Tensile, rheological and morphological characterizations of multi-walled carbon nanotube/polypropylene composites prepared by microinjection and compression molding

Ezat, G.S., Kelly, Adrian L., Youseffi, Mansour, Coates, Philip D.

07 April 2022

Yes / Polypropylene (PP) reinforced with 2 and 4 wt% of multi-walled carbon nanotubes (MWNT) were melt-blended in twin screw extruder and then molded by compression or micromolding process. The impact of injection speed on the surface morphology, rheological and tensile characteristics was investigated by using a scanning electron microscope, parallel plate rheometry, and tensiometry. Results showed that the tensile properties of micro-molded specimens were remarkably higher than those of the compression molded sheets. Compared to compression molded sheets, micromolded specimens demonstrated up to 40 and 244% higher tensile stiffness and yield strength, respectively, most likely due to the alignment of polymer chain segments in the flow direction induced during the micromolding process. It was observed that the fast filling speed caused a drop in the tensile properties of the nanocomposites and polymer. Rheological examination revealed that the presence of a rheological percolation network in the nanocomposites produced by micromolding and the fast injection speed was beneficial for establishing the percolated network. Morphological examination revealed that the size of nanotube agglomerations that appeared in micromolded specimens was up to five times smaller than in compression molded sheets and the agglomeration size decreased with the increase of the injection speed.

Compression molding

Injection speed

Microinjection molding

Nanocomposites

Polypropylene

Predicting the location of weld line in microinjection-molded polyethylene via molecular orientation distribution

Liao, T., Zhao, X., Yang, X., Whiteside, Benjamin R., Coates, Philip D., Jiang, Z., Men, Y.

31 January 2020

Yes / The microstructure and molecular orientation distribution over both the length and the thickness of microinjection‐molded linear low‐density polyethylene with a weld line were characterized as a function of processing parameters using small‐angle X‐ray scattering and wide‐angle X‐ray diffraction techniques. The weld line was introduced via recombination of two separated melt streams with an angle of 180° to each other in injection molding. The lamellar structure was found to be related to the mold temperature strongly but the injection velocity and the melt temperature slightly. Furthermore, the distributions of molecular orientation at different molding conditions and different positions in the cross section of molded samples were derived from Hermans equation. The degree of orientation of polymeric chains and the thickness of oriented layers decrease considerably with an increase of both mold temperature and melt temperature, which could be explained by the stress relaxation of sheared chains and the reduced melt viscosity, respectively. The level of molecular orientation was found to be lowest in the weld line when varying injection velocity, mold temperature, and melt temperature, thus providing an effective means to identify the position of weld line induced by flow obstacles during injection‐molding process. / Jilin Scientific and Technological Development Program. Grant Number: 20180519001JH; National Key R&D Program of China. Grant Number: 2018YFB0704200; National Natural Science Foundation of China. Grant Numbers: 21674119, 21790342; Newton Advanced Fellowship of Royal Society. Grant Number: NA150222

Microinjection molding

Molecular orientation

Polyethylene

SAXS

Weld line

Fabrication of Integrated Nebulizer Nozzle Plate Utlizing Micro-molding for FD- ESI Mass Spectrometry

Chang, Chien-chung

01 July 2005

This study presents a novel concept to integrated nebulizer nozzle plate for FD-ESI (Fused-droplet Electrospary Ionization Mass Spectrometry) using modified LIGA process. This fabrication technique can reduce the production cost of current nozzle plate. It comprises of multi-exposure and single develop (MESD) process, the extra-hard Ni-Co (Nickel-Cobalt) electroforming and thin-wall plastic microinjection molding. The template of nozzle plate is patterned using dry film and MESD process. Later, the template is transferred into metal Ni-Co mold by electroplating. In this study, the technique of extra-hard Ni-Co alloy electroplating process with Hardness of Vickers over (HV) 550 is developed. Then with the stiffness of Ni-Co mold, it can withstand high injection speed. Thin-wall microinjection molding process with short cycle time to fabricate nozzle plate can be finished. Liquid crystal polymer (LCP) is used for thin-wall microinjection molding process. In order to make efficiently atomization, we used ANSYS to optimize PZT actuator. Besides, the work of nebulizer with FD-ESI was demonstrated in this study. a novel design of nozzle plate.

Microinjection molding

Ni-Co electroforming

UV-LIGA

Nebulizer

MESD

FD-ESI

nozzle plate

Investigation of Mold Design and Process Parameters in Microinjection Molding to Fabricate a Deformable Membrane Mirror

El-Taleb, Ahmed Salem

26 December 2013

No description available.

Industrial Engineering

Polymers

Microinjection molding

mold design

microchannel

deformable membrane mirror

process parameters

Rhéologie des polymères fondus à hauts taux de cisaillement : application à la microinjection / Polymer melts rheology at high shear rate : microinjection molding application

Mnekbi Djebali, Cheima

07 December 2012

La rhéologie à hauts taux de cisaillement pour deux polymères, le PEHD semi-cristallin et le PMMA amorphe a été étudiée. Des outils de rhéométrie classique, un rhéomètre plan-plan en mode dynamique, et un rhéomètre capillaire, ont été utilisés dans des conditions extrêmes (avec des filières pour la rhéométrie capillaire de diamètres allant jusqu'à 0,3 mm) mais les dépouillements de ces résultats ont été fait suivant les hypothèses conventionnelles en négligeant les instabilités et les phénomènes physiques qui interviennent lors de ces écoulements.Nous avons par la suite développé un modèle mathématique de l'écoulement dans un capillaire pour rendre compte de l'importance des différents phénomènes physiques qui peuvent avoir lieu dans des écoulements extrêmes, à savoir l'échauffement et la piezodépendance de la viscosité, la compressibilité et le glissement à la paroi. Les résultats du modèle développé ont été comparés avec les résultats expérimentaux.Nous avons aidé au développement d'une presse de microinjection originale et nous l'avons testée avec un moule de plaque instrumenté d'épaisseur allant jusqu'à 0,2 mm. Nous avons montré qu'il était possible de réaliser des pièces de qualité ce qui est avéré par des mesures de pression, vitesse et de température bien reproductibles. Nous avons exploité les données rhéologiques expérimentales dans la modélisation de la phase de remplissage avec le logiciel de calcul Rem3D. Des corrélations entre les mesures expérimentales et les calculs ont été réalisées en comparant l'évolution des pressions dans le système d'alimentation et dans l'empreinte. / Rheology at high shear rate for both polymers, semi-crystalline HDPE and amorphous PMMA was studied. Classical rheometry tools, plane-plane dynamic mode rheometer and capillary rheometer, were used in extreme conditions (with channels diameters for capillary rheometry up to 0.3 mm). However, analyses of these results were made following conventional assumptions neglecting instabilities and physical phenomena involved in these flows.We then developed a mathematical model of a capillary flow in to reflect the importance of different physical phenomena that can occur in extreme flows, namely heating, pressure dependency of viscosity, compressibility and the wall slip. The results of the developed model were compared with experimental results.We helped develop a press microinjection original and we tested it with instrumented plate mold with thickness up to 0.2 mm. We have shown that it is possible to make quality parts which are proven by well reproducible pressure, speed and temperature measurements. We used the experimental rheological data in filling phase modeling with the calculation software Rem3D. Correlations between experimental measurements and calculations were carried out by comparing the pressure in the filling system and the cavity.

Rhéologie à hauts taux de cisaillement

Microinjection

Simulation par éléments finis

Piezodépendance de la viscosité

Thermodépendance de la viscosité

Glissement à la paroi

High shear rate rheology

Microinjection molding

Finite element simulation

Pressure dependent viscosity

Temperature dependent viscosity

Wall slip

Strukturintegrierbare Sensoren auf Basis piezoelektrischer Polymere / Sensors Based on Piezoelectric Polymers for Structure Integration

Schulze, Robert

07 August 2017

Die vorliegende Arbeit beschreibt die Entwicklung von Sensoren in einer neuen, großserienfähigen Technologie. Mit dem Mehrkomponentenmikrospritzgießverfahren werden mechanische Sensorstrukturen aus (faserverstärktem) Kunststoff an polymere piezoelektrische Wandler angebunden. Die hergestellten Aufnehmer können über die Weiterverarbeitung mit Hybridtechnologien für die Strukturintegration eingesetzt werden. Diese Dissertation stellt Entwurfsmethoden und Modelle zur Vorausberechnung der neuartigen Sensoren bereit, die zur Qualifizierung der neuen Technologie benötigt werden. Dazu werden bekannte Modellierungsansätze angewandt und wesentliche Erweiterungen für die praktische Nutzung erarbeitet. Entwurfsrelevante technologieabhängige Kenngrößen, wie die elastischen Eigenschaften der verarbeiteten Werkstoffe und die geometrischen Dimensionen der hergestellten Sensorstrukturen werden untersucht und deren Einfluss auf den Entwurfsprozessdargelegt. Die hergestellten Sensoren werden in ihrer Grundfunktion messtechnisch charakterisiert und die System- und Strukturintegration vorgestellt. / The presented work describes the development of sensors in a novel technology approach feasible for large-scale production. By using the multicomponent microinjection molding process, mechanical sensor structures out of (fiber-reinforced) polymers are joined with piezoelectric polymer transducers. The fabricated sensors can be processed further with hybrid manufacturing technologies and adapted for structure integration. This thesis introduces design methods and models for the preliminary calculation of the novel sensors, which are required for a technology qualification. Therefore, existing modelling approaches adapted and essentially extended for practical use. Design relevant parameters related to the technology like the elastic properties of the applied materials or the geometric dimensions of the manufactured sensor structures are characterized and the system and structure integration of the sensors is presented.

Polymerer Sensor

P(VDF-TrFE)

Mikrospritzgießen

Sensorentwurf

Kombinierte Simulation

Strukturintegration

Sensortest

Technologiequalifizierung

Polymer Sensor

Piezoelectric Transducer

P(VDF-TrFE)

Microinjection Molding

Sensor Design

Combined Simulation

Structure Integration

System Integration

Sensor Test

Technology Qualification

ddc:600

Piezoelektrischer Wandler

Mikrospritzguss

Systemintegration

Strukturintegrierbare Sensoren auf Basis piezoelektrischer Polymere

Schulze, Robert

10 January 2017

Die vorliegende Arbeit beschreibt die Entwicklung von Sensoren in einer neuen, großserienfähigen Technologie. Mit dem Mehrkomponentenmikrospritzgießverfahren werden mechanische Sensorstrukturen aus (faserverstärktem) Kunststoff an polymere piezoelektrische Wandler angebunden. Die hergestellten Aufnehmer können über die Weiterverarbeitung mit Hybridtechnologien für die Strukturintegration eingesetzt werden. Diese Dissertation stellt Entwurfsmethoden und Modelle zur Vorausberechnung der neuartigen Sensoren bereit, die zur Qualifizierung der neuen Technologie benötigt werden. Dazu werden bekannte Modellierungsansätze angewandt und wesentliche Erweiterungen für die praktische Nutzung erarbeitet. Entwurfsrelevante technologieabhängige Kenngrößen, wie die elastischen Eigenschaften der verarbeiteten Werkstoffe und die geometrischen Dimensionen der hergestellten Sensorstrukturen werden untersucht und deren Einfluss auf den Entwurfsprozessdargelegt. Die hergestellten Sensoren werden in ihrer Grundfunktion messtechnisch charakterisiert und die System- und Strukturintegration vorgestellt. / The presented work describes the development of sensors in a novel technology approach feasible for large-scale production. By using the multicomponent microinjection molding process, mechanical sensor structures out of (fiber-reinforced) polymers are joined with piezoelectric polymer transducers. The fabricated sensors can be processed further with hybrid manufacturing technologies and adapted for structure integration. This thesis introduces design methods and models for the preliminary calculation of the novel sensors, which are required for a technology qualification. Therefore, existing modelling approaches adapted and essentially extended for practical use. Design relevant parameters related to the technology like the elastic properties of the applied materials or the geometric dimensions of the manufactured sensor structures are characterized and the system and structure integration of the sensors is presented.

info:eu-repo/classification/ddc/600

ddc:600