日本地球惑星科学連合2016年大会

講演情報

ポスター発表

セッション記号 M (領域外・複数領域) » M-TT 計測技術・研究手法

[M-TT31] インフラサウンド及び関連波動が繋ぐ多圏融合地球物理学の新描像

2016年5月26日(木) 15:30 〜 16:45 ポスター会場 (国際展示場 6ホール)

コンビーナ:*山本 真行(高知工科大学 システム工学群)、新井 伸夫(名古屋大学減災連携研究センター)、市原 美恵(東京大学地震研究所)

15:30 〜 16:45

[MTT31-P01] 宇宙用真空装置を用いたインフラサウンドセンサーの較正実験

*山本 真行1 (1.高知工科大学 システム工学群)

キーワード:インフラサウンド、較正、宇宙用真空装置

Infrasound monitoring is important for atmospheric study and disaster prevention for destructive geophysical events such as volcanic eruptions, thunderstorms, landslides, tsunamis, etc. We have been developed a kind of infrasound sensor in our laboratory since 2007, then most recently, a combined type infrasound sensor was successfully developed, collaborating with a company of RESONA ALES in 2015. At a time of infrasound sensor construction, precise calibration with simulated infrasonic waves is significant for evaluation. Here we introduce a method of calibrating infrasonic waves with precise pressure amplitude and frequency with using a space chamber in laboratory. The space chamber is usually used at a scene of testing rocket-borne instruments and satellites in extremely severe rarefied environment before the launch with using multiple vacuum pumps to create space environment in laboratory. However, we use the chamber as an extremely rigid volume without having any surrounded surface change during the calibrating experiments. The infrasound is understood as pressure waves in the atmosphere, thus the same kind of waves can be simulated if we inject a fixed small volume into the fixed amount of atmospheric volume enveloped by the rigid chamber. The simulated pressure level can easily be calculated by using a ration between the injected small volumes per the large amount of enveloped space. A small space chamber in Kochi University of technology (KUT) with 240 litter volume was used for this kind of calibration with a small syringe with giving 1/108 of the 240 litter per a fixed time constant. The syringe can be accurately controlled by a motor-driven push-pull motion mechanics with a long time period up to 1000 s. Therefore, sinusoidal pressure waves with a pressure level of 0.001 Pa as well as extremely slow frequency of 0.001 Hz was realized for calibration. By using such facilities in KUT, precise calibration with the developed infrasound sensor as well as any other infrasound sensors, microphones, and barometers can be realized. In this paper, calibrating datasets for various types of sensors will be shown.