SU1687125A1 - Device for automatic irrigation control - Google Patents

Abstract

The invention relates to agriculture and can be used in irrigated agriculture for the automation of discrete irrigation of agricultural crops. The purpose of the invention is to provide an automatic feed to the field of specified volumes of irrigated water irrigation rates. A device for automatic control of the irrigation regime, comprising a relative evaporation sensor 5. adjustable capacity 24. transfer valve 3 with a switch 4. setting device 7 of irrigation norms with a software board 10. measuring tank 6 with two siphons 22 and 23. built-in in it, hydraulically connected respectively to sensor 5 and capacity 24. After evaporation of water from sensor 5 the valve 30 is opened, water is drained from the tank 24, due to the counterweight 26, the switch 4 turns the valve 3 and opens the pipeline 2 to irrigate and fill the measuring tank, the drain hole 17 of which is adjusted for a certain time to fill the tank 6. After - The tank 6 includes two siphons 22 and 23. which fill the sensor 5. at the same time the valve 30 is closed and the tank 24 is filled. By pressing the lever 25, the valve 3 closes the valve 3 and turns off the water, the valve 3 opens after the water evaporates in the sensor 5 and the watering process is repeated. 1 il. u fe

Description

The invention relates to agriculture and can be used in irrigated agriculture to provide automatic discrete irrigation of crops.

The purpose of the invention is the provision of automatic supply to the field of specified volumes of irrigation norms of irrigation water.

The drawing shows a control device, General view,

The device for automatic control of the irrigation regime contains the main and irrigation pipelines I and 2, a transfer valve 3 with a switch 4 installed between them, a relative evaporation sensor 5, a measuring tank 6 and a watering rate adjuster 7, which includes a scale 8 of watering rates, a float travel limiter 9 on the circuit board 10. lever switch 11 positions of the setter 7 of the irrigation norms interacting with the protrusions of the rack 12 of the circuit board 10, equipped with a latch 13.

Measuring tank 6 with the help of nozzles 14 and 15 and a flexible sleeve 16 is connected to the irrigation pipe 2. In addition, the tank 6 has an adjustable drain hole 17 and support shelves 18 for the float 19, which is equipped with a rod 20 with a protrusion 21. interacting with the switch 11 of the board 10 setter 7 irrigation norms. Two siphons 22 and 23 are mounted in the bottom and cavity of the float T9, which are removed from the tank 6 using flexible parts and hydraulically connected respectively to the relative evaporation rate sensor 5 and the equilibrium tank 24 mounted on the beam 25 switch 4 of the valve 3. The beam 25 is equipped with a ballast 26 and mounted on a support 27. Using a flexible sleeve 28, the equilibrium tank 24 is connected to a drain pipe 29 having a valve 30 controlled by the weight of the relative evaporation sensor 5 mounted on the elastic element 31.

The device operates as follows.

Before the first watering, the sensor 5 is filled with water. When evaporating a given volume of water from the sensor 5, which corresponds to the achievement of soil moisture in the field of pre-irrigation value, using the elastic element 31, the valve 30 of the drain pipe 29 opens. In this case, water flows out of the balance tank 24 through the drain pipe 29. In this case, the ballast 26 is lowered and the switch 4 of the transfer valve 3 opens the pipe 2 for irrigation. Water simultaneously enters the field and into the measuring tank 6 through a flexible hose 16 and patrol side 14. According to the difference in the flow rate of water flowing through the tube 14 to the regulating tank 6 and flowing out of it through the adjustable hole 17, the correspondence of the duration of watering is established at its bottom filling the control tank 6 to the top of the elbow of the siphon 23, which is mounted in the cavity of the float 19. pops up as the control tank 6 is filled. On the upper part of the float 19, the rod 20 is vertically mounted, the upper end of which limits the stroke float 19, abutting against one of the limiters 9. installed on the software board 10 setter 7 irrigation norms.

After the float emerges and is fixed in its upper position by the rod 20, water continues to flow through the tube 14 to the regulating tank 6 and, having reached the upper elbow of the siphon 22, it enters the relative evaporation sensor 5 through a flexible sleeve, filling it. The sensor under the influence of the gravity of the water drops and closes the valve 30 of the drain pipe 29. At the same time, water through a siphon 23 and a flexible hose enters the tank 24 equilibrium, filling it. The tank 24 pulls the ballast 28 and, using the drive valve switch 4, closes the hydrant valve 3, shutting off the water supply to the field and to the volumetric tank 6. After the evaporation of water from the sensor 5, the process is repeated.

In accordance with climatic conditions, the characteristics of soil conditions and cultivated crops on · board 10 in accordance with scale 8, the norm of each irrigation is established during the growing season with the help of stops 9 fixed at different levels in accordance with the scale. In particular, the drawing shows 8 irrigations for the entire growing season. The scale is calibrated in accordance with the diameter of the nozzle 14, the cross section of the drain hole 17 and the pressure in the irrigation pipe 2 and its flow rate.

Thus, the numbers shown on the scale of the board 10 correspond to the irrigation rate per 1 ha.

At the beginning of the growing season, the board 10 is set so that the emphasis of the first irrigation is on the axis of the stem 20. When the latter moves upward at the time of irrigation, the time of its movement to the abutment 9 corresponds to the required amount of water supplied to the field in accordance with a scale of 8 through pipe 2. . When the stem moves downward, the protrusion 21 of the rod transfers the board 10 by means of the switch 11 and the protrusions of the rack 12 to the position corresponding to the irrigation rate of the second watering (second position.

circuit boards). The latch 13 locks the board in the second position. After practicing the second watering process is repeated.

Claims (1)

Claim A device for automatic control of the irrigation regime, including a shut-off element mounted on the irrigation pipe, interacting with the beam, one arm of which is connected to the counterweights, and the other with an adjustable tank hydraulically connected to the relative humidity sensor and with a measuring tank with an irrigation rate regulator and adjustable drain at the bottom of the tank, characterized in that. what. in order to ensure automatic supply to the field of specified volumes of irrigation water irrigation norms, the float is equipped with a rod rigidly mounted on the axis of the tank with a stop and two siphons installed inside it, one of which is hydraulically connected to the relative humidity sensor, and the second - with an adjustable capacity, in this case, the measuring tank in the upper part is equipped with a lever switch interacting with the rod stop and longitudinal guides in which the irrigation rate adjuster is movably mounted, made in the form of a movable LTL provided with a rack with projections which interact with the lever switch, and mounted with a certain pitch in a longitudinal direction of the card 15 travel stops of the float, interact with the upper end of its stem, the relative humidity sensor fluidly connected to an adjustable capacitance.