気象集誌. 第2輯 41 巻, 6 号

台風のレイン・バンドの理論

水平円形うずに重ねられたエラストイド・グラボイド波は,ある条件下では半径(γ)の方向にしま状の様相を呈する。この様相を近似的に表わすファクターexp(ikγ)が,エラストイド・グラボイド波に固有なファクターexp(ilθ)と結合して,らせん状の上昇気流域が得られる。ここでθは方位角である。 1の小さい値の波は中心近くでのみ,また1の大きい値の波は中心からかなり離れた所でのみ半径方向にしま状の様相を呈することを示す。またこの種の波動の発生に関しても言及する。

植物群落内部の気流の乱流構造について

麦畑で行なわれた観測結果から経験的に得られた指数関数型の畦間風速分布U(Z)=UHexp{-α(1-Z/H)}
にしげきされ,この型の風速分布を与えるために必要であろうと思われる畦間気流の乱流構造について考えた。ここにHは植物群落の高さを表わす。
これまでに行なわれたわずかばかりの観測から,畦間でのうずの大きさとエネルギーについて定性的な知識も得られているし,植物群落上部では風速分布が対数法則U(Z)=V*H/κlnZ-d/Z0でよく表現されることも知られている。ここにdは地表面修正量を表わす。
著者の穂波現象に関する考察結果を利用して,畦間気流の中のうずは穂波を生ずるうずが若干変形されたものであるとして,指数分布式を特長づけるαが植物群落の葉の繁茂度やdなどと経験的に関係づけられている。

雪の形と化学成分

雪の形別に採集した試料について,その含有化学成分,Cl, Na, NH4, SO4, Ca, Mg, NO2, Fe, Siを測定した。
雪は柱状結晶・雲粒つき六花・六花・放射状六花・霰などに分類された。含有化学成分は,雪の形別に特徴的なあらわれ方をすることがわかった。
(1)柱状結晶中では,Na, C1, NH4の濃度は他の結晶形のものに比べ最も少ない。
(2)NH4の量は六花に最も多く含まれている。
(3)C1とNaの濃度は,霰で最大で, C1とNaの比は,海水中のClとNaの比と非常ににている。

1959年8月14日,台風7号の北上に際し津付近に発生した集中豪雨について

Two remarkable groups of precipitation were observed as the typhoon 5907 advanced northward through the central part of Japan. One of these groups was observed in the vicinity of Tsu city west of the typhoon path, showing a heavy rainfall amounting to 95.3mm hr-1. The other group brought about one-third hourly precipitation of the former on the mountainous areas in front of the typhoon. The mechanism of these rainfalls is analyzed using isobaric and isentropic charts, with the following results:
(1) These rainfalls are qualitatively explainable by use of isentropic analysis, though the observed precipitation does not coincide with a computed one based on the large scale analysis.
(2) From the observed value of the former precipitation, a small scale disturbance is presumed, which took birth on the westside of the typhoon trajectory owing to an interaction of westerly currents and the typhoon, and the horizontal scale of the disturbance is estimated to be about 50 km. In other words, this is inferred to be a meso-scale disturbance possessing an ascending velocity of 2m sec-1, or an isentropic slope of 1/20.

体感気候と不快指数

Applying the equation of turbulent transfer to the heat loss from a human body, an equation is obtained which describes that the heat loss is proportional to the gradient of total heat (enthalpy) . But for practical purposes the heat loss is assumed to be proportional to the difference of total heat, and a transfer coefficient is introduced instead of eddy diffusion coefficient. When it is comfortable, i. e. in spring or autumn, the heat loss is considered to be the normal. An index (=comfort index) Ic is defined as a ratio (heat loss)/(normal heat loss), and also another index (discomfort index) ID is efined as ID=1-Ic. Thus ID will denote the rate of disturbance for the development of normal heat loss. ID will also be used as a climatic index ; thus adopting reasonable values for the total heat, it is found that
(i) ID>30% corresponds to the climate : without clothes, (ii) 30%>ID>10% : summer clothes,
(iii) 10%>ID>-10%: spring clothes, (iv) -10%>ID>-30%: winter clothes, (v) -30%>ID: protecting outfit against cold.
The effect of wind on the index is readily taken into account by assuming the square root law of wind velocity for the coefficient, and it is shown explicitly that the effect is larger in the cooler climate than in the warmer. The difference in the indices due to clothing is also discussed and the relation is proved to be linear. Finally two charts are given, one (Fig. 1 in the text) denoting relations between (dry-bulb) temperature, relative umidity, wet-bulb temperature, enthalpy, discomfort index, and wind velocity, and the other (Fig. 2 in the text) denoting the relation between our index ID and hitherto used index ID'.

落下紙片と雨滴の衝突について

In order to consider the effect of random walking on the process of coalescence, the blotting paper fragment (2×2cm2) coated with soluble blue is dropped through the rain from about 9 meter height above ground.
The number of rain droplets collected by the paper fragment increases proportionally to the falling duration of the paper fragment and the spacial concentration of rain droplets, but this number has no relation to the size of rain droplets or the relative velocity of paper fragment with respect to rain droplets.
The rate of collision is about twice the expected value, which is calculated under the assumption that the paper fragment falls vertically with constant cross-section and average speed.