• Radiation Oncology Journal
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• v.10 no.2
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• pp.147-153
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• 1992

It is ideal thing to compensate tissue deficit without skin contamination in curvatured irradiation field of high energy photon beam. The 3-dimensional compensating technique utilizing tissue equivalent materials to ensure an adequate dose distribution and skin sparing effect was described. This compensator was made of paraffin ($70\%$) and stearin wax ($30\%$) compound. The parameters for evaluation of the effect on skin dose in application of compensator were considered in the size of the field, the thickness of the compensator and the source-to-axis distance. The results are as follows; the skin doses were not changed even though application of the compensator, but depended on the field size and the source-to-axis distance, and the skin doses were only slightly changed within $1\%$ relative errors as increasing the thickness of the compensator in these experiments.

• Clean Technology
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• v.18 no.2
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• pp.155-161
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• 2012

The purpose of this study is to remove paraffin wax binder effectively from powder injection molded part using supercritical fluids in powder injection molding process. For a thin powder injection molded part about 1-2 mm thickness, paraffin wax binder can be removed rapidly without any defect by traditional supercritical extraction process which has fixed high temperature and pressure condition. But, for a thick powder injection molded part, there are limitations in removing paraffin wax binder by the fixed high process condition because crack occurs at the beginning step. Therefore, here we studied variable condition debinding process that starts with mild process condition at the beginning step and then increase the process conditions simultaneously at each step. To find out the initial process condition that has the highest extraction yield without any defect for each sample thickness, we investigated various supercritical debinding conditions using 1-4 mm thickness ceramic injection molded sample. By using the variable condition debinding process that starts with the initial process condition at the first step and then increasing process conditions simultaneously at each step (temperature from 333.15 to 343.15 K, pressure from 12 to 27 MPa, and $CO_2$ flow rate from 1.5 to 10 L/min), over 95% of paraffin wax binder was removed from the 4 mm thick (10 mm diameter) ceramic injection molded disk samples within 5 hours.

• Proceedings of the Plant Resources Society of Korea Conference
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• 2019.04a
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• pp.109-109
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• 2019

2018년 5월 전라북도 남원군에서 재배하여 수확 후 $0^{\circ}C$ 저장고에서 예냉을 마친 산마늘을 사용하였으며 외 포장 상자는 골판지로 구성된 통기공이 없는 골판지상자 1kg용을 사용하였다. 골판지상자와 함께 내부 포장으로 사용하기 위한 내포장 필름은 $20{\mu}m$ 두께의 HDPE으로 된 필름 봉지, 흡습종이는 파라핀왁스 코팅 종이($32{\times}35cm$, 태영산업)를 이용하여 조합 처리하고 국내에서 개발한 기능성 필름2종으로 포장처리는 총 4가지로 (1) PE(관행) (2) PE+흡습지 (3) 기능성필름1($30{\times}58cm$, 기능성물질 1%+40,000OTR, 제조사: 신영산업사) (4) 기능성필름2($30{\times}58cm$, Key fresh, 제조사: 씨앤케이프로팩(주)) 각 처리당 1kg 씩의 산마늘 잎을 포장하였다. 실험은 포장 처리 후 상온상태로 전북 완주군 실험실까지 수송하였으며 실험실 도착 후 상온 실험실에 두고 2일과 6일 후 중량감소율, 색도, 엽록소, 손실률 및 종합선도 등 품질특성 변화를 조사하였고 각 포장방법별 온도와 상대습도 변화를 보기 위하여 산마늘 잎이 포장된 상자 내부 중앙 부분에 디지털온습도기록계(SP-2000-20R)를 고정한 후 측정하였다. 대조구로 사용한 PE필름 단용으로 포장한 산마늘 잎은 상온저장 6일 경과 후 중량 소율이 1.7%, PE필름+신선지 처리는 1.0%, 기능성필름1과 기능성필름2는 거의 중량감소가 없어 1% 미만의 변화를 보였다. 산마늘 잎의 SPAD 값에 의한 엽록소 수치와 색도를 측정한 명도($L^*$)와 Hue angle 값의 변화는 기능성필름1과 기능성필름2가 유사하게 높게 유지되었고 반면에 PE필름은 저장 2일 후 부터 값이 감소하기 시작하여 6일 후 크게 감소하였다. 저장 6일 후 기능성필름1과 기능성필름2가 외관품위에서 높은 평가를 받아 상품성을 유지하고 있었으나 PE필름 처리와 PE필름+흡습지 처리는 상품성을 상실한 상태였다. 이러한 경향은 건전율에 있어서도 유사하였으며 기능성필름1(다공성 나노 물질이 혼입되어 있으며 산소투과율을 $40,000cc/m2{\cdot}day{\cdot}atm$으로 조성한 필름)이 상온저장 6일 후 상품성을 유지하는 건전율이 83%로 가장 높았다.

• Journal of the Korean Recycled Construction Resources Institute
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• v.1 no.1
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• pp.17-25
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• 2013

Thermal storage technology used for indoor heating and cooling to maintain a constant temperature for a long period of time has an advantage of raising energy use efficiency. This, the phase changing material, which utilizes heat storage properties of the substances, capsulizes substances that melt at a constant temperature. This is applied to construction materials to block or save energy due to heat storage and heat protection during the process in which substances melt or freeze according to the indoor or outdoor temperature. The micro-encapsulation method is used to create thermal storage from phase changing material. This method can be broadly classified in 3 ways: chemical method, physical and chemical method and physical and mechanical method. In the physical and chemical method, a wet process using the micro-encapsulation process utilized. This process emulsifies the core material in a solvent then coats the monomer polymer on the wall of the emulsion to harden it. In this process, a surfactant is utilized to enhance the performance of the emulsion of the core material and the coating of the wall monomer. The performance of the micro-encapsulation, especially the coating thickness of the wall material and the uniformity of the coating, is largely dependent on the characteristics of the surfactant. This research compares the performance of the micro-capsules and heat storage for product according to molecular mass and concentration of the surfactant, SSMA (sulfonated styrene-maleic anhydride), when it comes to micro-encapsulation through interfacial polymerization, in which Dodecan-1 is transformed to melamin resin, a heat storage material using phase changing properties. In addition, the thickness of the micro-encapsulation wall material and residual melamine were reduced by adjusting the concentration of melamin resin microcapsules.