畑地灌漑に関する基礎研究 : 第V報. 群落状態に於ける畑作物用新型吸水自記装置とその利用観測成績
スポンサーリンク
概要
- 論文の詳細を見る
In order to study the water consumption of crops as the fundamental knowledge of irrigation, it is desirable to record the consumptive absorption rate automatically not in each individual plant but under community conditions. As the automatic water consumption recorders designed in the past were of automatic balance types, material plants were limited in their weight and also in number, usually only one or a small number of plants having been used. Therefore, it was hitherto impossible to record the variation of water consumption of field crops under community conditions continuously. TAMAI (1956), one of the authors, introduced the automatic water absorption recorder for field crops (Fig. 3) the design of which was based on a different principle from that of BRIGGS & SHANTZ (1915) and STEINBERG (1930). This recorder was one of the micro-automatic recorders for individual plants and could not be used for plant community. The authors newly devised another type of recorder, which is fit for the use of a group of a considerable number of plants. In the present paper, the construction of the new type recorder and some results obtained by using it will be stated. For the purpose of determining water absorption rate of crops under community conditions, many porous cups for auto-irrigation were connected with each other as shown in Fig. 1, and they were placed on the bench. Soil was piled up on the bench to bury the porous cups, then crops were planted in the soil, and the soil surface was covered with vinyl cloth. The amount of water absorbed by crops could be known by measuring the amount of lost water in the reservoir (R). Furthermore, the automatic recorder (recording flowmeter), as shown in Fig. 2, was provided between the porous cups (P) and the reservoir (R) so that the water absorption of crops could be recorded continuously by it. This recording flowmeter is composed of three main parts: (1) A lever (L) equipped with a water tank (T); (2) Electric valves (V_1, V_2) which are worked by electric magnets (M_1, M_2) ; (3) A part composed of a recording drum (D), a electric magnet (M_3) and a recording pen (R. P.). The water tank (T) is connected with the reservoir (R) and the porous cups (P), which supply water to crops, through the two valves (V_1 and V_2) respectively. Suppose a difinite amount of water in the tank is spent by the crops, the lever inclines to the left because the right side of the lever becomes light. Then a balancing ball (B. B.) rolls on the lever from the center to the left and accelerates the touching of a contact point (K_1). If the contact point touches, then the electric magnet (M_1) acts, the valve (V_1) opens, and water flows down from the reservoir (R) into the tank (T). When the amount of flowing water becomes equal to the amount of water spent by the crops, the lever inclines to the right, and the balancing ball on the lever rolls back to the center, accelerating the touch of another contact point (K_2). If the contact point (K_2) touches, the electric magnet (M_2) acts, the valve (V_2) opens, the valve (V_1) closes, and the flowing water stops. Here the water in the tank is again absorbed by the crops. Simultaneously with the action of the magnet (M_2), the electric magnet (M_3) acts and a line is drawn with the recording pen (R. P.) on the drum (D). Thus, the absorption of water, the supply of water and the recording of lines being repeated, the water absorption of crops is recorded on the drum with the density of lines. Contact points (K_3 and K_4) were especially provided to use electricity instantaneously. Though lines were drawn at each time when 50 cc of water was absorbed, the volume of water absorbed at a time is adjustable by changing the size of the balancing ball (B. B.) and the distance where it rolls. The recording flowmeter in Fig. 2 can measure a large amount of flowing water with less expense than that in Fig. 3, because mercury is not used in the former but it is used in the l
- 日本作物学会の論文
- 1959-01-01
著者
関連論文
- 香料ゼラニウムの精油分泌機能に関する生理・生態学的研究 : (第1報)腺鱗分布密度と収油率の関係及びその種間差異について
- 香料ゼラニウムの精油分泌機能に関する生理・生態学的研究 : (第2報) 原料葉の乾燥が収油量及腺鱗分布密度に及ぼす影響 (第115回 講演会)
- 香料用ゼラニウムの育種に関する研究 : II. Pelargonium denticulatumにおける倍数性系統の作出とその特性
- 陸稲と二三の作物の生育時期別吸水特性の自記装置による調査
- 香料用ゼラニウムの育種に関する研究 : VI.戻雑種B_1およびB_2の特性ならびに実用的有望種(B_1 No.10)の選抜
- 香料用ゼラニウムの育種に関する研究 : V.Pelargonium roseumおよびP.denticulatumの種間雑種個体間の形態、収油率ならびに油質の変異
- 香料用ゼラニウムの育種に関する研究 : IV. Pelargonium roseumおよび P. denticulatumの倍数体間交雑による種間雑種の育成
- 香料用ゼラニウムの育種に関する研究 : III. Pelargonium denticulatum および P. roseumの細胞学的観察
- 環境制御装置による畑作の水分代謝の研究 : 第1報 水稲および柑橘の低温処理と水分代謝
- 畑地灌漑に関する基礎研究 : 第VI報. 畑作早期水稲の二三の吸水特性について
- 畑地灌漑に関する基礎研究 : 第V報. 群落状態に於ける畑作物用新型吸水自記装置とその利用観測成績
- 香料用ゼラニウムの育種に関する研究 : I.Pelargonium roseumにおける倍数性系統の作出とその特性