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.
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Various topics related to sustainability in plastics, including bio-related, environmental issues, green, recycling, renewal, re-use and sustainability.
Alan J. Lesser, Xianbo Hu, Peter J. Walsh, May 2005
Recent reports have shown the fibers made from polyp- phylenebenzobisoxazole show a significant reduction in properties after relatively mild exposure to environmental conditions. This paper discusses potential mechanisms responsible for the degradation and reports results on degradation of fiber properties due to various environmental exposure conditions.
This paper presents an investigation on the design and optimization of plastic milk crates using the finite element method (FEM) with the aim of reducing the mass and simplifying the shape of a standard milk crate. The paper also explores the possibility of manufacturing such milk crates using recycled High Density Polyethylene (HDPE) instead of virgin HDPE or virgin polypropylene (PP) to make it more cost effective.
Responding to environmental, sustainability, business and market needs, DuPont has recently commercialized a new polymer platform Sorona®. Sorona® polymer is produced from fiber-grade 1,3- propanediol (PDO). It is a linear semi-crystalline polymer with a melting temperature of ~228°C and a glass transition temperature of about 50°C. (See Figure 1)
Four case studies are presented to illustrate environmental stress cracking (ESC) within automotive components. ESC is a very important mode of plastic component failure. The presented cases illustrate how the failure analysis process was used to identify the failure mechanism as well as the primary factors responsible for the failures. The four cases depict representative automotive failures involving varied designs and service conditions.
A wide variety of bioactive composites for bone regeneration have been developed and investigated over the last decades. In order to promote bioactivity, certain types of glasses, ceramics and minerals are incorporated into biodegradable or biostable polymers. In this study, several established and novel fillers such as calcium phosphates, silicates and glasses were screened for bioactivity. Promising candidates were then incorporated into two different grades of poly-?-caprolactone by solution mixing, and testing was conducted in a simulated body fluid to determine in vitro bioactivity. At different time periods the exposed samples were characterized by SEM, EDX and FTIR microscopy in order to investigate the formation of the apatite layer needed for bone ingrowth. The screening results of this work produced suitable polymer/filler combinations for further in vitro and in vivo testing in different types of tissue engineering applications.
It has been found that some thermoplastic systems survive accelerated UV weathering but fail in true environmental conditions. This is because quartz filters pass artificially high levels of 275 nm - 340 nm light, but artificially lower levels of longer wavelengths. For systems that are more reactive to longer wavelengths, the accelerated exposure tests provide false assurances of true weatherability. A specific example of this phenomenon occurring within polypropylene will be shown and discussed in detail.
This work probes a hypothesis for initiation of environmental stress cracking (ESCR) based on a thermodynamic criterion for localized stress induced swelling. The threshold metric involves observation of solid-vapor surface energy and contact angle of a liquid on a loaded polymer substrate and thus inference of solidliquid interfacial surface energy with respect to substrate stress. The intent is to develop a screening technique for ESCR that is not limited by the kinetics of the crazing event.
Amar K Mohanty, Hiroaki Miyagawa, Rigoberto Burgueno, Manjusri Misra, May 2005
Biobased neat unsaturated polyester materials containing epoxidized methyl soyate (EMS) and their clay nanocomposites were processed with cobalt naphthenate as a promoter and 2-butanone peroxide as an initiator. A certain amount of unsaturated polyester resin (UPE) was replaced by EMS. The combination of the UPE and EMS resulted in an excellent combination, to a new biobased thermoset material showing relatively high elastic modulus and the constant glass transition temperature with up to 25 wt.% replacements with EMS. Izod impact strength was almost constant while changing the amount of EMS and adding clay nanoplatelets.
Tongnian Li, Shaoqin Gong, Lih-Sheng Turng, May 2005
Three types of polylactide (PLA) composites, namely, PLA/nanoclay, PLA/core-shell rubber, and PLA/nanoclay/ core-shell rubber were melt compounded via a co-rotating twin-screw extruder. The effects of two types of organically modified nanoclay (i.e., Cloisite®30B and 20A), two types of core-shell rubber (i.e., Paraloid EXL2330 and EXL2314), and the combination of nanoclay and rubber on the mechanical properties of the composites were investigated. In comparison with pure PLA, both types of PLA/5wt% nanoclay composites showed an increased modulus, a slightly reduced tensile strength, a similar impact strength, and a significantly reduced strain at break. PLA/EXL2330 composites with a rubber loading level of 10wt% or higher exhibited much higher impact strength but lower modulus and strength when compared to pure PLA. The simultaneous addition of 5wt% nanoclay (Cloisite®30B) and 20wt% EXL2330 resulted in a PLA composite with a 134% increase in impact strength, a 6% increase in strain at break, a similar modulus, and a 28% reduction in tensile strength as compared to pure PLA.
Lawrence T. Drzal, Manju Misra, Amar Mohanty, May 2005
Polymeric and composite materials from plant derived fiber (Natural/Bio-fiber) and crop-derived plastics (Bio-plastic) are novel materials of the 21st century and have the potential to be of great importance to the materials world, not only as a solution to growing environmental threat but also as a solution to alleviating the uncertainty of petroleum supply. As this new generation of biobased polymers enters the commercial market, success in competing with established petroleum based polymers will depend on their performance, properties and cost as determined primarily in the commercial marketplace. While environmental consciousness continues to grow, and some governmental programs have been established to assist with the entrée of biobased materials into the marketplace. E.g., the US Research and Development Act of 2000 along with Presidential Executive Orders 13134 & 13104 and the “Farm Bill” signed by President Bush on May 13, 2002, have a goal of achieving a performance/cost ratio competitive with petroleum-based polymers for value-added applications. The technology road map for plant/crop-based renewable resources 2020, sponsored by the U.S. Department of Agriculture (USDA) and the U.S. Department of Energy (DOE), has set a goal of increasing the utilization of basic chemicals from biobased renewable resources of 10% by 2020, and further increase to 50% by 2050.While the chemistry, reaction pathways and processing steps to producing biobased chemicals and polymers are relatively straight forward, it is the use of these materials in high performance, value-added applications that will be critically important to achieve sustainability and economic viability. The most promising path to achieve sustainability and economic viability is through the addition of biofibers to biobased polymers to produce biocomposites. Research underway in the Composite Materials and Structures Center at Michigan State University and other Universities has been directed at defining, de
Stephen P. McCarthy, Balint Koroskenyi, Robert J. Nicolosi, May 2005
Diabetes is one of most common and widespread diseases. As high as 6% of the world population suffers from diabetes, which, including its complications, is the fourth most important cause of mortality and the main cause of permanent blindness. In the United States alone, 16 million people, nearly one in 17 people, have diabetes. More than 2,000 new cases are diagnosed every day. Most patients require three to four injections of insulin a day. In addition to patient compliance problems, chronic subcutaneous injection may cause side effects, such as lipoatrophy or lipohypertrophy. Oral delivery of insulin has been elusive due to acidic and enzymatic degradation of insulin in the gastrointestinal tract.Oral delivery of insulin is more preferable to subcutaneous injections, because it may provide a better glucose homeostasis and decrease the chances of peripheral hyperinsulinaemia, which is linked to neuropathy and retinoendopathy. Successful oral delivery has not been achieved due to various challenges regarding the sustainability of peptides in the gastrointestinal tract. Typical oral bioavailability of proteins is generally less than 1-2 % because of the numerous physiological barriers in the digestive tract. Ingested proteins become subjected to acidic degradation in the stomach, luminal degradation by enzymes in the intestine, and intracellular degradation. Since proteins are built with peptide linkages, they are susceptible to acidic degradation. It has been shown that some proteins do have some bioavailability when administered directly into the intestine, bypassing the acidic milieu of the stomach. [1] Various polymer matrices have been designed for enteric coatings with adequate pH-response to protect insulin in the stomach. Polyacrylates Eudragit RS1 and RS2 showed bioavailabilities of 9.3-12.7 % due to their ability to release insulin further down in the gastrointestinal tract at pH 7.5-8.0.[2] Polymer nanospheres have been studied for oral delivery. Accordin
Surface quality of profile extruded from recycled uPVC has been examined using a novel on-line visualization system and surface interferometry. A calibrated strip profile was extruded from various grades of recycled uPVC window frame. Surface defects were monitored using a high-frequency line-scan camera and categorised in terms of size, shape and position. Surface roughness was measured using a white light interferometer. PVC recovery method, batch variation and processing conditions were found to affect surface quality of the extrudate.
Gang Li, Pierre Sarazin, Zhenhua Yuan, Basil D. Favis, May 2005
Polycaprolactone (PCL)/thermoplastic starch (TPS) biodegradable blends were prepared via a one-step extrusion system over the entire range of composition at different viscosity ratios. A detailed morphology analysis of the PCL/TPS blends was investigated by electron microscopy after selective extraction. Through a judicious combination of concentration control and processing conditions, the volume average diameter of TPS droplets can be closely controlled from 0.5 to 16?m. The rheological behavior of these blends is also examined in depth.
Jessica Z. Bielawski, Matthew Boshar, Joseph Morano, May 2005
In this study the co-extrusion and use of a cyclicalpha olefin and metallocene polyethylene for medical and packaging applications was investigated. The combination of these materials are cost competitive and provides the opportunities for an environmentally friendly disposal and possible recycling. A film with alternating polyethylene, cyclic- alpha olefin, and polyethylene layers was coextruded with the use of three extruders leading into a multi-layer feedblock. The film was tested for oxygen and water permeability, tensile properties, falling dart impact strength, and tear strength. An economic analysis of the fabrication of the film for the use in medical and packaging applications was also constructed. The study demonstrated that the co-extrusion of a cyclo-olefin and metallocene polyethylene provides an opportunity for environmental means of disposal and a means of fabrication.
Helmut Potente, Wolfgang Ernst, Jörg Oblotzki, May 2005
Some polymers based on renewable resources like starch containing materials can be plasticated by extrusion processing. Foams based on theses materials have an increasing importance in packaging applications, but also insulation materials have been developed. Starch contains water, which can work as a physical blowing agent for processing of these foams. The foaming process depends on process parameters like the pressure gradient in the die as well as on material properties like rheology. The main target is the production of foams with low density, high expansion ratio and a homogenous cell structure.The foaming process starts in the flow channel of the die. The cell nucleation process can be investigated by a die design with transparent inserts in the flow channel. The influence of process parameters on cell nucleation was determined. It could be shown that a higher pressure gradient in the die leads to a higher expansion ratio and thus to a later cell nucleation.Furthermore, the rheological properties also have an impact on the foaming behavior of molten starch. Shear viscosity is influenced by melt temperature, water content and mechanical energy input during the extrusion process. In this work, the dependency of the flow properties on process parameters was investigated in order to quantify the differences in pressure build-up caused by changes in screw speed and the resulting consequences on viscosity.
The chemical structure of crosslinked polyethylene (PEX) prevents easy reprocessability. Crosslinking of the polymer backbone covalently bonds it to another polymer chain. This bond prevents chain slippage and therefore any further melt processing. With an increase in time or temperature the crosslinking reaction will proceed, increasing its molecular weight to a point where it can not be processed a second time. The objective of this research is to determine a time window such that the crosslinked material can be reground and reprocessed using conventional melt processing equipment before the crosslinking reaction proceeds to a point where the material becomes unprocessable.
Lluís Cabedo, José L. Feijoo, José Ma. Lagarón, Juan J. Saura, Enrique Giménez, May 2005
Biodegradable blends of amorphous Poly(lactic acid) (PLA) and polycaprolactone (PCL) have been developed by melt blending. The morphology of these materials was characterized by means of WAXD and TEM, showing that silicate layers of the kaolinite (chemically modified kaolinite) were intercalated and evenly distributed within the biodegradable matrix. Mechanical, thermal and gas barrier properties of the different blends and nanocomposites were studied and the effect of clay addition on the above-mentioned properties was evaluated.
Extensive use of plastic products in a country like the Czech Republic make the recycling of plastic unavoidable. This also is influenced by a host of factors such as increasing price of raw materials (oil and other semi processed products), growing concern for ecology and environment, etc. However, recycling is not only the technology alone, but it also includes issues such as legislation, both social and most importantly economics. The present study attempts to describe the economic conditions that influence the performance of plastic recycling companies. The paper analyses the conditions of development of plastic recycling companies in the Czech Republic using Economic Value Added (EVA) indicator.
Jérôme Burlet, Marie-Claude Heuzey, Charles Dubois, Paula Wood-Adams, Josée Brisson, May 2005
Polylactide (PLA) polymers are among the most promising plastic made from renewable resources. Thermal stablization of these polymers remains a challenging issue of their industrial processing. We have studied the effect of TNPP in the scope of preventing the molecular weight reduction of PLA at its processing temperature. The stabilizing effect of TNPP was found to strongly depend on the concentration used.
In the last few years, UV curable coatings have gained great interest among numerous automotive OEMs and finishers because it allows for more efficient manufacturing, improved performance properties and an overall more environmentally friendly process. In consideration of this interest, the automotive lighting sector should be evaluated as a benchmark for early UV technology success as well as continued innovation in terms of appearance, performance and processing advantages.
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Any article that is cited in another manuscript or other work is required to use the correct reference style. Below is an example of the reference style for SPE articles:
Brown, H. L. and Jones, D. H. 2016, May.
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