D-printed out with the dimensions of 3.4 × 3.3 × 0.2, followed by pre-treatment and stationary phase coating.

Earthquake Mitigation Effect Analysis of Hysteretie DamPers in Steel Frame

2014 â—½  
Vol 580-583 â—½  
pp. 1767-1770
Author(s):  
Chao Xu â—½  
Yong Feng Niu â—½  
Yong Xie Zhao
Keyword(s):  
Yield Strength â—½  
Mild Steel â—½  
Cyclic Load â—½  
Energy Performance â—½  
Hysteresis Curve â—½  
Initial Stiffness â—½  
Effect Analysis â—½  
Yield Displacement â—½  
Good Energy â—½  
New Type

This paper analyses the frame without mild steel dampers and the frame installed the new T-type , box –type and S-type mild steel dampers by FEM ABAQUS. The results shows the frame installed the new mild steel dampers have smaller yield displacement and the fuller hysteresis curve at low cyclic load, but the initial stiffness, yield strength , stiffness after yielding are greater. Research shows that the new type mild steel dampers have good energy performance, and have the better effect to seismic framework.

scholarly journals Numerical Study of Fire and Energy Performance of Innovative Light-Weight 3D Printed Concrete Wall Configurations in Modular Building System

Sustainability â—½  
10.3390/su13042314 â—½  
2021 â—½  
Vol 13 (4) â—½  
pp. 2314
Author(s):  
Thadshajini Suntharalingam â—½  
Perampalam Gatheeshgar â—½  
Irindu Upasiri â—½  
Keerthan Poologanathan â—½  
Brabha Nagaratnam â—½  
...  
Keyword(s):  
Thermal Energy â—½  
Lightweight Concrete â—½  
Numerical Study â—½  
Building Design â—½  
Energy Performance â—½  
Sound Insulation â—½  
Fire Performance â—½  
Standard Fire â—½  
3D Printed â—½  
Building System

3D Printed Concrete (3DPC) technology is currently evolving with high demand amongst researches and the integration of modular building system (MBS) with this technology would provide a sustainable solution to modern construction challenges. The use of lightweight concrete in such innovative construction methods offers lightweight structures with better heat and sound insulation compared to normal weight concrete. It is worth noting that fire and energy performance has become central to building design. However, there are limited research studies on the combined thermal energy and fire performance of 3DPC walls. Therefore, this study investigates fire performance of 20 numbers of varying 3DPC wall configurations using validated finite element models under standard fire conditions. The fire performance analysis demonstrated that 3DPC non-load bearing cavity walls have substantial resistance under standard fire load and its performance can be further improved with Rockwool insulation. There is significant improvement in terms of fire performance when the thickness of the walls increases in a parallel row manner. Previous thermal energy investigation also showed a lower U-value for increased thickness of similar 3DPC walls. This research concludes with a proposal of using 3DPC wall with Rockwool insulation for amplified combined thermal energy and fire performance to be used in MBS.

An Origami-Based Tunable Helmholtz Resonator for Noise Control: Introduction of the Concept and Preliminary Results

2017 â—½  
Author(s):  
Amine Benouhiba â—½  
Kanty Rabenorosoa â—½  
Morvan Ouisse â—½  
Nicolas Andreff
Keyword(s):  
Noise Control â—½  
Experimental Testing â—½  
Helmholtz Resonator â—½  
Experimental Tests â—½  
Acoustic Control â—½  
Wide Range â—½  
Foldable Structures â—½  
3D Printed â—½  
Passive Acoustic â—½  
Acoustic Domain

A Helmholtz resonator is a passive acoustic device that enables noise reduction at a given frequency. This frequency is directly related to the volume of the resonator and to the size of the neck that couples the resonator to the acoustic domain. In other words, controlling the volume of the cavity allows a real time tunability of the device, which means noise control at any desired frequency. To that end, we propose an Origami-based tunable Helmholtz resonator. The design is inspired from the well-known origami base, waterbomb. Such foldable structures offer a wide range of volume shifting which corresponds to a frequency shifting in the application of interest. The foldability of the structure is first investigated. Then, a series of numerical simulations and experimental tests were preformed are presented, in order to explore the capabilities of this origami structures in acoustic control. A shift in the frequency domain of up to 197 Hz (131–328 Hz) was achieved in an experimental testing using 3D printed rigid devices.

scholarly journals Experimental Testing, Modeling, and Simulation of 3D Printed Composite Material for Morphing Wing Application

2020 â—½  
Author(s):  
Rebecca Rajs â—½  
Marc Palardy-Sim â—½  
Guillaume Renaud â—½  
Michael Jakubinek â—½  
Farjad Shadmehri
Keyword(s):  
Composite Material â—½  
Modeling And Simulation â—½  
Experimental Testing â—½  
Morphing Wing â—½  
3D Printed
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