SU886845A1 - Rice irrigation system - Google Patents

Description

The invention relates to agriculture, namely to engineering rice irrigation systems.

Rice systems with cards of a wide filling front and 5 dumps are known, in which individual cells form a single check, and a cart irrigation channel is combined with a dump.

The disadvantages of the known systems include the large specific length of the map irrigation network, low efficiency and degree of land use, unsatisfactory reclamation state of the lower parts of the system.

A well-known rice irrigation system 15 including district distribution and discharge channels, cards, checks located in two parallel rows between district distribution and discharge channels, a network of card irrigation and drainage channels, check outlets and waste structures, one for each adjacent to the card sprinkler and each check adjacent to it. 25

This system is closest to that described by technical nature.

The peculiarity of the arrangement of checks in two rows made it possible to limit the length of irrigators and discharges, bringing them only to the middle line between the first and second rows of checks so that they, alternating between themselves, formed a comb-shaped figure in plan view.

However, this system does not provide for the possibility of reuse of irrigation water, in addition, with open and peeled construction drainage channels require periodic repair due to the low stability of the slopes of the channels, which are exposed both from the outside - by flows flowing through the channel and from the inside - by filtered masses of water from checks per channel.

The aim of the invention is to further reduce water losses, increase the efficiency of the card irrigation canals and increase the stability of the slopes of the card drainage channels.

This goal is achieved by the fact that each check adjacent to the card irrigation canal is equipped with an additional check outlet from the card irrigation canal to the check, and each adjacent check is equipped with an inter-check outlet, and the waste structures of the adjacent checks are installed directly on the precinct discharge channels.

The drawing schematically shows a rice irrigation system.

The rice irrigation system includes a district distribution channel 1, a cart irrigation channel 2, a district discharge channel 3, card drainage channels 4, rollers 5, checks 6, 7, 8, 9, check outlets 10 at the head of a cart irrigation canal 2, check outlets 11 at the end of the cart irrigation canal 2, maps 12, waste facilities 13, additional check outlets in the head of the cart irrigation canal 2 and inter-check outlets 15.

The system works as follows.

During the first and subsequent flooding from the district distribution channels 1, water is supplied to the card irrigation canals 2, from where through the outlets 14 (in their head) to adjacent first checks 8, 9. Additional outlets 14 are designed for the maximum flow rate required to flood two checks, therefore, the flooding period of checks is 8 and two times less than usual (about 1.5 days).

During this period, the main outlets 10 and 11 are closed. Having accumulated the volume of water necessary for flooding on checks 8 and 9, check outlets 14 are blocked, after which the water from checks 8 and 9 is passed through outlets 15 to checks 6 and 7 adjacent to them. After holding the time necessary for agricultural technology, water from the checks 6 and 7 is discharged through the structures 13 directly into the precinct discharge channel 3.

It should be noted that check-outlets 14 and inter-check outlets operate no more than 9 days a year out of a total of 105 days of the irrigation period. This leads to more simplified requirements for their implementation, that is, they can be non-automated.

To maintain a certain predetermined layer of water in the checks during the growing season of rice, i.e., to replenish the losses of the check filled with water, which arise due to transpiration of the plants, surface evaporation of the water mirror and filtration, check outlets and 11, which can be performed manually, are used.

The card irrigation channel 2, therefore, can only be designed to replenish water losses in two checks 6 and

7. Usually this is 1.5-2.5 g / s-ha. These costs are very stable and channel 2 efficiency is high. The low costs of channel 2 allow it to be performed in a pipe or in a tray. For example, for checks of 6 ha, sprinkler 2 may have a pipe diameter of 50 cm.

Check outlets 10 and 11 operate most of the irrigation period and can be automated. Consumption at these facilities is 5-7 times less than on known systems, which greatly simplifies the automation of the system. Drainage channels 4 with such a network design work only to drain filtration water with a specific flow rate of 0.4—0.7 l / s-ha. Since they are not loaded with waste water, the stability of their walls increases significantly.

Given the described operation of the system, it is advisable to carry out water outlet and waste facilities, maintaining a certain ratio between their estimated costs. If we take the estimated flow rate or throughput of the main check facilities 10, 11 as Q, then the throughput capacity of additional check outlets 14 must be maintained within 15-18 Q, and the overflow intercheck outlets 15 within 5—9 Q and check waste facilities 13 within 2-3 Q.

The main technical and economic advantage of this system is expressed in the saving of irrigation water when filling in receipts of about 1000 m ³ / ha. When the cost of water is 52 rubles. per 1 thousand m ³ , the savings is 52 rubles. per hectare.

In addition, it is possible to reduce the construction cost of the rice system by using pipes and making channels of smaller diameter.

Claims (1)

The drawing schematically shows a rice irrigation system. Rice irrigation system includes precinct distribution channel 1, kart irrigation canal 2, precinct waste canal 3, kart drainage canals 4, rollers 5, checks 6, 7, 8, 9, check inlets 10 at the head of the irrigation canal 2, check inlets 11 in the end of the map irrigation canal 2, maps 12, discharge structures 13, additional check water outlets 14 in the head of the map irrigation canal 2 and intercheck water outlets 15. The system works as follows. During the first and subsequent floods from precinct distribution channels 1, water is supplied to kart irrigation canals 2, from where through outlets 14 (in their head) to adjacent first checks 8, 9. Additional outlets 14 are calculated on the maximum flow rate required for flooding two checks, therefore, the period of flooding of checks 8 and 9c is two times less than usual (approximately 1.5 days). During this period, the main water outlets 10 and 11 are closed. After accumulating on the checks 8 and 9 the volume of water necessary for flooding, the check outlets 14 are closed, after which the water from the checks 8 and 9 is passed through the outlets 15 to the checks 6 and 7 adjacent to them. After the time required for agrotechnical treatment, water from checks 6 and 7 is discharged through facilities 13 directly into precinct discharge channel 3. It should be noted that check outlets 14 and intercheck outlets 15 work no more than 9 days a year out of a total of 105 days of irrigation period. This leads to more simplified requirements for their execution, i.e., they may be non-automated. To maintain some specified water layer in the checks during the rice growing season, i.e., to replenish the loss of the check-filled water that occurs due to transpiration of plants, surface evaporation of the water mirror and filtration, check water outlets 10i and I, which can be made without manual, are used. Kart irrigation canal 2, therefore, can only be calculated for the replenishment of water loss in two checks 6 and 7. This is usually 1.5-2.5 g / s-ha. These costs are very stable and the efficiency of channel 2 is high. The low flow rates of channel 2 allow it to be carried out in a pipe or in a tray. For example, for checks of 6 hectares, sprinkler 2 may have a pipe diameter of 50 cm. Check outlet lugs 10 and I work most of the irrigation period and can be automated. The consumption of these facilities is 5-7 times less than that of the known systems, which greatly simplifies the automation of the system. Drainage channels 4 with this network design work only for the removal of filtration water with a specific flow rate of 0.4-0.7 l / s-ha. Since they are not loaded with waste water, the stability of their walls increases significantly. Taking into account the described operation of the system, it is advisable to carry out the discharge and discharge structures, keeping a certain ratio between their estimated costs. If we take the estimated flow rate or throughput of the main check structures 10, and beyond Q, then the capacity of the additional check outlets 14 must be kept within 15-18Q, and the overflow inter-checker outlets 15 within 5-9 Q and the check waste facilities 13 within 2-3 Q. The main technical and economic advantage of this system is the saving of irrigation water when filling in checks of about 1000. When the cost of water is 52 rubles. per 1 thousand m, saving is 52 rubles. per hectare. In addition, it is possible to reduce the construction cost of the rice system by using pipes and making channels of smaller diameter. The invention of the rice irrigation system includes precinct distribution and discharge channels, maps, checks located in two parallel rows between the divisional distribution and discharge channels, a network of kart irrigation and drainage canals, check inlets and discharge structures one for each adjacent to the map irrigation canal and each check adjacent to it, characterized in that, in order to reduce losses, increase the efficiency of map irrigation canals and increase stability STI slopes Cartesian drainage channels, each adjacent to a Cartesian orosielnomu channel is provided with a check additional checks of the Cartesian rositelnogo overflow channel in the check, and each contiguous with it the check provided mezhchekoym overflow, wherein the safety waste soouzheni checks installed adjacent to eposredstvenno divisional drainage canals. / J / f : i // four / / f / : /