Investigation of recycled PET and its application for blow moulded containers requiring thermal stability at elevated tempoeratures.

Patuto, Joseph, jpatuto@bigpond.net.au

January 2008

Polyethylene Terephthalate (PET) has become the preferred material of choice for many packaging applications. A preference over glass due to its low weight, similar transparency to glass and cost consideration, including the availability of recycled PET feedstock via kerbside collection has provided newer opportunities for hot-fill applications. Ostensibly, this material is used for beverage markets requiring cold and hot filling (85 oC) of liquid foods. However due to the poor thermal stability of PET - due to its low glass transition temperature - an increase in elevated temperatures limits the number of market segments the material can be utilised. Current practices incorporate the heat-set process, aimed at improving the crystallisation kinetics within the amorphous and crystalline region. This body of work incorporates a single stage Injection Stretch Blow Moulding machine (ISBM). Modifications to conventional carbonated soft drink (CSD) beverage containers to include heat-set capabilities are incorporated. The current research study investigates the potential benefits of RPET blends for improving thermal stability at elevated temperatures. This study investigates changes in mechanical properties which include • Youngs modulus, • top load strength, • burst strength, • Thermal analysis specifically investigating changes in • Glass transition temperature, • enthalpy changes due to heat-set conditions • Percentage crystallinity changes as a function of heat-set conditions Rheological characteristics to all materials used were investigates. Furthermore, changes in the physical properties to each PET beverage container were investigated which include; • process shrinkage (S1), • hot-fill shrinkage (S2) • Density changes via optimised DoE parameters. A combination of cold (80 oC) and hot moulds (150 oC) as measured via Forward Looking Infrared (FLIR) at the exterior to the blow mould and their affect on percentage crystallinity was studied. Preform surface temperature (PST) and strain induced crystallinity, assisting in molecular relaxation is analysed. Upon completion to an exhaustive experimental ISBM trial, a DoE software package - in this case Echip - was used to analyse and predict optimised hot-fill shrinkage values of 2.5 percent with a maximum constrained RPET blend value totalling 40 percent. ISBM optimised conditions demonstrated advantages when combining an increased preform surface temperature, RPET blends and optimised ISBM process conditions as indicated via the DoE at low heat-set temperatures.

PET

packaging

injection stretch blow moulding

Bifurcation scenarios in semiconductor lasers subject to optical injection /

Marilley, Rachel.

January 2007

Thesis (M.S.)--Rochester Institute of Technology, 2007. / Typescript. Includes bibliographical references (leaf 28).

Processing bulk metallic glass from the molten state

McCracken, Ivan A.

25 April 2003

This paper documents the investigation into injection molding, or die casting, a bulk metallic glass (BMG). A BMG is an amorphous metal of a thickness greater than 25 ��m, according to leading researchers in the field. This critical thickness differentiates a normal metallic glass from a "bulk" metallic glass. The impetus for studying the ability to process lies in the material properties of the BMG, which has twice the strength of steel and the ability to be formed much like a thermoplastic. An initial discussion of processing options and history precedes a detailed description of the machine concept and design, including the governing parameters placed on the design. An account of methods and materials used has been included, along with problems encountered and resultant remedies. The initial results consist of the verification of the machine concept and the ability to replicate nanometer-sized surface features from a mold. Design issues are addressed and the corresponding revisions described. The final machine revision shows an increase in process repeatability. A presentation of photographs, which show results of forming the BMG against both copper and stainless steel, is offered as a qualitative assessment of the processing capability. A discussion of considerations and paths forward has been included for future research using the machine that was developed, but these processing theories could also be carried over to other experiments. In the end, this study proves the ability to form extremely small surface features in cast BMG parts and makes suggestions on research avenues that may give a better understanding of the variables involved in processing BMG from the molten state. / Graduation date: 2003

Metallic glasses

Injection molding of metals

Die-casting

Numerical simulation of flow separation control by oscillatory fluid injection

Resendiz Rosas, Celerino

29 August 2005

In this work, numerical simulations of flow separation control are performed. The sep-aration control technique studied is called 'synthetic jet actuation'. The developed code employs a cell centered finite volume scheme which handles viscous, steady and unsteady compressible turbulent flows. The pulsating zero mass jet flow is simulated by imposing a harmonically varying transpiration boundary condition on the airfoil's surface. Turbulence is modeled with the algebraic model of Baldwin and Lomax. The application of synthetic jet actuators is based in their ability to energize the boundary layer, thereby providing signifcant increase in the lift coefficient. This has been corroborated experimentally and it is corroborated numerically in this research. The performed numerical simulation investigates the flow over a NACA0015 air-foil. For this flow Re = 9??105 and the reduced frequency and momentum coefficient are F+ = 1:1 and C?? = 0:04 respectively. The oscillatory injection takes place at 12.27% chord from the leading edge. A maximum increase in the mean lift coefficient of 93% is predicted by the code. A discrepancy of approximately 10% is observed with corresponding experimental data from the literature. The general trend is, how-ever, well captured. The discrepancy is attributed to the modeling of the injection boundary condition and to the turbulence model.A sensitivity analysis of the lift coefficient to different values of the oscillation parameters is performed. It is concluded that tangential injection, F + ?? O(1) and the utilized grid resolution around the site of injection are optimal. Streamline fields ob-tained for different angles of injection are analyzed. Flow separation and attachment as functions of the injection angle and of the velocity of injection can be observed. It is finally concluded that a reliable numerical tool has been developed which can be utilized as a support tool in the optimization of the synthetic jet operation and in the modeling of its operation.

numerical simulation

separation control

oscillatory fluid injection

A study on Raman Injection Laser

Liu, Debin

01 November 2005

The Raman Injection Laser is a new type of laser which is based on triply resonant stimulated Raman scattering between quantum confined states within the active region of a Quantum Cascade Laser that serves as an internal optical pump. The Raman Injection Laser is driven electrically and no external laser pump is required. Triple resonance leads to an enhancement of orders of magnitude in the Raman gain, high conversion efficiency and low threshold. We studied this new type of laser and conclude some basic equations. With reasonable experimental parameters, we calculated the laser gain, losses and the output power of the Raman Injection Laser by using Mathematica and FEMLab. Finally we compared the theoretical and experimental results.

Raman Injection Laser

Quantum Cascade Laser

Efficiency analysis of varying EGR under PCI mode of combustion in a light duty diesel engine

Pillai, Rahul Radhakrishna

10 October 2008

The recent pollution norms have brought a strong emphasis on the reduction of diesel engine emissions. Low temperature combustion technology such as premixed compression ignition (PCI) has the capability to significantly and simultaneously reduce nitric oxides (NOx) and particulate matter (PM), thus meeting these specific pollution norms. There has been, however, observed loss in fuel conversion efficiency in some cases. This study analyzes how energy transfer and brake fuel conversion efficiency alter with (or are affected by) injection timings and exhaust gas recirculation (EGR) rate. The study is conducted for PCI combustion for four injection timings of 9°, 12°, 15° and 18° before top dead center (BTDC) and for four exhaust gas recirculation (EGR) rates of 39%, 40%, 41% and 42%. The data is collected from the experimental apparatus located in General Motors Collaborative Research Laboratory at the University of Michigan. The heat release is calculated to obtain various in-cylinder energy transfers. The brake fuel conversion efficiency decreases with an increase in EGR. The decrease in the brake fuel conversion efficiency is due to the decrease in work output. This decrease is due to an increase in the pumping work and an increase in friction and decrease in gross indicated work. The decrease in the combustion efficiency is because of the increased formation of unburnt products due to increased ignition delay caused by the application of EGR and decreasing air-fuel (A/F) ratio. A definite trend is not obtained for the contribution of heat transfer to the total energy distribution. However the total heat transfer decreases with retardation of injection timing because of decreasing combustion temperature. As the injection timing is retarded, the brake fuel conversion efficiency is found to decrease. This decrease is because of a decrease in net work output. This is because the time available for utilization of the energy released is less because of late combustion. The total heat transfer decreases with retardation of injection timing because of decreasing combustion temperature. The contribution of heat transfer to the total energy distribution decreases with increase in EGR.

injection timing

EGR

Low temperature combustion

PCI

Development of flax fiber-reinforced polyethylene biocomposites by injection molding

Li, Xue

31 March 2008

Flax fiber-reinforced plastic composites have attracted increasing interest because of the advantages of flax fibers, such as low density, relatively high toughness, high strength and stiffness, and biodegradability. Thus, oilseed flax fiber derived from flax straw, a renewable resource available in Western Canada, is recognized as a potential replacement for glass fiber in composites. Among plastics, polyethylene is a suitable material for use as a matrix in composites. However, there are not many studies in this area. Therefore, the main goal of this research was to develop flax fiber-polyethylene (PE) biocomposites via injection molding and investigate the effect of material properties and processing parameters on their properties. <p>Alkali, silane, potassium permanganate, sodium chlorite, and acrylic acid treatments were employed to flax fiber to decrease the hydrophilic of fiber and improve the adhesion between the fiber and the matrix. All chemically treated fiber-HDPE biocomposites had higher tensile strength and lower water absorption compared with non-chemically treated ones. Acrylic acid treatment of the fiber resulted in slight increase in its degradation temperature; using this treated fiber resulted in biocomposites with the best performance. Therefore, the morphological, chemical, and thermal properties of acrylic acid treated fiber were also studied. <p>Linear Low Density Polyethylene (LLDPE) and High Density Polyethylene (HDPE) were the main matrices investigated in this research. Showing a high tensile strength and similar water absorption, HDPE was used as the matrix in further research. Flax fiber with 98-99% purity was chosen as reinforcement since the flax shive mixed with the fiber decreased the tensile and flexural properties but increased the water absorption of the biocomposite. <p>Acrylic acid-treated fiber-HDPE biocomposites had been developed through injection molding under different processing conditions. Increasing the fiber content of biocomposite increased its tensile and flexural strengths, especially flexural modulus, but its water absorption capacity also increased. It was possible to improve the mechanical properties of biocomposites and decrease the water absorption by adjusting injection temperature and pressure. Injection temperature had more influence on the quality of the biocomposite than injection pressure. Injection temperature lower than 195°C was recommended to achieve good composite quality. <p>Melts of HDPE and flax fiber-HDPE biocomposites were categorized as power-law fluids. Apparent viscosity, consistency coefficient, and flow behavior index of biocomposites were determined to study their flow behavior. The statistical relationship of these parameters with temperature and fiber content were modeled using the SAS and SPSS softwares. The injection filling time was related to the material rheological properties: biocomposites required longer filling time than pure HDPE. Low injection temperature also resulted in long filling time.<p>The thermal conductivity, thermal diffusivity, and specific heat of biocomposites containing 10, 20, and 30% fiber by mass were determined in the processing temperature range of 170 to 200°C. Fiber content showed a significant influence on the thermal properties of the biocomposites. The predicted minimum cooling time increased with the thickness of the molded material, mold temperature, and injection temperature, but it decreased with the ejection temperature.

Injection molding

Flax fiber

Biocomposites

Polyethlyene

High Efficiency Organic Light Emitting Diodes with MoO3 Doped Hole Transport Layer

Qiu, Jacky

20 August 2012

Organic Light Emitting Diodes (OLEDs) are widely viewed as next generation platform for flat panel displays and solid state lighting. Currently, OLED efficiency is not high due to high driving voltage. Molybdenum trioxide (MoO3) is ideal for p-type doping of the wide bandgap organic semiconductor 4,4’-bis-9-carbozyl biphenyl (CBP). With p-type doped CBP layer as Hole Transport Layer (HTL), driving voltage can be significantly reduced. Effective design for doped OLED structure consists of a HTL with doped layer from 20nm to 40nm and MoO3 concentration above 5%, the optimized OLED with doped CBP HTL present an 18% improvement over a standard device with CBP HTL at 100mA/cm2. Injection is found to be the principle cause of the reduction of driving voltage and shows close relations to doped layer thickness. Also charge balance is an important factor for high current efficiency, doped layer can be used as tools to promote charge balance.

OLED

Dopant

Hole Injection

High Efficiency

0794

High Efficiency Organic Light Emitting Diodes with MoO3 Doped Hole Transport Layer

Qiu, Jacky

20 August 2012

Organic Light Emitting Diodes (OLEDs) are widely viewed as next generation platform for flat panel displays and solid state lighting. Currently, OLED efficiency is not high due to high driving voltage. Molybdenum trioxide (MoO3) is ideal for p-type doping of the wide bandgap organic semiconductor 4,4’-bis-9-carbozyl biphenyl (CBP). With p-type doped CBP layer as Hole Transport Layer (HTL), driving voltage can be significantly reduced. Effective design for doped OLED structure consists of a HTL with doped layer from 20nm to 40nm and MoO3 concentration above 5%, the optimized OLED with doped CBP HTL present an 18% improvement over a standard device with CBP HTL at 100mA/cm2. Injection is found to be the principle cause of the reduction of driving voltage and shows close relations to doped layer thickness. Also charge balance is an important factor for high current efficiency, doped layer can be used as tools to promote charge balance.

OLED

Dopant

Hole Injection

High Efficiency

0794

Harm production : correctional environments, injection drug users and risk of infection with blood-borne pathogens

Milloy, Michael-John Sheridan

05 1900

Background: Analyses of the individual-, social- and structural-level factors promoting the transmission of HIV and other blood-borne pathogens have consistently identified exposure to correctional environments, especially for individuals who use injection drugs (IDU), as a risk factor for infection. The objectives of this project were: to review the epidemiologic literature on incarceration and HIV infection among IDU, critically examining evidence presented supporting a causal linkage between imprisonment and infection; to investigate incarceration experiences in a cohort of active IDU; and to assess the possible effects of incarceration on the post-release risk environment of active IDU. Methods: Longitudinal datasets for quantitative analyses were derived from the Vancouver Injection Drug User Study (VIDUS) and the Scientific Evaluation of Supervised Injection (SEOSI), both prospective cohorts of IDU in Vancouver’s Downtown Eastside neighbourhood. In the first analysis, the prevalence and correlates of reporting incarceration in the the previous six months were identified in SEOSI using generalized estimating equations (GEE). In the second analysis, the possible effect of imprisonment on the prevalence of risk factors for HIV infection was estimated in VIDUS using linear growth curve analysis. Results: In the first analysis, 902 individuals interviewed at least once between 1 July 2004 and 30 June 2006 were included. Overall, 423 (46.9%) reported an incarceration event at some point during the study period. In a multivariate GEE model, recent incarceration was independently associated with a number of high-risk factors, including syringe sharing. In the second analysis, 1603 individuals were interviewed at least once between 1 May 1996 and 31 December 2005 and in cluded. Of these, 147 (9.2%) matched the study criteria and were included as cases; 742 (46.3%) were included as matched controls. In linear growth curve analyses adjusted for age, gender and ethnicity, syringe sharing was significantly more common in the incarcerated group (p = 0.03) after incarceration than in the control group. Conclusions: Our findings support the existence of a role for incarceration in continued viral transmission. In response, appropriate harm reduction measures should be expanded within correctional environments and social, political and legal reforms enacted to reduce the incidence of imprisonment for individuals who use illicit drugs.

Epidemiology

Injection drug use

HIV/AIDS

Incarceration