This study investigated the noise reduction effect according to the structure of the sound-absorption and insulating materials in order to maximize the noise reduction effect in various noise environments. For this purpose, the transmission loss according to the change in hole size of the performated plate in sound-absorption and insulating board was predicted using an CAE model. The sound-absorption and insulating board was modeled and the computation of the transmission loss was performed after applying the physical properties and boundary conditions. The pure sounds of 32Hz to 4,000Hz were generated, and the analysis was performed by changing the diameter and pitch of the perforated plate. It was confirmed that the influence of the diameter and pitch of the perforated plate is closely related to the structure that make up the sound-absorption and insulating material. In order to effectively reduce the variously changing noises, it is believed that a method of improving transmission loss for each frequency band of interest is needed by changing the structure of the sound-absorption and insulating material so that the diameter and pitch of the perforated plate can be changed.
대기 압력 변동을 측정하는 인프라사운드 관측 기술을 통하여 원거리 지표폭발 사고를 분석하였다. 2019년 12월 24일 전남 광양시에서 발생한 2차례 폭발 사고에서 발생한 인프라사운드 신호가 151-435 km 거리에 위치하는 12개 음파 관측소에 기록되었다. 당시 인프라사운드는 북북서 방향의 성층권 바람에 의해 약 40 km 고도에서 굴절되어 같은 방향에 분포하는 관측소에 도달하였다. 반면, 약 10 km 고도에서는 강한 서풍의 영향으로 대류권 굴절 신호가 북동 및 동쪽 방향에 위치하는 관측소에 도달하는 등 방향에 따라 상이한 전파 경로를 보였다. 대기 유효음파속도구조와 포물선 방정식 모델링을 통해 전파 경로상의 투과손실을 계산하고 폭발 지점으로부터 기준거리에서의 초과압력을 추정하였다. 추정된 초과압력은 초과압력-폭발량 관계식에 적용함으로써, 두 차례의 폭발은 각각 14, 65 kg TNT 폭발 에너지에 상응하는 것으로 계산되었다. 1차 폭발 당시에 폭발 충격으로 부속물이 대기 중으로 비산하는 현상이 관측되었고, 폭발 충격에 의한 파편 운동과 초과압력 간의 관계식으로 1차 폭발의 에너지는 약 49 kg 이하 TNT 폭발에 상응하는 것으로 계산되었다. 본 연구에서 제안한 폭발 에너지 추정 방법은 향후 다양한 원거리 폭발 에너지 계산에 활용이 가능하리라 본다. 향후 계산 결과의 신뢰도를 높이기 위해서는 대기 속도구조 불확실성에 대한 연구와 다양한 발파 자료를 통한 검증 연구가 필요하다.
Today, conventional CVT equipped vehicle controls engine torque and gear ratio by using engine torque map and shifting map. But this control process is difficult to optimize the fuel economy when the driving mode is changed arbitrary. In this study, I propose the real-time CVT control with considering the power loss of transmission system to improve vehicle fuel economy and drivability. The driving performance and fuel economy of the proposed control logic is analyzed by backward simulation and the validity of new control logic is verified.
This study aims to find an appropriate window for apartment to provide proper sound insulation. To achieve this goal, measured windows with various thicknesses of the sound insulation performance of inner air space and sound absorption materials in the inner air space. As a result of this study the improvement of the sound insulation performance of windows was shown through the analysis and the measuring of window these characteristics. These results may be applied to the manufacture of window frames and provide basic data for the improvement of the sound insulation performance of windows.
PURPOSES : This study is to compare sound transmission loss(STL) value depending on the four kinds of materials, PC(Polycarbonate), PMMA(Polymethyl mathacrylate), PE(Polyethlyene), PP(Polypropylene), and two types of structure, single layer and double with vacuum layer, of soundproof panel.
METHODS : With four sorts of polymer material, the specimens were made as various structures, 4 mm and 8 mm of single soundpoof panel and vacuum layered 4 mm of one. The experimental condition and procedures were complied with authorized process test, KS F 2808.
RESULTS: STL of single panel made of PC were the greatest followed by PMMA, PE, PP regardless of the thickness of panel, However, STL of PMMA panel began to decrease around 2500 Hz and reached the lowest value among others in 5000 Hz. Vacuum layer soundproof panel showed good performance in more than 2000 Hz. Only vacuum layer panel made of PC presented resonance frequency at 800 Hz while that of other vacuum ones at 1000 Hz.
CONCLUSIONS: According to results of single layer, it was found that single panel functioned as the theorical way we expected in terms of surface density. That trends were blurred as the panel got thicker. And it was suggested also that vacuum layer panel performed well at high frequency, more than 2000 Hz.