• Title/Summary/Keyword: microcellular injection molding

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A Study on Measurement of Shrinkage of Molded Plastics in a Microcellular Foaming Injection Molding Process (초미세 발포 사출 성형 공정에서 성형된 플라스틱의 수축률 측정에 관한 연구)

  • Hwang, Yun-Dong;Cha, Sung-Woon;Lee, Jung-Hyun
    • Proceedings of the KSME Conference
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    • 2001.06c
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    • pp.621-626
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    • 2001
  • Microcellular foaming process was developed at MIT in 1980's to save a quantity of raw materials and improve mechanical properties. There are many process variables in appling microcellular foaming process to the conventional injection molding process. Of all process variables, part dimension control and shrinkage are the most influential on the post molded dimension. The post molding dimensional change of thermoplastic resins is important to tool designers for predicting the specific difference of molded part vs. actual mold cavity. Generally, articles injection molded are smaller in size than the cavity; hence, the term shrinkage factor is used to define the allowance a designer specifies. It is important to consider the factors that influence molded part dimension. According to ASTM Designation: D 955, shrinkage from mold dimensions of molded plastics was measured. In injection molding, the difference between the dimensions of the mold and of the molded article produced therein from a given material may vary according to the design and operation of the mold. In this paper, shrinkage data of molded plastic parts was obtained. It can be an important information for designing optimum mold system in a microcellular foaming injection molding process.

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Cell morphology of microcellular foaming injection molding products with pressure drop rate (초미세 발포 사출 시 핵 생성장치를 이용한 셀 크기의 변화)

  • 김학빈;차성운
    • Proceedings of the Korean Society of Precision Engineering Conference
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    • 2004.10a
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    • pp.491-495
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    • 2004
  • The industries use polymer materials for many purposes for they have many merits. The costs of these materials take up too great a proportion of the overall cost of products that use these materials as their major material. It is advantage for polymer industries to reduce these costs. The microcellular foaming process was developed in the early 1980s to solve this problem and proved to be quite successful. Microcellular foaming process uses inert gases such as $CO_2$, $N_2$. As these gases solve into polymer matrices, many properties are changed. The microcellular foaming process makes the glass transition temperature of polymers to low, and diminish the residual stress of polymer matrices. Besides, the microcellular foaming process has several merits, impact strength elevation, thermal insulation, noise insulation, and raw material saving etc. This characteristic of microcellular foaming process has influenced by cell morphology. The cell morphology means cell size and cell density. The cell morphology has influenced by many factors. The examples of factor are pressure drop rate, foaming temperature, foaming time, saturation pressure, saturation time etc. Among their factors, pressure drop rate is the most important factor for cell morphology in microcellular foaming injection molding process. This paper describes about the cell morphology change in accordance with the pressure drop rate of microcellular foaming injection molding process.

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Design of Gas Supply System for Microcellular Foamed Injection Molding Using Axiomatic Approach (공리적 접근을 사용한 초미세 발포 사출기용 가스공급장치의 설계)

  • Lee, J.W.;Cha, S.W.;Kim, J.H.
    • Proceedings of the KSME Conference
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    • 2001.06c
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    • pp.414-419
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    • 2001
  • Microcellular foamed plastic is a foaming technology that is safer to the environment and has no significant deterioration of mechanical properties compared to the conventional foamed plastic. Currently, the development of the injection-molding machine for microcellular plastic (MCP) is nearing completion. Currently, researches on the mass production system for the MCP injection-molding machine are under progress. The purpose of this paper is to design the gas supply system suitable for microcellular foaming in the injection-molding machine. For the design process, Axiomatic Approach, a powerful tool for design, will be used.

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Impact Strength as Foaming Magnitude of Microcellular Foamed Plastics (초미세 발포 플라스틱의 공극률에 따른 충격 강도)

  • 황윤동;차성운;김철진
    • Proceedings of the Korean Society of Precision Engineering Conference
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    • 2001.04a
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    • pp.341-345
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    • 2001
  • New technoloty called microcellular foaming process was developed at MIT in 1980's. Although it has many good things, it could not be used it all sides of manufacturing plastics. Because it takes a long time for making foamed goods. So microcellular foaming injection molding process appeared to solve this problem. The first purpose of this research is to measure the impact strength as foaming magnitude of microcellular foamed plastics. There are two methods such as batch process and microcellular foaming injection molding process in making foamed plastics. According to the experimental data, the impact strength of each specimen was measured to find out the influence of foaming magnitude of microcellular foamed plastics.

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Influence of Mold Temperature on the Thickness of a Skin Layer and Impact Strength in the Microcellular Injection Molding Process (초미세 발포 사출공정에서 금형의 온도가 스킨층 두께와 충격강도에 미치는 영향)

  • Lee J.J.;Cha S.W.
    • Proceedings of the Korean Society of Precision Engineering Conference
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    • 2005.06a
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    • pp.1630-1635
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    • 2005
  • The microstructure of the parts made by the microcellular injection molding process influence properties, including impact strength, tensile strength and density of material. Microstructure of microcellular plastics is divided into core foaming region and solid skin region. Core foaming region is influenced by pressure drop rate, viscosity and cell coalescence. However, actual mechanism of the skin layers is not known despite its importance. The study on the skin layer is getting important because foaming rate of the plastics is determined by the thickness ratio of the skin layer. Especially in case of large molded part, control of the skin layer is needed because skin layer thickness is changed largely. Therefore it is necessary to study variation in skin layer thickness with processing parameters. In this paper, the influence of temperatures in the mold cavity on the skin layer s thickness was also addressed. In addition, the relationship between the temperature distributions across cavity of the mold with impact strength on parts made with the microcellular injection molding process was addressed. In addition, the method to predict the variation in skin layer thickness with mold temperature is discussed.

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Application of a Microcellular Foaming Process of Mixed Materials of LDPE, EVA and Foaming Agent and Estimation of Influence of Each Factor (LDPE, EVA 및 발포제 혼합재료의 초미세 발포 공정 적용과 각 인자의 영향성 평가)

  • Park, Dae-Keun;Cha, Sung-Woon;Hwang, Yun-Dong
    • Proceedings of the KSME Conference
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    • 2001.11a
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    • pp.853-858
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    • 2001
  • Generally, mixed materials of LDPE, EVA and foaming agent are manufactured by crosslinking foaming or chemical foaming process. Above materials were used in a microcellular foaming injection molding process. Influence of each factor such as injection type, temperature of barrel, rate of mixed materials and contents of foaming agent was estimated by DOE(Design of Experiments). As a result of experiments, injection type and rate of LDPE, EVA have an influence on foaming rate. This data can be used in field of application of LDPE and EVA.

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Effect of Gas amount on Viscosity Change in Microcellular Plastics (가스의 주입량에 따른 초미세 발포플라스틱의 점도 변화)

  • Lee, Jung-Joo;Cha, Sung-Woon;Kim, Seung-Young
    • Proceedings of the KSME Conference
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    • 2004.04a
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    • pp.1114-1119
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    • 2004
  • In a foaming process of microcellular plastics (MCPs) with a injection molding, research on the viscosity change that occurs when the gas is injected to the polymer has received little attention despite its importance. The purpose of this paper is to provide the basic data required to determine the processing condition by measuring viscosity changes against the gas injection rates of the blowing agent, and to verify the influence of the viscosity change on the flow condition of polymer inside the mold at the injection process.

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Injection Molded Microcellular Plastic Gear (I) - Process Design for the Microcellular Plastic Gear - (초미세발포 플라스틱 기어에 관한 연구 (I) - 초미세발포 플라스틱 기어의 공정설계 -)

  • Ha Young Wook;Chong Tae Hyong
    • Transactions of the Korean Society of Mechanical Engineers A
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    • v.29 no.5 s.236
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    • pp.647-654
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    • 2005
  • This research Proposes a Process design of injection molded microcellular plastic gears for enhancing the fatigue strength/durability and accuracy of the gears applying thermodynamic instability to microcellular foaming process. To develop the injection molded plastic gears by way of microceliular process, it is absolutely necessary the following two process design. The first is microcellular forming process for enhancing the strength/durability of plastic gears. To be microcellular process succeeded, based on the microcellular principle, mechanical apparatus is designed where nucleation and cell growth are to be generated renewably. The second is the counter pressure process which is mainly fur improving the tooth surface roughness and the accuracy of microcellular gears. For the former process, screw, nozzle and gas equipment are newly designed, and for the latter, counter pressure by nitrogen gas is intentionally brought about into mold cavity when injecting plastic gears. Based on the proposed process design, using gear mold, experiments of injection molding show that, in internal space of plastic gears, microcellular nuclear cells less than 5 lim in diameter have been generated homogeneously via electron microscope photos.