High strain deformation and ultimate failure of HIPS and ABS polymers

O'Connor, Bernard

January 1997

No description available.

620.11223

Numerical Model for the Lateral Compression Response of a Plastic Cup

Dapic, Ignacio

03 September 2003

A numerical analysis based on the finite element method is developed to simulate the mechanical response of a typical sixteen-ounce plastic drink cup subjected to a lateral compressive load. The aim of the analysis is to simulate a test in which the cup is supported horizontally in a fixture on a testing machine platen, and a loading nose attached to the actuator is displaced downward into the cup. The numerical model is developed using the software packages MSC.Patran, ABAQUS/CAE, and ABAQUS/Standard. The high impact polystyrene material of the cup is modeled as linear elastic, considering isotropic and orthotropic material behavior. The structural model of the cup is a truncated conical shell including a ring at the open end of the cup and circumferential stiffening ribs. The analysis is based on small strain, large rotation shell kinematics, and the loading apparatus of the test is simulated with a rigid, circular cylinder contacting the cup. Coupons cut from the wall of a cup are subjected to tension to determine the ranges of the meridional and circumferential moduli of elasticity. Rings cut from the open end of the cup were tested in diametrical tension to aid in validating the finite element modeling. Reasonable correlation of the simulation to available cup compression test data is achieved. Parametric studies are conducted for several meridional thickness distributions of the cup wall, and for a range of orthotropic material properties. / Master of Science

Finite element method

High Impact Polystyrene

truncated conical shell

Modelling the degradation processes in high-impact polystyrene during the first use and subsequent recycling

Vilaplana, Francisco

January 2007

<p>Polymers are subjected to physical and chemical changes during their processing, service life, and further recovery, and they may also interact with impurities that can alter their composition. These changes substantially modify the stabilisation mechanisms and mechanical properties of recycled polymers. Detailed knowledge about how the different stages of their life cycle affect the degree of degradation of polymeric materials is important when discussing their further waste recovery possibilities and the performance of recycled plastics. A dual-pronged experimental approach employing multiple processing and thermo-oxidation has been proposed to model the life cycle of recycled high-impact polystyrene (HIPS). Both reprocessing and thermo-oxidative degradation are responsible for coexistent physical and chemical effects (chain scission, crosslinking, apparition of oxidative moieties, polymeric chain rearrangements, and physical ageing) on the microstructure and morphology of polybutadiene (PB) and polystyrene (PS) phases; these effects ultimately influence the long-term stability, and the rheological and mechanical behaviour of HIPS. The PB phase has proved to be the initiation point of HIPS degradation throughout the life cycle. Thermo-oxidation seems to have more severe effects on HIPS properties; therefore, it can be concluded that previous service life may be the part of the life cycle with the greatest influence on the recycling possibilities and performance of HIPS recyclates in second-market applications. The results from the life cycle degradation simulation were compared with those obtained from real samples from a large-scale mechanical recycling plant. A combination of different analytical strategies (thermal analysis, vibrational spectroscopy, and chromatographic analysis) is necessary to obtain a detailed understanding of the quality of recycled HIPS as defined by three key properties: degree of mixing, degree of degradation, and presence of low molecular weight compounds.</p>

Polymer chemistry

Polymerkemi

Ativação superficial de poliestireno de alto impacto e polipropileno por plasmas dc de ar atmosférico e nitrogênio / Surface activation of high impact polystyrene and polypropylene by nitrogen and atmospheric air dc plasmas

Silva, Tiago Ghiggi Caetano da

28 May 2010

Made available in DSpace on 2016-12-08T17:19:35Z (GMT). No. of bitstreams: 1 Pre-textuais.pdf: 212246 bytes, checksum: 2486f89cad1425c52e00eedff44e22a0 (MD5) Previous issue date: 2010-05-28 / Coordenação de Aperfeiçoamento de Pessoal de Nível Superior / Among the treatment options for polymers surface modifications, the plasma technology has showed a wide potential due to its efficiency and low waste generation. Conventional chemical treatments by means of sulfochromic solutions and other solvents present risks to factory workers and additional costs with residues disposal.In this study, polypropylene and high impact polystyrene were treated with nitrogen and atmospheric air cold plasmas in different voltages and treatment times. The remaining parameters (process current and gas pressure) were kept constant. Surface tensions up to 89% higher than the untreated state were observed for polypropylene and up to 57 % for high impact polystyrene. The presence of nitrogen and oxygen based polar groups was detected by means of photoelectrons spectroscopy (XPS). In addition, physical changes on polymers surfaces were observed by scanning electrons spectroscopy (SEM).The adhesion tests carried out by means of pull-off technique on painted polypropylene treated with atmospheric air during 10 minutes showed an increase of 516% in pull-off pressures after activation treatments. / Entre as opções de tratamentos para a modificação de superfícies de polímeros, a tecnologia de plasmas é promissora pela eficiência e baixa geração de resíduos. Tratamentos químicos convencionais através de soluções sulfocrômicas e outros solventes representam riscos relacionados à segurança de operadores de fábrica e custos adicionais com o descarte de resíduos.Neste trabalho, amostras de polipropileno e poliestireno de alto impacto foram tratadas com plasmas de ar atmosférico e nitrogênio em diferentes voltagens (320 e 400V) e tempos de tratamentos (5; 10; 40, 70 minutos). Os demais parâmetros (corrente de processo e pressão de gás) foram mantidos constantes.Foram observados aumentos nos valores das tensões superficiais de até 89% para o polipropileno e 57% para poliestireno de alto impacto após os tratamentos. A presença de grupamentos polares a base de nitrogênio e oxigênio foram detectadas através de espectroscopia de fotoelétrons (XPS). Modificações físicas na superfície dos polímeros foram também observadas por microscopia eletrônica de varredura (MEV). Os testes de aderência conduzidos em amostras de polipropileno tratadas com ar atmosférico durante 10 minutos através da técnica pull-off, demonstraram aumentos nas pressões de arrancamento dos filmes de tinta da superfície do material de até 516% vezes após os processos de ativação.

Plasma dc

Polipropileno

Poliestireno de Alto Impacto

Tensão Superficial

Dc plasmas

Polypropylene

High impact polystyrene

Surface tension

Avaliação da utilização de Resíduos Eletroeletrônicos (REEE) incorporados ao concreto em substituição ao agregado graúdo / Evaluation of the use of Waste Electro-Electronic (WEEE) incorporated to the concrete in substitution to the large aggregate

Almeida, Flávia Florentino de [UNESP]

30 August 2017

Submitted by FLÁVIA FLORENTINO DE ALMEIDA null (flavialm_1@hotmail.com) on 2017-10-09T15:23:59Z No. of bitstreams: 1 Flavia Final rev 09. ...02.10.17_word2010.pdf: 3209005 bytes, checksum: c3164cf910a07e38e30d2c81a62eb29f (MD5) / Approved for entry into archive by Monique Sasaki (sayumi_sasaki@hotmail.com) on 2017-10-09T18:53:36Z (GMT) No. of bitstreams: 1 almeida_ff_me_bauru.pdf: 3209005 bytes, checksum: c3164cf910a07e38e30d2c81a62eb29f (MD5) / Made available in DSpace on 2017-10-09T18:53:36Z (GMT). No. of bitstreams: 1 almeida_ff_me_bauru.pdf: 3209005 bytes, checksum: c3164cf910a07e38e30d2c81a62eb29f (MD5) Previous issue date: 2017-08-30 / Coordenação de Aperfeiçoamento de Pessoal de Nível Superior (CAPES) / Uma das alternativas para a destinação de Resíduos de Equipamentos Eletroeletrônicos (REEE), termo adotado no Brasil e tradução literal do inglês Waste Eletronic and Electrical Equipament (WEEE), é a reciclagem. Em geral os metais presentes nesses resíduos apresentam maior interesse para as recicladoras, porém as carcaças dos equipamentos constituídas por polímeros acabam sendo destinadas a aterros. O presente trabalho apresenta uma forma simples e barata de se agregar valor a esse resíduo, tornando-o mais vantajoso financeiramente. Um estudo do comportamento do concreto com adição de polímeros fracionados provenientes de carcaças de equipamentos eletroeletrônicos descartados em substituição a parte do agregado graúdo é apresentado. Para isso foi feita a caracterização dos polímeros proveniente do REEE e foi estudado o comportamento de corpos de prova produzidos com adição de 5%, 8%, 10%, 15% e 20% em massa desse resíduo, mantendo um traço sem incorporação para comparação. O agregado graúdo obtido a partir dos polímeros advindos do REEE tem predominância da sua granulometria na faixa dos 6,3 mm, são identificados como sendo constituídos por HIPS (High Impact Polystyrene), e apresentam-se como material hidrofílico possibilitando boa interação com argamassa de cimento e água. Os concretos obtidos com até 20% de incorporação desse resíduo apresentam densidade superior a 2,0g/cm3, permitindo classifica-los como um concreto estrutural normal. O aumento da porcentagem de incorporação de REEE ao concreto leva a uma diminuição da resistência a compressão, porém esse valor é sempre superior a 20 MPa, identificando-o como um concreto de resistência média. A incorporação desse resíduo, devido ao seu formato, contribui com uma característica semelhante a de utilização de fibras em concreto impedindo o rompimento completo dos corpos. Esses resultados evidenciam a viabilidade de se incorporar REEE ao concreto, possibilitando uma valorização desse resíduo como agregado graúdo para concreto. / One of the alternatives for the disposal of Waste Electrical and Electronic Equipment (WEEE), is recycling. In general, the metals present in these wastes are of greater interest to recyclers, but the carcasses of equipment made of polymers end up being destined to landfills. The present paper presents a simple and inexpensive way to add value to this waste, making it more advantageous financially. A study on the behavior of concrete with addition of fractionated polymers from carcasses of discarded electro-electronic equipment replacing part of the large aggregate is presented. For this, was done the characterization of the polymers from WEEE and analyzed the behavior of test specimens produced with addition of 5%, 8%, 10%, 15% and 20% in mass of this residue, maintaining a trace without incorporation for comparison. The large aggregate obtained from the WEEE polymers has a predominance of their granulometry in the range of 6.3 mm. They are identified as HIPS (High Impact Polystyrene) and are presented as a hydrophilic material allowing a good interaction with cement and water. The concretes obtained with up to 20% of incorporation of this residue present density superior to 2,0 g / cm3, allowing to classify them like a normal structural concrete. The increase in the percentage of incorporation of WEEE into the concrete leads to a decrease in the compressive strength, but this value is always higher than 20 MPa, identifying it as a medium-strength concrete. The incorporation of this residue, due to its shape, contributes with a characteristic similar to the use of fibers in concrete preventing the complete rupture of the bodies. These results demonstrate the feasibility of incorporating WEEE into the concrete, allowing a valorization of this waste as a large aggregate for concrete.

Concreto

Propriedades mecânicas

Cimento Portland

Poliestireno de alto impacto

Concrete

Mechanical properties

Portland cement

High impact polystyrene

Analytical strategies for the quality assessment of recycled high-impact polystyrene (HIPS)

Vilaplana Domingo, Francisco Javier

30 May 2008

Polymers are subjected to physical and chemical changes during their processing, service life, and further recovery, and they may also interact with impurities that can alter their composition. These changes substantially modify the stabilisation mechanisms and mechanical properties of recycled polymers. The assessment of the quality properties of recycled polymers is therefore crucial to guarantee the performance of recyclates in further applications. Three key quality properties have been defined for this quality analysis: degree of mixing (composition), degree of degradation, and presence of low molecular weight compounds (degradation products, contaminants, additives). Furthermore, detailed knowledge about how the different stages of their life cycle affect the degree of degradation of polymeric materials is important when discussing their further waste recovery possibilities and the performance of recycled plastics. A dual-pronged experimental approach employing multiple processing and thermo-oxidation has been proposed to model the life cycle of recycled high-impact polystyrene (HIPS used in packaging applications, and electrical and electronic equipment (E&E). Both reprocessing and thermo-oxidative degradation are responsible for coexistent physical and chemical effects (chain scission, crosslinking, apparition of oxidative moieties, polymeric chain rearrangements, and physical ageing) on the microstructure and morphology of polybutadiene (PB) and polystyrene (PS) phases; these effects ultimately influence the long-term stability, and the rheological and mechanical behaviour of HIPS. The PB phase has proved to be the initiation point of HIPS degradation throughout the life cycle. Thermo-oxidation seems to have more severe effects on HIPS properties; therefore, it can be concluded that previous service life may be the part of the life cycle with the greatest influence on the recycling possibilities and performance of HIPS recyclates in second-market applicat / Vilaplana Domingo, FJ. (2008). Analytical strategies for the quality assessment of recycled high-impact polystyrene (HIPS) [Tesis doctoral no publicada]. Universitat Politècnica de València. https://doi.org/10.4995/Thesis/10251/2186 / Palancia

Thermo-oxidation

Recycling

High-impact polystyrene

Quality analysis

Degradation

Reprocessing

Brominated flame retardants

MAQUINAS Y MOTORES TERMICOS

230416 - Análisis de polímeros

331210 - Plásticos

Modelling the degradation processes in high-impact polystyrene during the first use and subsequent recycling

Vilaplana, Francisco

January 2007

Polymers are subjected to physical and chemical changes during their processing, service life, and further recovery, and they may also interact with impurities that can alter their composition. These changes substantially modify the stabilisation mechanisms and mechanical properties of recycled polymers. Detailed knowledge about how the different stages of their life cycle affect the degree of degradation of polymeric materials is important when discussing their further waste recovery possibilities and the performance of recycled plastics. A dual-pronged experimental approach employing multiple processing and thermo-oxidation has been proposed to model the life cycle of recycled high-impact polystyrene (HIPS). Both reprocessing and thermo-oxidative degradation are responsible for coexistent physical and chemical effects (chain scission, crosslinking, apparition of oxidative moieties, polymeric chain rearrangements, and physical ageing) on the microstructure and morphology of polybutadiene (PB) and polystyrene (PS) phases; these effects ultimately influence the long-term stability, and the rheological and mechanical behaviour of HIPS. The PB phase has proved to be the initiation point of HIPS degradation throughout the life cycle. Thermo-oxidation seems to have more severe effects on HIPS properties; therefore, it can be concluded that previous service life may be the part of the life cycle with the greatest influence on the recycling possibilities and performance of HIPS recyclates in second-market applications. The results from the life cycle degradation simulation were compared with those obtained from real samples from a large-scale mechanical recycling plant. A combination of different analytical strategies (thermal analysis, vibrational spectroscopy, and chromatographic analysis) is necessary to obtain a detailed understanding of the quality of recycled HIPS as defined by three key properties: degree of mixing, degree of degradation, and presence of low molecular weight compounds. / QC 20101119

Polymer Chemistry

Polymerkemi

Reciclagem do copolímero acrilonitrila-butadieno-estireno e do poliestireno de alto impacto oriundos de rejeitos de equipamentos elétricos e eletrônicos na forma de blendas poliméricas / Recycling of copolymer acrylonitrile-butadiene-styrene and high impact polystyrene from waste electrical and electronic equipment in the form of polymer blends

Hirayama, Denise

14 August 2015

O crescimento na geração de rejeitos de equipamentos elétricos e eletrônicos (REEE), legislações mais rigorosas e o valor agregado destes materiais incentivam o desenvolvimento de tecnologias de reciclagem. Contudo, a reciclagem dos componentes poliméricos dos REEE (CP-REEE) precisa superar desafios como a degradação durante o uso e reprocessamento, a presença de diferentes aditivos nos rejeitos e a depreciação de propriedades causada pela mistura não controlada de polímeros. Assim, o objetivo deste trabalho foi desenvolver um estudo sobre a reciclagem mecânica na forma de blendas poliméricas de rejeitos do copolímero acrilonitrila-butadieno-estireno (ABS) e do poliestireno de alto impacto (HIPS), empregando agentes compatibilizantes. No desenvolvimento do trabalho foram realizadas a caracterização dos CP-REEE, análise das propriedades mecânicas, químicas, térmicas e morfológicas dos polímeros e das blendas de ABS/HIPS nas proporções de 1:3, 1:1 e 3:1 com variações na composição dos polímeros reciclados e virgens e por fim, realizado um estudo do envelhecimento foto-oxidativo acelerado de uma blenda ABS/HIPS. Os resultados mostraram que os polímeros ABS e HIPS reciclados ainda apresentam boas propriedades mecânicas e que a presença de agentes compatibilizantes provoca o aumento da tenacidade nas blendas ABS/HIPS. A incorporação de polímeros virgens nos materiais reciclados não promove ganho significativo nas propriedades mecânicas das blendas. Blendas com até 50% de ABS demonstraram ter propriedades próximas às do HIPS, enquanto as blendas com altos teores de ABS não alcançaram valores de propriedades mecânicas similares aos do ABS virgem. O comportamento das propriedades das blendas virgens e recicladas frente ao envelhecimento fotoquímico foi similar, indicando que o material reciclado apresenta grande potencial para aplicações. O estudo de blendas ABS/HIPS de CP-REEE demonstra que o controle da composição das blendas definem a sua aplicação. / The growth in waste electrical and electronic equipment (WEEE) generation, directives more stringent and the aggregate value presents in these waste are encouraging the development of recycling technologies. However, recycling of polymeric components from WEEE (PC-WEEE) must overcome challenges such as degradation during use and reprocessing, the presence of various additives in the waste and the depreciation of properties caused by uncontrolled polymers mixture. The aim of this work was to develop a study of the mechanical recycling in the form blends with of polymeric waste of acrylonitrile-butadiene-styrene copolymer blends (ABS) and high impact polystyrene (HIPS) using compatibilizers. During the study was carried out the characterization of the PCWEEE and mechanical, chemical, thermal and morphological analysis of the polymers and the ABS / HIPS blends in proportions of 1:3, 1:1 and 3:1 with recycled and virgin polymers, as well as a study of the accelerated photo-oxidative aging of the ABS/HIPS blends. The results showed that ABS and HIPS recycled polymers still have good mechanical properties and the presence of compatibilization agents leads to increased toughness in ABS/HIPS blends. The incorporation of virgin polymers in recycled materials does not promote significant gain in the mechanical properties of the blends. Blends with up to 50% ABS have demonstrated to be closer to the HIPS, while blends with high content of ABS did not reach values of mechanical properties similar to the virgin ABS. The mechanical properties of virgin and recycled blends during the photochemical aging were similar, indicating that the recycled material has great potential for applications. The study of ABS/HIPS blends from PC-WEEE demonstrated that control of the blend composition establish their applications.

High impact polystyrene (HIPS)

Poliestireno de alto impacto (HIPS)

Reciclagem e compatibilizante

Recycling and compatibilizer

Reciclagem do copolímero acrilonitrila-butadieno-estireno e do poliestireno de alto impacto oriundos de rejeitos de equipamentos elétricos e eletrônicos na forma de blendas poliméricas / Recycling of copolymer acrylonitrile-butadiene-styrene and high impact polystyrene from waste electrical and electronic equipment in the form of polymer blends

Denise Hirayama

14 August 2015

O crescimento na geração de rejeitos de equipamentos elétricos e eletrônicos (REEE), legislações mais rigorosas e o valor agregado destes materiais incentivam o desenvolvimento de tecnologias de reciclagem. Contudo, a reciclagem dos componentes poliméricos dos REEE (CP-REEE) precisa superar desafios como a degradação durante o uso e reprocessamento, a presença de diferentes aditivos nos rejeitos e a depreciação de propriedades causada pela mistura não controlada de polímeros. Assim, o objetivo deste trabalho foi desenvolver um estudo sobre a reciclagem mecânica na forma de blendas poliméricas de rejeitos do copolímero acrilonitrila-butadieno-estireno (ABS) e do poliestireno de alto impacto (HIPS), empregando agentes compatibilizantes. No desenvolvimento do trabalho foram realizadas a caracterização dos CP-REEE, análise das propriedades mecânicas, químicas, térmicas e morfológicas dos polímeros e das blendas de ABS/HIPS nas proporções de 1:3, 1:1 e 3:1 com variações na composição dos polímeros reciclados e virgens e por fim, realizado um estudo do envelhecimento foto-oxidativo acelerado de uma blenda ABS/HIPS. Os resultados mostraram que os polímeros ABS e HIPS reciclados ainda apresentam boas propriedades mecânicas e que a presença de agentes compatibilizantes provoca o aumento da tenacidade nas blendas ABS/HIPS. A incorporação de polímeros virgens nos materiais reciclados não promove ganho significativo nas propriedades mecânicas das blendas. Blendas com até 50% de ABS demonstraram ter propriedades próximas às do HIPS, enquanto as blendas com altos teores de ABS não alcançaram valores de propriedades mecânicas similares aos do ABS virgem. O comportamento das propriedades das blendas virgens e recicladas frente ao envelhecimento fotoquímico foi similar, indicando que o material reciclado apresenta grande potencial para aplicações. O estudo de blendas ABS/HIPS de CP-REEE demonstra que o controle da composição das blendas definem a sua aplicação. / The growth in waste electrical and electronic equipment (WEEE) generation, directives more stringent and the aggregate value presents in these waste are encouraging the development of recycling technologies. However, recycling of polymeric components from WEEE (PC-WEEE) must overcome challenges such as degradation during use and reprocessing, the presence of various additives in the waste and the depreciation of properties caused by uncontrolled polymers mixture. The aim of this work was to develop a study of the mechanical recycling in the form blends with of polymeric waste of acrylonitrile-butadiene-styrene copolymer blends (ABS) and high impact polystyrene (HIPS) using compatibilizers. During the study was carried out the characterization of the PCWEEE and mechanical, chemical, thermal and morphological analysis of the polymers and the ABS / HIPS blends in proportions of 1:3, 1:1 and 3:1 with recycled and virgin polymers, as well as a study of the accelerated photo-oxidative aging of the ABS/HIPS blends. The results showed that ABS and HIPS recycled polymers still have good mechanical properties and the presence of compatibilization agents leads to increased toughness in ABS/HIPS blends. The incorporation of virgin polymers in recycled materials does not promote significant gain in the mechanical properties of the blends. Blends with up to 50% ABS have demonstrated to be closer to the HIPS, while blends with high content of ABS did not reach values of mechanical properties similar to the virgin ABS. The mechanical properties of virgin and recycled blends during the photochemical aging were similar, indicating that the recycled material has great potential for applications. The study of ABS/HIPS blends from PC-WEEE demonstrated that control of the blend composition establish their applications.

Poliestireno de alto impacto (HIPS)

Reciclagem e compatibilizante

High impact polystyrene (HIPS)

Recycling and compatibilizer