The SPE Library contains thousands of papers, presentations, journal briefs and recorded webinars from the best minds in the Plastics Industry. Spanning almost two decades, this collection of published research and development work in polymer science and plastics technology is a wealth of knowledge and information for anyone involved in plastics.
Over the past decade a new family of materials called nanocomposites have emerged as potentially important commercial composites for engineering and packaging applications. These materials have normally contained a smectite clay as the nanosize component of the composite. These materials are naturally occurring minerals that exhibit large aspect ratios and one dimension in the nanometer range. These minerals however, are normally very hydrophilic and, therefore must be surface modified in order to render them compatible with most polymers or monomers. This paper reports a series of new surface modified clays for use in nanocomposites and some application to nanocomposites. In recent years a family of surface modified clays has been developed that do not involve the use of onium ions. This paper will describe these new methods of surface modifications and examples of how they can be applied to polymer nanocomposites.
Tony D. Brooks, Thomas E. Galvanek, Louis N. Kattas, May 1999
Satisfying your loyal customers is the best way to maintain and grow a strong business. By quantifying you performance on the critical factors defining customer satisfaction, you can focus company resources to increase profits, expand in the most attractive markets, and prevent defections. In addition, it reveals unique competitive opportunities to maximize your market position and image. This highly effective approach was developed by the authors and used successfully in North America and Europe with many companies throughout the plastic industry.
The use of thermoplastic polymers, reinforced with a variety of man made products, including fibrous glass, Kevlar*, polyester, and nylon fabrics, has been growing aggressively in recent years. Combining dissimilar polymer matrices as the impregnating skins allows for unusual combinations of functional properties. One major problem, unlike their sister thermosetting composites, is the lack of crosslinking, which ensures functional integrity, especially at elevated temperatures. This is offset, however, by enhanced impact toughness which most thermosetting composites cannot offer. The scope of this study was to investigate the property retention index (PRI) of a range of thermoplastic mat composites (TMC) and to evaluate the PRI for selected physical properties, including torsional modulus and flexural behavior. The role of the impregnating resin, the reinforcement type/physical form, and fabrication/assembly scheme shall be reported.
This paper will compare and contrast output from blow molding software to actual molded parts. The software being studied is a 3D shell element blow molding simulation package. With the rapid growth of blow molding today there is a need for simulation software, which will help processors, mold builders, and part designers. This software may help to reduce the time to market by eliminating design guesswork based on past experience. This study will examine one oval bottle and compare actual wall thicknesses to the software. A mold and a laser mic will be used to determine actual volumes, diameters and thicknesses along the parison.
The purpose of this paper is to reduce design iterations in blow molding design by producing better products and reducing the time to market. The software being used can provide a good starting point for the design and initial process. This paper will provide published data on thickness predictions from the software and the actual values obtained from molded parts. Both simple and complex geometry will be tested. The geometry used at the start is a cylindrical bottle, followed by an oval bottle. The oval bottle will provide a good opportunity to see the thickness variations at the further extremes. The software predicts the thickness by using 3D shell elements.
Throughout the packaging industry decisions are often made concerning types of bottles to use for certain container applications. When deciding which type of bottle is suitable for a product one aspect is the hoop strength of the bottle. This hoop strength is measured by air pressure testing the bottles. Using the guidelines set forth in ASTM D 2561, an apparatus that consists of a pressure regulator and explosion chamber, an average hoop strengths were determined for each HDPE bottle. The results of the hoop strength testing will show the mechanical differences between the bottle types and material types. It will be shown that the apparatus can also be used to determine the increase in diameter of each bottle with pressure. It can also be used to determine long term creep properties. The specimen sizes provided variables to explore the hoop strengths of HDPE. Conclusions were made on the different hoop strengths of the different specimens.
X-ray diffraction patterns for polymers with splits in the classic Amorphous Halo" pattern are difficult to predict using molecular modeling. These polymers contain a level of order intermediate between that of a crystal and a truly amorphous polymer that is not simply a combination of the two (semicrystalline). We have accurately predicted the Wide Angle X-ray Diffraction (WAXD) pattern for 23 erythro di-isotactic poly(norbornene) (PNB)a polymer with promising application as an interlayer dielectric or a photoresist material in the microelectronics industry. Molecular modeling predicts this polymer exists in the glassy state in a helical conformation that is occasionally disrupted by kinks. Comparison to other modeling results on poly(t-butyl acetylene) (PTBA)suggests that both these polymers belong to a new class of polymers that contain this helix-kink conformation. This conformation is what is responsible for the viscosity behavior of PNB and it may be useful in understanding both viscosity and membrane barrier properties for this class of polymers."
X-ray diffraction patterns for polymers with splits in the classic Amorphous Halo" pattern are difficult to predict using molecular modeling. These polymers contain a level of order intermediate between that of a crystal and a truly amorphous polymer that is not simply a combination of the two (semicrystalline). We have accurately predicted the Wide Angle X-ray Diffraction (WAXD) pattern for 23 erythro di-isotactic poly(norbornene) (PNB) a polymer with promising application as an interlayer dielectric or a photoresist material in the microelectronics industry. Molecular modeling predicts this polymer exists in the glassy state in a helical conformation that is occasionally disrupted by kinks. Comparison to other modeling results on poly(t-butyl acetylene) (PTBA)suggests that both these polymers belong to a new class of polymers that contain this helix-kink conformation. This conformation is what is responsible for the viscosity behavior of PNB and it may be useful in understanding both viscosity and membrane barrier properties for this class of polymers."
Hemant Nanavati, Prashant Desai, A.S. Abhiraman, May 1999
The polymer chain is considered to comprise of freely orienting statistical segments having a distribution of vector lengths and polarizabilities, which are utilized to develop stress-elongation and birefringence-elongation relationships for crosslinked polymer networks. This formulation provides an accurate fit of poly(cis-isoprene) and polyethylene stress-elongation data over a wide elongation range, using two physical parameters. These fitted parameters yield objective predictions of birefringence-elongation relationships. This approach incorporates primary molecular structural features in modeling mechanical and optical properties of rubbery polymer networks.
Jo Ann Ratto, Diane M. Steeves, Elizabeth A. Welsh, Bert E. Powell, May 1999
A series of biodegradable polymer/clay nanocomposites have been prepared using two techniques: in-situ polymerization and twin screw extrusion. These samples containing 5-25% clay and polycaprolatone (PCL) were characterized with regard to processability, biodegradability, morphology, thermal behavior and mechanical properties. The processing at different screw speeds (20, 40, 60 rpm) did not alter the polymer/clay interactions. Biodegradation results in soil showed 50% mineralization of PCL/clay in 50 days as compared to 10% for the pure PCL film. X-ray diffraction patterns demonstrated that the polymer had different degrees of intercalation in the silicate layers of the clay. Dynamic mechanical analysis showed no change in the PCL glass transition temperature with the addition of clay.
Using stress relaxation measurements, we describe the kinetics of the physical aging process for two semi-crystalline, biaxially stretched polyester films, PET and PEN, within their respective ? transition regimes. By applying the principles of time-aging time and time-aging temperature equivalence, we establish the temperature dependence of the corresponding aging acceleration factors over a temperature range spanning from ca. Tg -40°C to Tg. The results for both materials show significant increase in the rate of physical aging at ca. 20°C below the glass transition temperature. However, the increase in aging rate is approximately tenfold higher for PET, implying that the segmental mobility of this polymer is significantly higher at the corresponding temperature.
The iniferter technique was applied to synthesis of the novel starlike C60 bonding polymers. Fullerene C60 with pendent N,N-diethyldithiocarbamate groups (C60-SR) was used as polyfunctional photoiniferter. The effects of UV irradiation time and ambient temperature on the molecular-weight of polymers were investigated. The photopolymerizations with C60-SR proceeded via a living radical mechanism, and gave soluble polyfunctional polymers (photoiniferters). Multiple polymer arms are attached the C60 core. C60-SR and the polymers obtained by C60-SR could also act as an excellent cross-linking agent.
There are many ways of optimizing the thermoforming process. However, any tuning of the processing parameters still remains a matter of experience. Using computer simulation software provides a way to explore various optimization possibilities without wasting machine production time, material and money through costly experiments. We have examined several methods of optimization using different materials, temperature, sheet thickness profiles and process parameters. For this purpose we have used the T-SIM® simulation program. This software uses a K-BKZ model capable to describe viscoelasticity and large deformation. The results of the simulations enable to determine which process parameters have the major influence and what are the pros and cons of each optimization method.
What is color? “The committee on colorimetry of the Optical Society of America has defined color as consisting of the characteristics of light other than spatial and temperal inhomogenities, light being that aspect of radiant energy of which a human observer is aware through the visual sensations which arise from the stimulation of the retina”(Ahmed, p.1) Simply stated color is what we “see the result of the physical modification of light by colorants as observed by the human eye and interpreted in the brain. Knowing what color is alone is not enough we must also understand how we perceive it. The Perception of color depends on many factors such as the inherent color characteristics of an object the surroundings of an object and even by such individual factors like past experience and individual visual response characteristics. (Ahmed p.2) In order to study color one must first learn to describe observed differences in color between two objects. This can be accomplished through the use of the following three variables: hue (dominant color) value (lightness vs. darkness) and chroma (saturation or purity of color). These variables are known as the color coordinates and form the basis of the language system used in color description and specification. (Ahmed p.5)"
What is color? “The committee on colorimetry of the Optical Society of America has defined color as consisting of the characteristics of light other than spatial and temperal inhomogenities, light being that aspect of radiant energy of which a human observer is aware through the visual sensations which arise from the stimulation of the retina”(Ahmed, p.1) Simply stated color is what we “see the result o fthe physical modification of light by colorants as observed by the human eye and interpreted in the brain. Knowing what color is alone is not enoughwe must also understand how we perceive it. The Perception of color depends on many factors such as the inherent color characteristics of an object the surroundings of an object and even by such individual factors like past experience and individual visual response characteristics. (Ahmed p.2) In order to study color one must first learn to describe observed differences in color between two objects. This can be accomplished through the use of the following three variables: hue (dominant color) value (lightness vs. darkness) and chroma (saturation or purity of color). These variables are known as the color coordinates and form the basis of the language system used in color description and specification. (Ahmed p.5)"
A.L. Kelly, M. Woodhead, R.M. Rose, P.D. Coates, May 1999
In-process rheometry (on-line & in-line) carried out during twin screw extrusion of several polyethylenes (LDPE, LLDPE and three HDPEs) is compared with conventional off-line rheometry for both shear and extensional properties. Use of two on-line and two off-line rheometers allowed comparison of data from a range of commercial instruments in order to validate their performances. In-process shear flow rheometry was undertaken using a six-sensor in-line extrusion die rheometer on a twin screw extruder. Results from the five rheometers were compared and good agreement observed between the different routes to measurement, for these relatively stable materials.
P.D. Coates, M. Matsuoka, M. Kamala, M. Martyn, May 1999
Flow visualisation has been undertaken using a specially designed flow cell mounted on a single screw extruder, which permits laser sheet lighting of selected planes in the flow. It has therefore been possible to quantify velocity fields and entry profiles in a 180 degree entry to a slit at locations across the flow, building up, for the first time, a quantified map of velocity components in the axial (x) and transverse (y) flow directions (including at the flow cell wall). Together with stress birefringence measurements, this allows accurate assessment of extensional viscosity, which has been compared with Rheometrics Meissner results for an LDPE. In addition, a modified cell has allowed visualisation of the slit entry region in the third orthogonal direction (z), leading to first ever observations of precession of an LDPE melt in its vortex region, providing new insights into the full 3-d flow field.
P.D. Coates, A.L. Kelly, M. Woodhead, A.J. Dawson, M. Martyn, N. Khoshooee, May 1999
Engineering polymers such as polyamides are known to be process-sensitive. In-process measurement of the flow behaviour of these polymers is therefore preferred over off-line measurements, for reliabilty of the information generated. In line rheometry studies for polyamides on a range of injection moulding machines (including servo electric and servo hydraulic) have been used successfully to monitor and quantify batch to batch variation in commercial polyamides. Specific injection pressure integrals were found to correlate well with product quality assessments. In addition, the effect of moisture content on in-process measurements in polyamides is also being investigated using a design of experiments approach: initial results suggest moisture content has a strong effect on variability of in-process measurements such as specific pressure integrals.
Bethany Ashworth, Jeremy Conley, Angelena Newman, May 1999
Plastics affect every aspect of our lives. Plastics is used and discarded everyday. What this theory addresses is how the use of discarded plastic has developed another method to recycle plastics material. Using plastic regrind in composite mixtures not only provides an alternative filler or reinforcement, but it also is a better way to recycle the discarded materials. Taking this theory into consideration, the Shawnee State University Plastics students developed a composite sidewalk using plastic regrind replacing the aggregate in concrete mixtures. The purpose of this paper is to discuss the installation and manufacturing techniques as well as the durability of the sidewalk over the past year.
K. Michailaros, P. Suwanmala, A. Klein, L.H. Sperling, May 1999
Polystyrene and poly (methyl methacrylate) latexes were prepared using conventional emulsion polymerization. The average diameter of both types of latex particles was close to 60 nanometers with a polydispersity index of 1.05. From the pure latex emulsions, blends were made of polystyrene and poly (methyl methacrylate) mixed according to different weight ratios. Samples of the latex blends as well as samples of both pure polymers were cleaned to remove remaining surfactant and subsequently dried. The dried latex powders were examined in a modulated differential scanning calorimeter so that the energy of film formation could be distinguished from the glass transition. A plot of energy of film formation versus composition shows a distinct minimum occurring at 74-weight % PMMA. The films formed under these conditions had between 10-70% of their surfaces obliterated by interfacial adhesion. A preliminary set of experiments using a high-resolution thermogravimetric analyzer of the latex blends in emulsion form indicates a body centered cubic packing structure for the latex particles.
Kim McLoughlin Senior Research Engineer, Global Materials Science Braskem
A Resin Supplier’s Perspective on Partnerships for the Circular Economy
About the Speaker
Kim drives technology programs at Braskem to develop advanced polyolefins with improved recyclability and sustainability. As Principal Investigator on a REMADE-funded collaboration, Kim leads a diverse industry-academic team that is developing a process to recycle elastomers as secondary feedstock. Kim has a PhD in Chemical Engineering from Cornell. She is an inventor on more than 25 patents and applications for novel polyolefin technologies. Kim is on the Board of Directors of SPE’s Thermoplastic Materials & Foams Division, where she has served as Education Chair and Councilor.
A Resin Supplier’s Perspective on Partnerships for the Circular Economy
About the Speaker
Gamini has a BS and PhD from Purdue University in Materials Engineering and Sustainability. He joined Penn State as a Post Doctorate Scholar in 2020 prior to his professorship appointment. He works closely with PA plastics manufacturers to implement sustainability programs in their plants.
A Resin Supplier’s Perspective on Partnerships for the Circular Economy
About the Speaker
Tom Giovannetti holds a Degree in Mechanical Engineering from The University of Tulsa and for the last 26 years has worked for Chevron Phillips Chemical Company. Tom started his plastics career by designing various injection molded products for the chemical industry including explosion proof plugs and receptacles, panel boards and detonation arrestors for 24 inch pipelines. Tom also holds a patent for design of a polyphenylene sulfide sleeve in a nylon coolant cross-over of an air intake manifold and is a Certified Plastic Technologist through the Society of Plastic Engineers. Tom serves on the Oklahoma Section Board as Councilor, is also the past president of the local Oklahoma SPE Section, and as well serves on the SPE Injection Molding Division board.
Joseph Lawrence, Ph.D. Senior Director and Research Professor University of Toledo
A Resin Supplier’s Perspective on Partnerships for the Circular Economy
About the Speaker
Dr. Joseph Lawrence is a Research Professor and Senior Director of the Polymer Institute and the Center for Materials and Sensor Characterization at the University of Toledo. He is a Chemical Engineer by training and after working in the process industry, he has been engaged in polymers and composites research for 18+ years. In the Polymer Institute he leads research on renewably sourced polymers, plastics recycling, and additive manufacturing. He is also the lead investigator of the Polyesters and Barrier Materials Research Consortium funded by industry. Dr. Lawrence has advised 20 graduate students, mentored 8 staff scientists and several undergraduate students. He is a peer reviewer in several journals, has authored 30+ peer-reviewed publications and serves on the board of the Injection Molding Division of SPE.
Matt Hammernik Northeast Account Manager Hasco America
A Resin Supplier’s Perspective on Partnerships for the Circular Economy
About the Speaker
Matt Hammernik serves as Hasco America’s Northeast Area Account Manager covering the states Michigan, Ohio, Indiana, and Kentucky. He started with Hasco America at the beginning of March 2022. Matt started in the Injection Mold Industry roughly 10 years ago as an estimator quoting injection mold base steel, components and machining. He advanced into outside sales and has been serving molders, mold builders and mold makers for about 7 years.
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How to reference articles from the SPE Library:
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