An enthalpy exchange element (EEE) is frequently made of papers, and a concern exists on growth of fungus or bacteria. This concern may be eliminated if polymer membrane is used instead of paper. Furthermore, most existing enthalpy exchangers have cross-flow configuration, which yields lower performance than counter-flow one. In this study, a counter-flow enthalpy exchange element was made using PVDF and cellulose composite. Heat and moisture transfer tests were conducted changing the frontal air flow rate from 150 m 3 /h to 350 m 3 /h at both the heating and the cooling condition. Results showed that the temperature efficiencies were approximately the same independent of the weather condition. Humidity efficiencies at the heating condition, however, were higher than those at the cooling condition. Furthermore, the heat transfer coefficients approached the theoretical value as the flow rate increased. In addition, the vapor transmission rates at the heating condition were higher than those at the cooling condition, probably due to the higher humidity efficiency at the heating condition. Future research will be focused on moisture diffusion characteristics of the composite membrane, which requires further measurements of water holdup, equilibrium adsorption curve, etc.
In this study, an enthalpy exchanger was coated by silver nano particles via spark discharge method and its antimicrobial and heat exchange efficiencies were evaluated. A method utilizing thermophoretic force was used to improve coating efficiency. Four spark discharge systems were parallel connected and generated silver nano aerosol particles (number concentration of 1.65×108 particles/cc, mode diameter of 31 nm). The coating efficiency was evaluated according to various face velocities (V=0.25~1 m/s) and temperature gradients ((Thot-Tcold)/Thot=0~0.09). The maximum coating efficiency was 90.8 % when the face velocity was 0.25 m/s and the temperature gradient was 0.09 (Thot=30℃, Tcold=2℃). Silver nano particles were coated onto the enthalpy exchange element and two different coating amounts of silver nano particles (0.11 ㎍/cm3 , 0.22 ㎍/cm3 ) were tested. For evaluation of antimicrobial efficiency, the suspension test method with E. coli was used. After the suspension test method, CFU(colony forming unit)s of each test sample were counted and colony ratio was calculated. The colony ratio was decreased more quickly when the amount of coated silver particles was increased. When the contact time between each sample and suspension was over 3 hours, antimicrobial efficiencies of coated samples were more over 99.9 % for both amount of silver nano particle(0.11 ㎍/cm3 , 0.22 ㎍/cm3 ). The coating of silver nano particles did not affect the heat exchange efficiency.
In Spray Forming, specific enthalpy is a key parameter in the deposition process as it influences the thermal condition of the impinging droplets as well as that of the deposit surface. An empirical model for the distribution of specific enthalpy in the spray cone was developed as an easy to handle alternative to numerical models with which the descriptive partial differential equations are solved numerically. The model results were compared with the experimental data to validate its applicability.
Phosphatidylcholine (PC) 인지질로 이루어진 모델 지질막은 세포막을 대신하여 지질막과 여러 분자간의 상호 작용을 연구하는 생물리 연구에 흔히 이용된다. 이들 모델 지질막을 제조하는 과정에서 지질 분자나 지질막과 작용하는 분자를 용해하는데 여러 가지 유기 용매가 이용된다. 용해 과정에 사용된 용매는 물론 제거되거나 소량 사용되기 때문에 실험 결과에 미치는 영향이 미미한 것으로 간주되어 보통 무시된다. 하지만 용매의 종류에 따라 소량의 용매가 용질 분자에 남아서 실험 결과에 영향을 미칠 수 있다. 본 연구에서는 시차열분석기와 인(31P) 고체 핵자기 공명 실험을 통하여 유기 용매가 지질막의 상변이와 지질막의 물리적 성질에 미치는 영향을 조사하였다. 클로로폼에 용해한 지질의 경우 비교적 쉽게 제거되었으며, 에탄올, trifluoroethanol (TFE) 또는 trifluoroacetic acid (TFA)에 용해한 분자들의 경우 용질에 잔류하여 지질과 용질의 상호작용시 지질의 물리적 성질에 영향을 미치는 것이 확인되었다. 따라서 지질막과 상호작용하는 분자들의 연구에서 용매의 선택이 중요하며 비록 미량이 사용되었을지라도 시료 제조와 실험 결과의 해석에 각별한 주의가 필요함을 보여 준다.