http://chineseinput.net/에서 pinyin(병음)방식으로 중국어를 변환할 수 있습니다.
변환된 중국어를 복사하여 사용하시면 됩니다.
신창훈,박석지,Sin, Chang-Hun,Park, Seok-Ji 한국전자통신연구원 1988 전자통신 Vol.10 No.1
통신서비스의 확산을 예측하기 위한 확산모형을 제시하였다. Bass모형을 기본으로 하여 가격과 소득을 고려한 확장된 확산모형을 제시하였고, 이 모형을 이용하여 우리나라 전화의 확산에 대한 실증분석을 하였다. This study suggests the diffusion models to predict the spread pattern of telecommunications services. The extended models containing both (either) price and (or) income varible are offered on the basis of Bass model. At the empirical test using Korean telephone data, the models with either price or income varible are the best forecasting model under apriori selected econometric criteria.
권옥배(Gwon, Ok-Bae),신창훈(Sin, Chang-Hun),박승수(Park, Seung-Su),한정민(Han, Jeong-Min),이정환(Lee, Jeong-Hwan) 한국신재생에너지학회 2006 한국신재생에너지학회 학술대회논문집 Vol.2006 No.06
In Japan, research and development were undertaken on gas hydrate-side industrial processes associated with power generation system connections that may particularly be necessary to develop gas hydrated technology-based industrial systems. In so doing, data and engineering technologies useful n formulating guidelines on design of practical process were accumulated. In addition, basic research into theoretical evidence were carried out to promote and support the development of technological elements for those processes. In basic research designed to promote and support the research and development of elemental technologies microanalyses were conducted to understand the decomposition mechanism of mixed gas hydrate. Moreover, measurement technologies that can be applied in industrial processes, such as numerical analyses and concentration ion measurement, were examined. Japan has developed a highly efficient gas hydrate formation process using micro-bubbles with a tubular reactor. Higher formation rate over conventional systems has been obtained by the process. As mentioned above, the technical problems were clarified and the economics were studied from a view point of the NGH technology in this study. The results can be applied for utilization and must contribute to popularization of gas hydrate production.
권옥배(Kwon, Ok-Bae),신창훈(Sin, Chang-Hun),박승수(Park, Seung-Su),한정민(Han, Jeong-Min),이정환(Lee, Jeong-Hwan) 한국신재생에너지학회 2006 신재생에너지 Vol.2 No.2
In Japan, research and development were undertaken on gas hydrate-side industrial processes associated with power generation system connections that may particularly be necessary to develop gas hydrated technology-based industrial systems. In so doing, data and engineering technologies useful n formulating guidelines on design of practical process were accumulated. In addition, basic research into theoretical evidence were carried out to promote and support the development of technological elements for those processes. In basic research designed to promote and support the research and development of elemental technologies, microanalyses were conducted to understand the decomposition mechanism of mixed gas hydrate. Moreover, measurement technologies that can be applied in industrial processes, such as numerical analyses and concentration measurement, were examined. Japan has developed a highly efficient gas hydrate formation process using micro-bubbles with a tubular reactor. Higher formation rate over conventional systems has been obtained by the process. As mentioned above, the technical problems were clarified and the economics were studied from a view point of the NGH technology in this study. The results can be applied for utilization and must contribute to popularization of gas hydrate production.
이선민(Sun-Min Lee),정지헌(Ji-Hun Jung),신창훈(Chang-Hoon Sin),권순일(Sun-Il Kwon) 한국가스학회 2013 한국가스학회지 Vol.17 No.4
본 연구에서는 캐나다 셰일가스전에 위치한 2개의 생산정에 대해 생산특성에 따라 적절한 생산자료 분석기법을 이용하여 분석을 수행하였다. Case A 생산정의 경우 생산자료가 매우 가변적으로 나타나 시간과 중첩시간을 적용하여 비교분석을 실시하였다. 유동영역을 구분하기 위해 생산자료를 로그-로그 그래프에 도시한 결과 천이 유동구간만 나타났다. 시간과 중첩시간을 적용하여 자극을 받은 저류층 면적이 각각 180, 240 acres로 산출되었고, 원시가스부존량은 15, 20 Bscf로 계산되었다. 그러나 산출된 저류층 면적은 경계영향유동자료로부터 산출된 것이 아니기 때문에 최소 값으로 판단된다. 이에 저류층 면적과 감퇴지수에 대한 생산성 예측을 수행하였다. 그 결과 감퇴지수가 0.5, 1로 커질수록 궁극가채량이 1.2배와 1.4배로 증가하였다. 또한 저류층 면적이 240에서 360 acres로 커지면 궁극가채량이 1.3배 증가되는 것을 확인할 수 있었다. Case B의 고압 저류층에 위치한 생산정은 상부지층압에 따른 지층압축률과 투과도를 적용하여 분석하였다. 지역학적 영향을 적용한 경우와 아닌 경우를 비교한 결과, 저류층 면적은 1.4배, 원시가스부존량이 1.5배로 증가하였다. 셰일 가스전 현장자료에 대한 분석 결과, 분석 방법에 따라 원시가스부존량, 궁극가채량 등 향후 생산성 예측이 크게 달라지므로 생산자료에 따라 유사시간, 중첩시간, 지역학적 분석 등의 적절한 분석방법을 적용하여야 정확한 생산자료 분석이 가능할 것으로 판단된다. This paper presents production data analysis for two production wells located in the shale gas field, Canada, with the proper analysis method according to each production performance characteristics. In the case A production well, the analysis was performed by applying both time and superposition time because the production history has high variation. Firstly, the flow regimes were classified with a log-log plot, and as a result, only the transient flow was appeared. Then the area of simulated reservoir volume (SRV) analyzed based on flowing material balance plot was calculated to 180 acres of time, and 240 acres of superposition time. And the original gas in place (OGIP) also was estimated to 15, 20 Bscf, respectively. However, as the area of SRV was not analyzed with the boundary dominated flow data, it was regarded as the minimum one. Therefore, the production forecasting was conducted according to variation of b exponent and the area of SRV. As a result, estimated ultimate recovery (EUR) increased 1.2 and 1.4 times respectively depending on b exponent, which was 0.5 and 1. In addition, as the area of SRV increased from 240 to 360 acres, EUR increased 1.3 times. In the case B production well, the formation compressibility and permeability depending on the overburden were applied to the analysis of the overpressured reservoir. In comparison of the case that applied geomechanical factors and the case that did not, the area of SRV was increased 1.4 times, OGIP was increased 1.5 times respectively. As a result of analysis, the prediction of future productivity including OGIP and EUR may be quite different depending on the analysis method. Thus, it was found that proper analysis methods, such as pseudo-time, superposition time, geomechanical factors, need to be applied depending on the production data to gain accurate results.