Part Cooling Analysis By Conformal Cooling Channels In Injection Molding

Ozmen, Emin Mehmet

01 December 2007

Straight cooling channels are the most common method of controlling part temperature in injection molding process. However, straight cooling channels are not enough to manage temperature uniformity of the parts. In this work, a numerical study is conducted to decrease cycle time and cost of the injection molded parts by using conformal cooling channels. For this purpose, the commercial injection molding simulation program Moldflow is used. The governing physical equations for injection molding were derived and presented. The assumptions of the model were checked for simple geometries by comparing analytical results and numerical results of Moldflow. Then, the effect of conformal cooling channels is investigated for injection molding of a half cylinder shell part. It was seen that conformal cooling channels cools part faster and more uniform than straight cooling channels without corruption on the surface appearance. Finally, a real life case study was presented. For this purpose, a refrigerator shelf that is manufactured by the Ar&ccedil / elik Company was studied. The process was simulated using actual process parameters and simulation results were compared with production results. Then, the process was simulated using conformal cooling channels and compared with production results. It is seen that the cycle time of the refrigerator shelf was decreased considerably while preserving surface quality appearance.

LB Academic Degrees 2381-2391

Simulation of the Filling Process in Micro-Injection Moulding

Jüttner, Gabor, Nguyen-Chung, Tham, Mennig, Günter, Gehde, Michael

20 August 2008

Nowadays, the filling and solidification of macro-scale injection mouldings can be predicted using commercial CAE software. For micro-injection moulding, the conventional tools do not work for all process conditions. The reasons might be the lack of high quality database used in the simulation and the improperly specified boundary conditions which do not reflect the real state in the cavity. Special aspects like surface tension or "size dependent" viscosity might also be responsible for the inaccuracy of the simulations. In this paper, those aspects related to the boundary conditions were taken into consideration, especially the thermal contact behaviour and the melt compression in the barrel which affects not only the temperature of the melt due to the compression heating, but also reduces the actual volume rate in the cavity. It can be shown that the heat transfer coefficient between the melt and the mould wall has a significant influence on the simulation results. In combination with precise material data and considering the reduction of the volume rate due to the melt compression in the barrel, the heat transfer coefficient may be quantified by means of reverse engineering. In general, it decreases when either the cavity thickness or the injection speed increases. It is believed that a pressure dependent model for the heat transfer coefficient would be more suitable to describe the thermal contact behaviour in micro injection moulding. The melt compression in the barrel affects definitely the filling behaviour and subsequently the heat transfer in the cavity as well, which is especially true for micro parts of high aspect ratio.

Heat transfer coefficient

Micro-injection molding

Simulation

ddc:600

Kunststoffverarbeitung

Spritzgießen

A study on the marketing of injection moulding machines : an analysis of the buying behaviour of industrial buyers /

Chung, Kwok Kwong, Albert.

January 1980

Thesis (M.B.A.)--University of Hong Kong, 1980.

Compression/injection molding of bipolar plates for proton exchange membrane fuel cells

Devaraj, Vikram

30 July 2012

Fuel cells are electrochemical energy conversion devices that convert chemical energy to electrical energy efficiently. Bipolar plates form an integral part of a fuel cell and their high manufacturing cost and low production rate have hindered the commercialization of fuel cells. Bipolar plates require high electrical conductivity, strength, chemical resistance and thermal conductivity. This thesis presents efforts to manufacture bipolar plates which meet these requirements using compression or injection molding. Compression or injection molding processes allow cost-effective, large-scale manufacturing of bipolar plates. A variety of material systems for the fabrication of bipolar plates are processed, molded and characterized. / text

Bipolar plate

Compression molding

Injection molding

Fuel cell

Methanol

Phenolic

Graphite

An expert product development system for plastic injection moulding parts

錢桂生, Chin, Kwai-sang.

January 1996

published_or_final_version / Industrial and Manufacturing Systems Engineering / Doctoral / Doctor of Philosophy

Expert systems (Computer science)

Plastics - Molding - Data processing.

Microprocessor control system for the injection molding process

Haber, Andrew.

January 1982

No description available.

Microprocessors.

Étude de l'effet des colorants sur les propriétés d'un thermoplastique, volume 1 /

Riou, Marcel.

January 1987

Mémoire (M. Sc. A.) --Université du Québec à Chicoutimi , 1987. / Bibliogr. : ff. xvii-xviii. Document électronique également accessible en format PDF. CaQCU

Optimizing flow of plastic PBT with 45% glass and mineral fiber reinforcement in an injection over mold process using Taguchi, CPk and mold flow simulation software approaches

Sanchez Urbina, Israel.

January 2009

Thesis (M.S.)--University of Texas at El Paso, 2009. / Title from title screen. Vita. CD-ROM. Includes bibliographical references. Also available online.

Rapid Tooling and the LOMOLD Process

Joubert, Francois

12 1900

Thesis (MScEng (Industrial Engineering))--University of Stellenbosch, 2005. / The LOMOLD process is a new plastic moulding process being researched at the University of Stellenbosch. The process essentially combines injection moulding and compression moulding. Molten plastic is forced into the mould cavity using a plunger. This plunger then forms part of the cavity wall. The plunger face must therefore follow the geometry of the part. Rapid Tooling evolved from Rapid Prototyping. There are two categories of Rapid Tooling: indirect and direct rapid tools. Indirect rapid tools are manufactured by using a master pattern to form the mould cavity. The accuracy of the mould cavity depends heavily on the accuracy of the master pattern. The master pattern is usually produced using Rapid Prototyping technology. Direct rapid tools use Rapid Prototyping technology to build the mould through and additive, layer by layer process or a subtractive process. This research investigates the use of Rapid Tools for the LOMOLD process. Aluminium Filled Epoxy Tooling (AFET) represents the indirect technology and CNC-machined tooling the direct technology. Both of these technologies are available at the University of Stellenbosch. Parts are manufactured on these tools using an experimental LOMOLD machine. These two technologies are compared in terms of part accuracy, tool lead time, tool cost and part cost. The research concluded that the only advantage the AFET has over the CNC-machined tool is a shorter manufacturing lead-time. In terms of tool cost, tool life, part geometric accuracy, part cost and cycle time the CNC tool is superior. Therefore the application of AFET is limited to small volume, prototype or pre-production runs for tool design confirmation, part functional testing and part appearance testing. It is also demonstrated that a cooling system on the AFET tool has no significant influence on the tool performance and should therefore, especially for production runs less than 150 parts, not be included in the tool to save on tool cost. Another conclusion is that the LOMOLD process is not consistent enough for a production process. This statement could be limited to the machine used for the research but to prove this statement wrong, the machine must be improved and more investigation is required.

Dissertations -- Industrial engineering

Theses -- Industrial engineering

Injection molding of plastics

Rapid tooling

Desenvolvimento de sistema ligante para processamento de alumina por injeção a partir de polímeros de fontes renováveis

Mota, Eliane Neves da

January 2014

Neste trabalho, inicialmente, foram obtidos TPSs (amidos termoplásticos) com diferentes concentrações de amido e plastificantes, por processamento em câmara de mistura, com o objetivo de determinar formulações para estudo em extrusora reativa. As formulações de TPS que apresentaram os melhores resultados de torque reométrico foram as que continham 39%m/m de amido. Investigou-se a influência da velocidade da rosca na obtenção de TPS por extrusora reativa, e os resultados mostraram que este parâmetro teve pequena influência na estabilidade do amido termoplástico, sendo possível utilizar 150 rpm de rotação. Foram produzidas 5 blendas com razões de TPS:PEBDL variando de 30:70; 40:60; 50;50; 60:40 e 70:30 para o desenvolvimento de um sistema ligante para a injeção de alumina pelo processo de moldagem de pós (MPI), a partir das quais foi possível analisar a influência do TPS no PEBDL, através de análises de MEV, IF, TGA, DMA e propriedades mecânicas. Quanto maior a concentração de TPS nas blendas, mais heterogênea foi a morfologia observada por MEV e menor o módulo de armazenamento e de perda obtidos por DMA. Este comportamento foi similar ao encontrado pela análise de resistência à tração, que apresentou propriedades mecânicas pobres para elevadas concentrações de TPS. Foram escolhidas três blendas para testar como veículo orgânico em feedstocks de alumina, com carga de partícula sólida de 45%, 50% e 55%v/v de Al2O3. A carga crítica para o sistema ligante-partículas sólidas determinada por reometria de torque foi de 50%v/v de alumina. / In this work, TPSs (thermoplastic starch), with different concentrations of starch and plasticizers for processing in the mixing chamber, were obtained in order to determine formulations for study in a reactive extruder. The TPS formulations that showed the best results for the rheometric torque were those containing 39% w/w starch. The influence of the screw speed to obtain TPS in the reactive extruder was investigated and the results showed that this parameter had little influence on the stability of the thermoplastic starch, allowing the use of 150 rpm rotation speed. Five blends were produced, with TPS:LLDPE ratios of 30:70; 40:60; 50:50; 60:40 and 70:30, to develop a binder for alumina injection by the powder molding process (MPI). From these five systems it was possible to analyze the influence of TPS in LLDPE through SEM analyzes, MFI, TGA, DMA and mechanical properties. The higher the concentration of TPS in blends, more heterogeneous morphology was observed by SEM and the lowest storage and loss modulus were obtained by DMA. This behavior was similar to that found by analysis of tensile strength, which showed poor mechanical properties for high concentrations of TPS. Three blends were chosen for testing as an organic vehicle in alumina feedstocks, with solid particles load of 45%, 50% and 55% v/v of Al2O3. The critical load for the system binder-solid particles, determined by torque rheometry, was 50% v/v of alumina.

Polímeros

Alumina

Polietileno linear de baixa densidade

Thermoplastic starch

LLDPE

Alumina

Powder injection molding

Feedstock