• Elastomers and Composites
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• 제51권1호
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• pp.24-30
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• 2016

Sole in the footwear usually modified with foaming agent on the polymer resin to improve the lightweightness and crush-cushion effect. In this study, we investigated rheological properties for polymer resin filled with the different type and concentration of foaming agent, capsule type foaming agent and organo-chemical foaming agent, under the time sweep test. Curing times of each polymer resin with different kind of foaming agent are delayed than reference material (epoxy resin with curing agent). In case of adding capsule type foaming agent, however, there is appropriate concentration to reduce the curing time, relatively. When foaming agent is activated, foaming force inflates the sample in contrast to condensation force of curing and then axial normal force develop to the (+) direction. Interestingly, by increase concentration of foaming agent, there is a specific point to break down the axial normal force development. The reason for this phenomenon is that coalescence of foams induce the blocking of axial normal force development.

• 한국농공학회지
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• 제30권1호
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• pp.73-80
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• 1988

This study was performed to obtain the basic data which can be applied to use of foaming mortars. The results obtained were Summarized as follows; 1.At the mixing ratio of 1:1, the highest bulk densities were showed by foaming mortars, respectively. But, it gradually was decreased in poorer mixing ratio and more addition of foaming agent. The decreasing rates of bulk densities were increased in richer mixing ratio and more addition of foaming agent. 2.The bulk densities were decreased up to 38.8-55.9% by mix-foaming type and 9.7-23.6% by pre-foamed type than cement mortar. 3.At the mixing ratio of 1:1, the lowest absorption rates were showed by foaming mortars, respectively. But, it gradually was increased in poorer mixing ratio and more addition of foaming agent. The increasing rates of absorption rates were increased in richer mixing ratio and more addition of foaming agent. 4.Absorption rates when immersed in 72hours were showed up tp 3.41-5.85 times by mix-foaming type and 1.05- 1.S5times by pre -foamed type than cement mortar, it was significantly higher at the early stage of immersed time than cement mortar. 5.The correlations between bulk density and absorption rate were highly singnificant, respectively. The multiple regression equations of bulk density and absorption rate were computed depending on a fuction of mixing ratio and addition of foaming agent. it was highly significant respectively.

• 대한기계학회:학술대회논문집
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• 대한기계학회 2001년도 추계학술대회논문집A
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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.

• 열처리공학회지
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• 제34권2호
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• pp.60-65
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• 2021

In this study, the effect of pressure type and foaming agent on the microstructural change of Al foam produced by powder compact processing was investigated. Better foaming characteristic is easily obtained from extrusion process with strong plastic deformation and preheating than that by uniaxial pressing with preheating. In current powder compact foaming process using TiH2/MgH2 mixture as a foaming agent, a temperature of 670℃ and addition of 30% MgH2 in TiH2 foaming agent was chosen as the most suitable foaming condition. The aluminum (Al) foams with maximum porosity of around 70%, relatively regular pore size and distribution were successfully produced by means of the powder metallurgy method and extrusion process.

• 한국농공학회지
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• 제30권3호
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• pp.106-113
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• 1988

This study was performed to obtain the basic data which can be applied to use of foamihg mortars. 1. At the mixing ratio 1:1, the highest strengths were showed by foaming mortam, respec - tively. But, it. gradually was decreased in poorer mixing ratio and more addition of foam- ing agent. The decreasing rates of strengths were incresed in poorer mixing ratio and more addition of foaming agent. 2. The strengths were decreased up to 77.0-92.8% by mix-foaming type and 36.7-74.4% by pre-foamed type than cement mortar. 3. At the mixing ratio of 1:1, the lowest air contents were showed by foaming mortars, respectively. But, it gradually was increased in poorer mixing ratio and more addition of foaming agent. The increasing rates of air contents were increased in richer mixing ratio and more addition of foaming agent. 4. Air contents were showed up to 26.0-63.8 times by mix-foaming type and 5.8-17.7 times by pre-foamed type than cement mortar, respectively. 5. The correlations between compressive strength and air content were highly significant, respectively. The multiple regression equations of strengths and air content were computed depending on a fuction of mixing ratio and addition of foarning agent. It was highly significant, respectively.

• Elastomers and Composites
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• 제58권2호
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• pp.65-69
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• 2023

To reduce the weight of the engineering plastic Nylon 6 resin, two high-temperature foaming agents, p-toluenesulfonyl semicarbazide (PTSS) and 5-phenyltetrazole (5-PT) (0-10 phr), were added and foamed without other additives. We investigated the effects of the foaming agent type and content on the foam density (g/cm³) and percent weight reduction rate of the Nylon 6 foam, and 5-PT exhibited better foaming performance than PTSS. In the case of 5-PT, the weight reduction rate was above 36% when the blowing agent content was 1.5 phr or higher, indicating that 5-PT is an effective blowing agent for reducing the Nylon 6 foam weight. Additionally, we studied the effect of the nucleating agent Talc content (0-0.4 phr) on Nylon 6 foaming, and the nucleating agent Talc considerably reduced foaming.

• 한국건축시공학회:학술대회논문집
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• 한국건축시공학회 2007년도 추계 학술논문 발표대회
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• pp.27-30
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• 2007

Recently, use of light-weight panel is increasing in building. Styrofoam sandwich panel is inexpensive and it is excellent in insulation ability and constructability. But styrofoam of panel inside is low ignition point. Consequently, when panel is fired, it is occur in poisonous gas. On the other hand, light-weight foamed concrete is excellent in insulation ability, fire resistance due to inner pore. Properties of light-weight concrete is influenced by foaming agent type. Accordingly, this study investigate in insulation property of according to foaming agent type in order to using light-weight foamed concrete instead of styrofoam. As a results, Non-heating zone temperature of light-weight foamed concrete of using AP, FP are lower than light-weight foamed concrete of using AES. Light-weight foamed concrete of using AES, FP are satisfied with fire performance of two hours at foam ratio 50, 100. Light-weight foamed concrete of using AP is satisfied with fire performance of two hours at AP ratio 0.1, 0.15. Insulation property is better closed pore by made AP, FP than open pore by made AES.

• 농업과학연구
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• 제15권1호
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• pp.82-94
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• 1988

이 논문(論文)은 기포(起泡)모르터의 제특성(諸特性)에 관(關)한 기초자료(基礎資料)를 제공(提供)하고져 수행(遂行)되었는 바, 이 연구(硏究)를 통(通)하여 얻어진 결과(結果)를 요약(要約)하면 다음과 같다. 1. 각(各) 기포(氣泡)모르터에서 물-시멘트비는 당배합비(富配合比)일수록, 기포제(起泡劑) 및 기포(氣泡)의 첨가량(添加量)이 증가(增加)할수록 감소(減少)하였으며, 보통(普通)시멘트 모르터에 비(比)하여 혼합기포주입형(混合氣泡注入型)은 1.6~53.1%, 사전기포주입형(事前氣泡注入型)은 4.4~24.1%의 물-시멘트비(比)가 감소(減少)되었다. 2. 각(各) 기포(氣泡)모르터의 밀도(密度)는 빈배합(貧配合)일수록, 기포제(起泡劑) 및 기포(氣泡)의 첨가량(添加量)이 증가(增加)할수록 작게 나타났으며, 밀도(密度)의 감소율(減少率)은 당배합(富配合)일수록, 기포제(起泡劑) 및 기포(氣泡)의 첨가량(添加量)이 증가(增加)할수록 크게 나타났다. 3. 기포(起泡)모르터는 보통(普通)시멘트 모르터에 비(比)하여 혼합기포주입형(混合氣泡注入型)은 38.8~55.9%, 사전기포주입형(事前氣泡注入型)은 9.7~23.6%의 자중감소(自重減少)를 보였다. 4. 각(各) 기포(起泡)모르터의 급수율(吸水率)은 빈배합(貧配合)일수록, 기포제(起泡劑) 및 기포(氣泡)의 첨가량(添加量)이 증가(增加)할수록 높게 나타났으며, 흡수율(吸水率)의 증가율(增加率)은 당배합(富配合)일수록, 기포제(起泡劑) 및 기포(氣泡)의 첨가량(添加量)이 증가(增加)할수록 크게 나타났다. 5. 72시간(時間) 수침(水浸)에서 각(各) 기포(氣泡)모르터의 흡수율(吸水率)은 보통(普遇)시멘트 모르터에 비(比)하여 혼합기포주입형(混合氣泡注入型)은 3.41~5.85배(倍)로 나타났으며, 사전기포주입형(事前氣泡注入型)은 1.05~1.55배(倍)로 나타났으며, 흡수율(吸水率)의 변화율(變化率)은 모두 수침초기(水浸初期)에 높게 나타나는 경향(傾向)을 보였다. 6. 각(各) 기포(氣泡)모르터의 각(各) 강도(强度)는 빈배합(貧配合)일수록, 기포제(起泡劑) 및 기포(氣泡)의 첨가량(添加量)이 증가(增加)할수록 작게 나타났으며, 각(各) 강도(强度)의 감소율(減少率)은 빈배합(貧配合)일수록, 기포제(起泡劑)나 기포(氣泡)의 첨가량(添加量)이 증가(增加)할수록 크게 나타났다. 7. 기포(氣泡)모르터는 보통(普通)시멘트 모르터에 비(比)하여 재령(材齡) 28일(日)에서 혼합기포주입형(混合氣泡注入型)은 77.0~92.8%, 사전기포주입형(事前氣泡注入型)은 36.7~74.4%의 강도감소(强度減少)를 보였고, 각(各) 기포(氣泡)모르터의 각(各) 강도간(强度間)의 상관관계(相關關係)는 직선형(直線形)으로 나타났으며 고도(高度)의 유의성(有意性)이 인정(認定)되었다. 8. 각(各) 기포(氣泡)모르터의 공기량(空氣量)은 빈배합(貧配合)일수록, 기포제(起泡劑)나 기포(氣泡)의 첨가량(添加量)이 증가(增加)할수록 크게 나타났으며, 공기량(空氣量)이 증가율(增加率)은 당배합(富配合)일수록, 기포제(起泡劑)나 기포(氣泡)의 첨가량(添加量)이 증가(增加)할수록 높게 나타났다. 9. 기포(氣泡)모르터의 공기량(空氣量)은 보통(普通)시멘트 모르터에 비(比)하여 혼합기포주입형(混合氣泡注入型)은 26.0~63.8배(倍), 사전기포주입형(事前氣泡注入型)은 5.8~17.7배(倍)를 보였다. 10. 각(各) 기포(氣泡)모르터에서 밀도(密度)와 흡수율(吸水率), 압축강도(壓縮强度) 및 공기량(空氣量)과의 상관관계(相關關係)는 매우 높은 유의성(有意性)을 보였고, 배합비(配合比)와 기포제(起泡劑) 및 기포(氣泡)의 첨가량(添加量)에 따라 밀도(密度), 흡수율(吸水率), 제강도(諸强度) 및 공기량(空氣量)을 추정(推定)할 수 있는 다중회귀방정식(多重回歸方程式)을 유도(誘導)하였으며 각(各) 방정식(方程式)은 고도(高度)의 유의성(有意性)이 인정(認定)되었다.

• 콘크리트학회논문집
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• 제23권2호
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• pp.151-158
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• 2011

선발포 방식을 통해 제조되는 기포 콘크리트에서 기포는 밀도, 강도, 공극 등의 물리적 특성에 영향을 끼치는 주요인이다. 기포 콘크리트에 대한 연구가 꾸준하게 진행되었지만, 기포 자체의 특성에 관한 연구는 화학적인 분야를 제외하고는 거의 없는 실정이다. 그러므로 용도에 적합한 기포 콘크리트를 제조하기 위해서는 기포의 성상에 대한 연구가 필수적으로 선행되어야 한다. 기포 콘크리트의 제조에서 기포를 유효하게 이용하기 위해서는 기포의 특성을 평가해야만 한다. 이 연구에서는 기포의 특성을 알아보기 위해 기포제 종류 및 농도 변화에 따른 기포의 특성에 관한 검토를 수행하였다. 기포의 특성을 알아보기 위해 사용한 기포제는 계면활성제계, 수지비누계, 단백질계 기포제를 사용하였고 기포제의 농도는 기포제 종류에 따라 0.05~13% 범위로 설정하였다. 측정 항목은 발포율, 기포 용적, 수용액 용적, 기포 크기 및 분포를 측정하였다. 분석 결과, 기포제 종류와는 상관없이 기포제 농도가 높을수록 발포율은 증가하는 것으로 나타났고, 기포제 농도는 기포, 수용액 용적 변화, 기포 크기 분포에도 영향을 끼치는 것으로 나타났다. 기포의 안정성 측면에서 단백질계가 계면활성제, 수지비누계 보다 높은 안정성을 나타냈다. 기포의 형상에서는 계면활성제계, 수지 비누계는 다각형의 기포를, 단백질계는 구형의 기포를 형성하였다.

• 한국농공학회지
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• 제27권1호
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• pp.46-61
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• 1985

This study was performed to obtain the basic data which can be applied to the use of foaming mortars. The data was based on the properties of foaming mortars depending upon various mixing ratios and addings to compare those of cement mortar. The foaming agents which was used at this experiment were pre-foamed type and mix-foaming type which is being used as mortar structures. The foaming mortar, mixing ratios of cement to fine aggregate were 1:1, 1: 2, 1 : 3 and 1 : 4. The addings of foaming agents were 0.0%, 0.5%, 1.0%, 1.5%, 2.0%, 2.5% and 3.0% of cement weight. The results obtained were summarized as follows; 1. At the mixing ratio of 1 : 1, the lowest water-cement ratios were showed by foaming mortars, respectively. But it gradually was increased in poorer mixing ratio and decreased in more addition of foaming agent. The water-cement ratios were decreased up to 1. 8~22. 0% by G, 2. 2~24. 1 % by U and 0. 7~53. 1% by J foaming mortar than cement mortar. 2, At the mixing ratio of 1 : 1, the highest bulk densities were showed by foaming mortars, respectively. But, it gradually was decreased in poorer mixing ratio and more addition of foaming agent. The bulk densities were decreased up to 1. 4~20. 7% by G, 2. 3~23. 7% by U and 26. 5~56. 5% by J foaming mortar than cement mortar. Therefore, foaming mortar could be utilized to the constructions which need low strengths. 3. At the mixing ratio of 1:1, the lowest absorption rates were showed by foaming mortars, respectively. But, it gradually was increased in poorer mixing ratio and more addition of foaming agent. Specially, according to the absorption rate when immersed in 72 hours, the absorption rates were showed up to 1. 01~1. 24 times by G, 1. 03~1. 58 times by U and 1. 10~5. 91 times by J foaming mortar than cement mortar. It was significantly higher at the early stage of immersed time than cement mortar. 4. At the mixing ratio of 1:1, the lowest air contents were showed by foaming mortars, respectively. But, it gradually was increased in poorer mixing ratio and more addition of foaming agent. Air contents were contented up to 4. 0~17. 2 times by G, 5. 2~23. 2 times by U and 23. 8~74. 5 times by J foaming mortar than cement mortar. 5. At the mixing ratio of 1 : 1, the lowest decreasing rates of strengths were showed by foaming mortars, respectively. But, it gradually was increased in poorer mixing ratio and more addition of foaming agent. Specially, the strengths of 28 days were decreased 0. 4~2. 2% than those of 7 days by foaming mortar, respectively. Also, the correlations between compressive and tensile strength, compressive and ending strength, tensile and bending strength were highly significant as a straight line shaped, respectively. 6. The correlations between absorption rate, air content, compressive strength and bulk density, absorption rate, compressive strength and air content were highly significant, respectively. The multiple regression equations of water-cement ratio, bulk density, absorption ate, air content, compressive strength, tensile strength and bending strength were computed depending on a function of mixing ratio and addition of foaming agent. It was highly significant, respectively. 7. At the mixing ratio of 1 : 1, the highest strengths were showed by cement mortar and foaming mortars, by chemical reagents. But, it gradually was decreased in poorer mixing ratio. The decreasing rates of strengths were in order of H $_2$S0 $_4$, HNO$_3$ and HCI, J,U,G foaming mortar and cement mortar. Specially, at the each mixing ratio, each chemical reagent and 3.0% of foaming agent, J foaming mortar was collapsed obviously. Therefore, for the structures requiring acid resistence, adding of foaming agent should be lower than 3.0%.