• Food Science and Preservation
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• v.10 no.2
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• pp.192-199
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• 2003

To prepare soybean curd utilizing effectively bioactive component of soybean, ultra fine whole soybean flour(UFWSF) was used as a soybean curd material for preparation of uncompressed whole soybean flour curd(UWSFC) in this study. The UWSFC was made with treatment by proteinase and coagulant, and proximate composition, color, textural properties and sensory evaluation of that were analyzed. Protease produced from Aspergillus sojae, bromelain and papain showed soybean curd coagulation ability and the pretense produced from Aspergillus sojae showed the highest soybean curd coagulation ability. When, after first heating and homogenizing, the proteinase was added to soybean milt textural properties of UWSFC were the best. Hunter's L and b values and textural properties (hardness, fracturability springiness, gumminess and chewiness) of UWSFC using proteinase and coagulant were higher than commercial soft soybean curd and adhesiveness and cohesiveness showed contrary tendency.

• Food Science and Preservation
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• v.7 no.3
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• pp.249-255
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• 2000

Soybean curd has been known as one of the most favorite traditional Korean foods as well as being high in protein. Each concentration of added natural materials soybean curds was chosen as 4% of carrot, 10% of cucumber, 1.0% of spinach and 0.05% of green tea powder. The yield of soybean curd containing natural materials was similar to that of non-containing curd. According to add GDL as coagulant, the yield of soybean curd containing natural materials was the highest. The turbidity of added natural material soybean curds was the highest coagulated with $CaCl_2$, but soybean curd containing green tea had the highest turbidity in the coagulated with GDL. In the chromaticity and texture properties of the additive natural materials in yhe soybean curd, the variety of additives had no effect. In the composition of natural materials, the carotenoid and chlorophyll content of soybean curds were high with $MgCl_2$ and $CaCl_2$ but polyphenol was high use of $CaSo_4$ and GDL.

• Journal of the Korean Society of Food Science and Nutrition
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• v.32 no.1
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• pp.75-81
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• 2003

Rheological properties of micronized full-fat soyflour (MFS ) milk were determined according to solid content, heat-treatment and type of coagulants. Heat-treated MFS milk showed a pseudoplastic flow pattern. The consistency and flow index of heated MFS milk was greatly affected by increasing the concentration of MFS and/or soy protein isolate (SPI). Apparent viscosity of MFS milk was gradually decreased by heating below 6$0^{\circ}C$, but was drastically increased by raising temperature further. Addition of coagulants and SPI resulted in dropping the temperature that allows to increase apparent viscosity drastically. A coagulant for MFS tofu was formulated based on the gelling Property of a single coagulant. The textural properties of MFS tofu were improved using 7.1% total protein fortified with SPI.

• Journal of the East Asian Society of Dietary Life
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• v.17 no.4
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• pp.547-553
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• 2007

The physicochemical and functional properties of tofu prepared with kanghwang(Curcuma aromatica Salab.) were investigated, in order to study the effects of six different commercial coagulants. The coagulant concentrations were determined as 0.3% GDL, 0.3% $MgCl_2$, 1.0% $CaCl_2$, 1.5% $CaSO_4$, 0.45% mixed coagulant, and 1.5% Milky-Mg by pre-experiments. Also, the optimum concentration for the added kanghwang(Curcuma aromatica Salab.) was chosen as 0.01%. The yields of the kanghwang tofu prepared with Milky-Mg, mixed, and GDL coagulants were higher than those prepared with $MgCl_2$, $CaCl_2$, and $CaSO_4$. The pH of the kanghwang tofu prepared with the $MgCl_2$ coagulant was higher than when made with the other coagulants. The turbidity of the kanghwang tofu was highest when it was coagulated with GDL, and moisture content was highest or the of kanghwang tofu coagulated with $CaCl_2$. In the color analysis of the kanghwang tofu, the $L^{***}$ value was highest with the Milky-Mg coagulant, while the $a^{***}$ value was highest and the b value lowest with the GDL coagulant. For the textural properties, the hardness results were in the order of $CaSO_4$ > $CaCl_2$ > $MgCl_2$ > mixed > GDL > Milky-Mg, springiness, gumminess, and brittleness were highest in the tofu coagulated with Milky-Mg. For the overall acceptability of the sensory properties, the Kanghwang tofu that was made using the mixed coagulant had the highest score.

• Korean Journal of Food Science and Technology
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• v.24 no.2
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• pp.154-159
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• 1992

An investigation was carried out to study the feasibility of tofu preparation with using isolated soyprotein(ISP) only. The ISP tofu was prepared by boiling the ISP suspension for 2 min before addition of coagulants. Effects of coagulants($CaSO_{4},\;CaCl_{2}\;MgCl_{2}\;GDL$) and coagulation temperature in the range of $2{\sim}95^{\circ}C$ were studied on the amounts of coagulants required, size and shape of coagulates, volume yield and textural properties of tofu. It was found that amounts of coagulants and tofu volume was significantly reduced and the larger and cloud-like shape was obtained as the coagulation temperature increased. A rather precipitation was occured under $40\;or\;50^{\circ}C$, which caused difficulty for tofu formation by pressing. GDL and $CaSO_{4}$ showed higher yields than those of $CaCl_{2}\;and\;MgCl_{2}$ at low temperature range and little difference at high temperature. In the textural properties of hardness, brittleness and gumminess of tofu were almost lineary and rapidly increased as the coagulation temperature increased where $CaCl_{2}\;and\;GDL$ produced highest and lowest of those values, respectively. The elasticity was reduced as the temperature increased for those made with $MaCl_{2},\;CaSO_{4}\;GDL\;and\;CaCl_{2}$, tofu showed little change.

• Journal of the Korean Society of Food Science and Nutrition
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• v.33 no.3
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• pp.603-608
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• 2004

Traditional Jeju tofu with a hard texture was manufactured by traditional method with a compounded coagulant. The processing condition for industrial production was optimized by determining soaking of soybean, extraction and heat treatment of soymilk as well as concentration and composition of coagulant. Maximum yield of soymilk was obtained by grinding one part of soaked soybean with eight parts of water, and the soluble solid of soymilk was about 8$^{\circ}$Brix. The free thiol group in soymilk was maximally exposed by heating at 10$0^{\circ}C$ for 2 min. A vacuum cooker for heating soymilk was effective for the improvement of yield and texture properties of tofu. The hardness of traditional Jeju tofu was obtained by increasing pressing time and drying by a fan instead of soaking in cold water. Optimization of a traditional tofu production resulted in the increase of total yield and improvement of quality control. Texture of traditional Jeju tofu prepared in industrial production scale was analyzed by instrumental analysis and sensory evaluation. Traditional Jeju tofu showed higher score in the hardness, roasting taste and overall preference compared with a commercial tofu, showing significant difference in 5% significant level..

• The Korean Journal of Blood Transfusion
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• v.23 no.2
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• pp.145-151
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• 2012

배경: 채혈 후 제제 경과시간에 따른 동결혈장의 혈액응고인자의 활성도와 이에 영향을 미치는 요인을 분석하여, 혈액응고인자제제의 원료혈장의 사용범위를 확장 가능한지 확인하고자 동결혈장의 채혈시간과 응고인자 특성을 측정하였다. 방법: ALT 부적격 혈장을 채혈 후 동결시간의 특성에 따라 4단계로 구분하였고, 6종류의 혈액 응고인자 활성도와 혈액형을 검사하였고, SAS 9.2 프로그램을 사용하여 통계처리 하였다. 결과: 혈액제제간 FVIII 활성도를 분석한 결과 PL-A>FFP>FP(8-24)${\approx}$FP(24-72) 순으로 유의하게 낮아졌고 혈액형에 따라서는 AB형이 제일 높고, O형이 제일 낮았다. 대한적십자사의 원료혈장에 대한 FVIII 활성 품질기준을 적용할 경우 PL-A, FFP와 FP24는 각각 85.0%와 82.5%로 적합하였다. 캐나다 퀘백 주처럼 FP24의 FVIII 활성이 0.52 IU/mL 이상을 적용할 경우 PL-A, FFP와 FP24는 각각 95.0%, 96.3%, 82.6%로 적합하였다. 또한 FP(8-24)의 A형과 AB형, FP(24-72)의 경우 AB형이 각각 82.1%, 83.3%, 100%로 적합하였다. 결론: 혈액응고인자제제용 원료혈장의 범위는 외국의 기준에 비추어 채혈 후 24시간 내에 동결된 혈장(FP24)으로 확대 사용이 가능하다. 이를 위해서는 채혈 후 동결시간과 혈액응고인자에 대한 품질기준을 유럽약전 또는 WHO 가이드라인과 비교하여 완화하는 것이 필요하다.

• Journal of Food Hygiene and Safety
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• v.35 no.2
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• pp.183-188
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• 2020

The manufacturing process for konjac jelly is largely divided into the three processes of powder manufacturing, a coagulation and finishing. It was found that the number of aerobic bacteria in konjac jelly decreases as the concentration of coagulation agent and soaking liquid increases. The temperature of the water has no significant effect. When the concentration of coagulation agent was maintained at 1.0%, the tensile strength was also maintained without significant change for up to 10 months. When the concentration was kept below 0.8%, however, the tensile strength showed a tendency to sharply decrease. After fixing the coagulant concentration to 1.0%, the effect by the soaking liquid was confirmed. At all concentrations of soaking, it was found that both tensile strength and bacterial numbers are unchanged until 10 months of storage.

• Journal of the Korean Society of Food Science and Nutrition
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• v.17 no.1
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• pp.25-31
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• 1988

The crude calcium acetate (CCA) was made from egg-shell and acetic acid to use the CCA as a coagulant for Tofu (soy bean curd). Amount of CCA. $CO_2$ and residue made from 5.6g egg-shell (average weight of a egg-shell) and 10% acetic acid(50m1) was 3.8g, $300{\pm}10ml(at\;25^{\circ}$ and 2.1g. respectively. Tofu formable minimum concentration of the CCA was about 0.14% similar to that of $CaCl_2$, $MgCl_2$. Volume, hardness, taste and content f protein and lipid of Tofu by addition of CCA were not significantly different in those of Tofu that magnesium chloride and calcium chloride were used.

• Journal of the KSME
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• v.19 no.4
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• pp.279-290
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• 1979

Arc Welding의 경우 arc열에 의하여 생성된 용융지(Molten Pool)가 응고하는 과정은 금형주물의 응고과정과 비슷하게 생각되나 실은 응고의 제1단계에서 양자간에 큰 차이가 있다. 즉, 금형에 주입된 용융금속이 응고하는 경우는 금형과 이에 접한 주조금속과는 응고후 별도로 분리할 수 있으며, 양자가 서로 융합해서는 안될 것이다. 이에 반하여 융접의 경우에는 금형속에 있는 용 융금속과 금형이라고 볼 수 있는 모재용융부단면과는 완전히 융합되어야 할 것이다. 금형주조 부분의 응고에서는 금형에 접한 주조금속이 열적과냉각(Thermal Supercooling)을 받아 그 내부에 결정핵이 생성되어 이것이 성장하는 과정을 거칠 것이다. 그러나 융접의 경우에는 일반적으로 용융금속과 모재와는 통일계통의 재료이므로 용융금속에 접한 모재부분 자신이 종자결정(Seed Crystal)와 같은 역할을 하여 용융금속내에 새로히 결정핵을 생성함이 없이 이 위에서 직접 결 정성장이 연행되는 것이다. 이것을 Epitaxial Growth라는 하나 이것이 용접부의 응고에서의 큰 특정인 것이다. 주조, 용접 공히 열절과냉각에 의한 응고의 초기단계를 거치면 합금인 경우 그 후의 응고과정은 주로 조성적 과냉각(Constitutional Supercooling)에 따르게 될 것이다. 이 기 회에 Epitaxy에 관해서 간단히 설명하고저 한다.