農業気象 15 巻, 4 号

煙の研究

The diffusion phenomena of smoke emitted from a continuous point source in the atmospheric surface layer are dealt with separately in the vertical and in the lateral wind directions. For the lateral diffusion the Taylor method making use of Lagrangian correlation function is applied and for the vertical diffusion the Monin method making use of the relation between the vertical turbulent velocity components and the mean horizontal wind velocity is applied. The diffusion width ‹Y²›^1/2 and the diffusion height ‹Z²›^1/2 of smoke from the ground source are calculated theoretically under characteristic thermal conditions and the downwind distributions of maximum concentration χ_p are calculated theoretically too as follows being x the downwind distance from the source:
(a) Extremely unstable:
‹Y²›^1/2_??_x,
‹Z²›^1/2_??_x^1.5,
χ_p_??_x^-2.5.}
(b) Neutral:
‹Y²›^1/2_??_x,
‹Z²›^1/2_??_x^0.8,
χ_p_??_x^-1.8.}
(c) Extremely stable:
χ_p_??_x^-1.5--1.0}
These results are shown in good agreement with Cramer's (1957) empirical relations obtained at the Project Prairie Grass.

風蝕防止に関する研究

Winderosion damages frequently such bare-cultivated land all over as sweet-potato-field digged up. We checked up for degree of the erosion in an open land and in four partitions whose ditch-width are 120cm, 180cm, 240cm, and 300cm, in each.
Most of flying soil, saltation as it is, drifts under 50cm, over the ground, while 10% of it moves in the shape of surface creep. Catch ditch of flying soil is intended for the interception of all the surface creep and the greater bulk of saltation there into the veryditch. Though its capacity is dependent on the erosive degree how the ground is blessed with, we found that 50% of saltation or so and the whole surface creep can be trapped.
Each ditch with shorter interval brings greater efficacy, but we are afraid unfit pile-up of soil may let bring severe winderosion, so that adequate ditch should be of two meter intervals. An inverted trapezoid, V-concave form, is sure to be better than any other, for a ditch with vertical section, U-form, is fragile and soon filled up with soil.

冷気の流出と霜道の形成

A preliminary study on the cold air drainage and the local distribution of frost was made in Matsukawa-machi, Shimoina, Nagano Prefecture on March 31 to April 5, 1958. Analyzing thermograph records observed at eight stations in the area, movements of the cold air were discussed in detail. Then, an example of up and down motion of inversion layer at night of April 4-5 was given in relation to the cold air drainage. A distribution map of air temperature measured by mobile observation in the most frosty part of the area showed marked localization. As conclusion, it was confirmed that the air came from the upper area of the river course, but they formed colder air masses at the upper parts of the studying area, and then flew down as the cold air drainage under the influence of micro-topography.

土壌面蒸発を土壌水分傾度より推定する方法 (続報)

The report on the possibility of computing the amount of evaporation from the soil surface using the vertical moisture gradient measured in the soil was made in the previous experimental study (Suzuki, S and Maruyama, E. 1957).
We measvred the evaporation from the surface of loam-and clay-soil by the method mentioned in the previous report, in the vast plain field attached to the Aero-Meteorological Observatory, Tateno in Ibaragi Prefecture, and at the same time in order to check the actual amount of evaporation from the same soil, we weighted hourly a steel cylinder vessel containing loam and clay-soil in it imbeded in the earth of the same soil structure.
Those two methods led to the vary same values. At the same time the values were found coincided with the ones estimated from the vertical gradient of vapour density in the atmosphere near the ground which was observed by another member of our observation group in the neighbourhood of the Observatory.
It was of much interest that the values calculated by means of Thornthwaite-Holtzman's formula reffered to the vertical distributions of wind-velocity, relative humidity and temperature, which were observed by the same group and in the same place, were found considerably different from ours.

水田の輻射収支及び漏水田の水温

In order to research the radiation balance in the paddy field and the relation between water temperature in the percolating paddy field to percolation, the author carried out the observations of the radiation, water temperature, percolation in August 1958 at Nyuzen, Toyama Pref.
The radiations were measured by using Beckman's net radiometer, hemispherical radiometer and Golzinsky solarimeter.
The results obtained are as follows;
(1) The radiation balance in the cultivated field is shown as following formula,
S=RS(1-α)+(R↓-R↑)
where S, RS, α, R↓, R↑ refer to the net radiation, short wave radiation, albedo, long wave radiation from upward and that from downward, respectively.
The results measured in the paddy field was shown in Fig. 2.
(2) The relations between rising effect of temperature in the percolating paddy field to percolation was found theoretically as shown in formula (16),
θ_wp-θ₀=(θ_w0)exp(v/-(Lρ_aDdq_s/dθ+c_pρ_aD)),
where θ_wp, θ_w0, v, L, ρ_a D, c_p, q refer to the average water temperature in the percolating paddy field, average water temperature in the no percolating field, irrigating watea temperature, percolation (c. c. per min), latent heat (590 cal), density of air, diffusion coefficient (39cm per min), specific heat of air and specific humidity, respectively.

電気抵抗法による土壌水分の測定

石膏ブロックの測定可能な範囲は水分当量附近より萎凋点までの土壌水分であり, ナイロンユニットは飽和状態より萎凋点までの広い範囲にこわたつて測定可能である。
一般にご吸収体を用いて間接的に土壌水分を求める場合は含水比の多い場合は精度がかなり低下するが乾燥状態にこなるにつれて敏感にご作用し或る程度精度が高い様である。吸収体は土性に応じてそれぞれ適したものを選択使用すべきで, 砂丘土壌ではナイロン・ユニット, 赤土では石膏ブロックでも良いが, ナイロン・ユニットの方がより適していると思はれる。又, 吸収体にはそれぞれ個体差があるからして, 実際に圃場で使用する前に予め測定することが大切であり, 埋設に際しては土壌と吸収体が良く接触するようにする必要がある。

防風墻の防風効果に及ぼす前後の地物の影響

本研究は防風墻前後近くに別の防風墻又は地物が存在した場合, それが防風墻の防風効果に如何なる影響を与えるかを見たものである。
実験は室内で風洞並びに簡易速風装置を使用した模型実験及び野外で自然風の中での実地試験等によつて行われた。得られた結果は次の様である。
1. 防風墻の前後に, 特に前方に地物があつた場合, 単独の場合よりも防風効果は遙かに低下する。尚, その際防風墻風下の風の垂直分布は今までに比してずつと下層部が強くなる。
2. 地物が最も強響する距離は垣状のもので前方2～倍の位置である。然し風の乱れの状態や地物の形状によつて多少移動するものと思われる。
3. 前方地物として板塀の様なものでなく, 柵の様に隙間の多いものや乱立した形のものでも, その防風墻防風効果に影響を及ぼす。
4. 以上の諸結果は野外の自然風の中での実験でも大体見られる。
5. 前方地物が防風墻の効果を低下させる原因は, 地物と防風墻の相互的位置の関係から防風墻単独の場合より遙かに流れに対する抵抗が少なくなるためで, その結果として風下への効果範囲も小さくなる。
6. 上述の原因から防風墻の前方に接近して他の防風墻を併置する時は, 一定限度以上の遮蔽率の場合は防風効果は減退する。但し遮蔽率の低い時はその不足を補い防風効果を増す。
7. 補助防風墻をもつて, 下部に隙間を有する防風墻を補填する際に, その位置によつては両者の相互関係から防風墻の効果が減退し, 補填の意義が減少する事もある。
8. 起伏地形で風向転換による防風を行う場合, 前方地物の影響は平地以上に大きい。