본 연구는 가스추진 174K급 LNG 운반선의 가스 압축기실에서 발생하는 가스누출 모사를 통해 가스탐지기의 최적 위치를 분석 하였으며, 새로 개정된 IGC 코드에 명시된 안전규정을 만족하는 합리적인 방법도 함께 제안하였다. 가스압축기실에서의 LNG 가스누출 수치해석을 위해, 실제 ME-GI 엔진이 장착된 174K급 LNG 운반선의 압축기실 형상과 장비, 배관의 배치와 같은 치수로 3D 설계되었다. 가 스누설에 대한 시나리오는 305 bar의 높은 압력과 1 bar의 낮은 압력을 적용하여 진행하였다. 고압용 핀홀의 크기는 4.5, 5.0, 5.6 mm이고 저압용은 100, 140 mm이다. 해석 결과, 5.6 mm 핀홀(고압)과 100, 140 mm 핀홀(저압) 상태의 누출에 대한 환기평가에서 가연성 가스농도는 심 각한 위험이 없음을 확인하였다. 그러나 개정된 IGC 코드에 따라 설치된 압축기실의 가스 감지 센서의 실제 위치는 다른 지점으로 이동 해야 하고, 측정 지점이 현 규정에서 요구하는 것보다 더 추가되어야 함을 확인하였다.
핵분열로 인해 생성되는 방사성 노블가스는 주변국의 핵활동을 감시할 수 있는 중요한 지표 핵종이다. 특히 제논은 생성량이 많고 반감기가 짧아 핵실험 탐지에 적합하며 크립톤은 핵연료 재처리 탐지의 추적자로 활용되고 있다. 방출된 방사성 노블가스는 막대한 대기에 희석되어 농도가 감소하고 일부는 시간에 따라 방사능이 감쇠하기 때문에 대기 중에는 매우 극미량으로 존재하게 된다. 따라서 측정을 통해 의미 있는 데이터를 얻기 위해서는 가능한 낮은 수준의 MDA를 설정하는 것이 중요하다. 본 연구에서는 방사성 제논과 크립톤을 동시 포집 할 수 있는 장비인 BfS-IAR시스템을 활용하여 이론을 통해 MDA 를 산출하였다. 또한 MDA 산출방식의 변화, 신뢰수준의 정도는 물론 계측 조건의 변화에 따른 영향을 확인하고 MDA를 저감하기 위한 방안들을 모색하였다. 그 결과 배경농도가 극미량인 제논의 경우 전처리과정의 효율화와 안정적인 계측 성능 유지가 가장 중요한 요소로 판단되었으며, 크립톤의 경우 제논과 달리 시료의 방사능이 높기 때문에 MDA 재설정을 통한 분석조건이나 시스템 최적화를 통해 효율적인 분석을 수행할 수 있을 것으로 판단된다.
We report on the efficient detection of NO gas by an all-oxide semiconductor p-n heterojunction diode structure comprised of n-type zinc oxide (ZnO) nanorods embedded in p-type copper oxide (CuO) thin film. The CuO thin film/ZnO nanorod heterostructure was fabricated by directly sputtering CuO thin film onto a vertically aligned ZnO nanorod array synthesized via a hydrothemal method. The transport behavior and NO gas sensing properties of the fabricated CuO thin film/ ZnO nanorod heterostructure were charcterized and revealed that the oxide semiconductor heterojunction exhibited a definite rectifying diode-like behavior at various temperatures ranging from room temperature to 250 oC. The NO gas sensing experiment indicated that the CuO thin film/ZnO nanorod heterostructure had a good sensing performance for the efficient detection of NO gas in the range of 2-14 ppm under the conditions of an applied bias of 2 V and a comparatively low operating temperature of 150 oC. The NO gas sensing process in the CuO/ZnO p-n heterostructure is discussed in terms of the electronic band structure.
This study concerns the integrated gas sensor system of wire and wireless communication by using IoT(Internet of Things) technology. First, communication part is that it delivers the detection information, which transferred by wire or wireless communication and required control procedure based on a wireless module that receives the gas leakage information from wired or wireless detector, to administrator or user’s terminal. Second, receiver part is that it shows the location and information, which received from the wired detector formed by a detecting sensor’s node as linking with the communication part, and transfers these to the communication part. Third, wireless detector formed as a communication module of a detecting sensor node is that it detects gas leakage and transfers the information through wireless as a packet.Fourth, wired detector communicated with the receiver part and formed as a communication module of a detecting sensor node is that it detects gas leakage, transfers and shows the information as a packet. Fifth, administrator’s terminal is that it receives gas leakage information by the communication part, transfers the signal by remote-control, and shut off a gas valve as responding the information. Sixth, database is that it is connected with the communication part; it sets and stores the default values for detecting smoke, CO., and temperature; it transfers this information to the communication part or sends a gas detecting signal to user’s terminal. Seventh, user’s terminal is that it receives each location’s default value which stored and set at the database; it manages emergency situation as shutting off a gas valve through remote control by corresponding each location’s gas leakage information, which transferred from the detector to the communication part by wireless.It is possible to process a high quality data regarding flammable or toxic gas by transferring the data, which measured by a sensor module of detector, to the communication part through wire and wireless. And, it allows a user to find the location by a smart phone where gas leaks. Eventually, it minimizes human life or property loss by having stability on gas leakage as well as corresponding each location’s information quickly.
This study is in regard to the gas detection system and gas detection method utilizing smart phone. This study includes; 1) the sensor module attached to the smart phone to detect and measure flammable gas or toxic gas; and 2) gas detection APP which is installed inside the smart phone and recognizes the user information and location information automatically by reading RFID tag indicating the user or the location to detect gas through the contact area where RFID and blue tooth reader is installed inside of the above mentioned smart phone, and then measures the combustible gas or toxic gas by operating above mentioned sensor module and obtains the data thus measured, and above mentioned smart phone is characterized by its transmission of the above mentioned user information, location information and measured data which are obtained by above mentioned gas detecting APP to operation server via communication network. With this, reliability for the location detecting gas by the user, the result of the measurement, etc. can be secured. Furthermore, this provides the effect of preventing artificial manipulation at the time of input which is associated with the identification of the user to be measured by utilizing removable sensor module and application or the mistake resulted from wrong input by the user.In addition, by transmitting the measured data from the sensor module carrying out gas detection to operation server, this provides the effect of making it possible to process the data thus collected to a specialized data for combustible gas or toxic gas.
In this study, a micro gas sensor for NOx was fabricated using a microelectromechanical system (MEMS) technology and sol-gel process. The membrane and micro heater of the sensor platform were fabricated by a standard MEMS and CMOS technology with minor changes. The sensing electrode and micro heater were designed to have a co-planar structure with a Pt thin film layer. The size of the gas sensor device was about 2mm×2mm. Indium oxide as a sensing material for the NOx gas was synthesized by a sol-gel process. The particle size of synthesized In2O3 was identified as about 50 nm by field emission scanning electron microscopy (FE-SEM). The maximum gas sensitivity of indium oxide, as measured in terms of the relative resistance (Rs=Rgas/Rair), occurred at 300˚C with a value of 8.0 at 1 ppm NO2 gas. The response and recovery times were within 60 seconds and 2 min, respectively. The sensing properties of the NO2 gas showed good linear behavior with an increase of gas concentration. This study confirms that a MEMS-based gas sensor is a potential candidate as an automobile gas sensor with many advantages: small dimension, high sensitivity, short response time and low power consumption.
ZnO thin films were prepared on a glass substrate by radio frequency (RF) magnetron sputtering without intentional substrate heating and then surfaces of the ZnO films were irradiated with intense electrons in vacuum condition to investigate the effect of electron bombardment on crystallization, surface roughness, morphology and hydrogen gas sensitivity. In XRD pattern, as deposited ZnO films show a higher ZnO (002) peak intensity. However, the peak intensity for ZnO (002) is decreased with increase of electron bombarding energy. Atomic force microscope images show that surface morphology is also dependent on electron bombarding energy. The surface roughness increases due to intense electron bombardment as high as 2.7 nm. The observed optical transmittance means that the films irradiated with intense electron beams at 900 eV show lower transmittance than the others due to their rough surfaces. In addition, ZnO films irradiated by the electron beam at 900 eV show higher hydrogen gas sensitivity than the films that were electron beam irradiated at 450 eV. From XRD pattern and atomic force microscope observations, it is supposed that intense electron bombardment promotes a rough surface due to the intense bombardments and increased gas sensitivity of ZnO films for hydrogen gas. These results suggest that ZnO films irradiated with intense electron beams are promising for practical high performance hydrogen gas sensors.
최근 의료진단 분야와 다른 적용분야를 위해 대면적 매트릭스 구조의 엑스선 영상이 활발하게 연구되어 오고 있다. 본 연구에서는, 의료진단을 위한 새로운 평판형 디지털 엑스선 가스 검출기를 제안하고 그에 따른 특성을 검증하고자 한다. 대기압에 반해 가스를 주입하는 어려움 때문에 챔버 형태의 구조로 만들어 질 뿐, 평판형 디지털 엑스선 가스 검 출기는 아직 어디에서도 연구된 바 없다. 이에 본 연구에서는 디스플레이 패널 제작 기술을 이용하여 샘플제작을 성공 하였다. 실험적인 측정을 위해 만들어진 샘플은 상판에는 유리기판위에 전극, 절연층, 산화마그네슘 보호막을 형성하 였으며, 하판에는 엑스선 형광층과 전극을 형성하였다. 누설전류와 엑스선 민감도를 측정하였으며, 전기장에 대한 민 감도의 선형성 측정 등의 전기적 특성평가를 실시하였다. 이에 대한 결과로 안정된 누설전류와 엑스선 민감도를 얻었 다. 그리고 조사 선량에 따라 좋은 선형성을 보이는 등 넓은 진단 동적영역을 확인할 수 있었다. 이러한 결과로 평판형 엑스선 가스 검출기의 디지털 엑스선 영상 검출기로의 적용 가능성을 확인 할 수 있었다.