SU1757533A1 - Irrigation stop signalling device - Google Patents

Abstract

Use: agriculture in the field of irrigation, in particular as a means for soil moisture measurement, and can be used to control the depth of soil moisture, including for water accounting purposes. SUMMARY OF THE INVENTION: The detector includes a measuring hollow probe 1 with a scale embedded in the soil, the upper protruding end of which is provided with guiding elements for a flexible rod connecting the permeable bag 7 placed in the cavity of the measuring probe 1 on the surface of the water wick 9 filled with a water-soluble material 8, with a signal element 4 located on the hinged rod 3 hinged on the outer wall of the probe 1. Before using the detector, the outer surface KSR Control probe 1 promazyvayut plastic hydrophobic lubricant 10 and R is set previously drilled to a predetermined depth beneath diameter alerter well. In the course of irrigation, irrigation water seeps through the underlying bottom of the well and the capillary movement of the water wick 9 dissolves the water-soluble material 8 in the permeable bag 7. As a result, the weight of the bag 7 becomes less than the tension of the flexible pulling rod 6, which leads to the overturning of the signal element 4 and is a signal for the operator to stop irrigation, i Il. t w fe

Description

The invention relates to agriculture, to the field of irrigation, in particular, to soil moisture metering in agriculture and can be used to control the depth of soil moisture, including for water accounting.

The aim of the invention is to simplify the design and improve the operational characteristics of the alarm.

The drawing shows a General view of the alarm termination of irrigation. The irrigation stop indicator includes a measuring probe 1 with a scale for immersing the detector in the soil, while the outer part of the probe 1 wall is connected via a hinge 2 to a rotary rod 3, at the end of which there is a signal element 4, made, for example, in the form of a flat, painted red color of a circle made of alYUMinyevbgo sheet, thick waterproof cardboard, plastic, etc. The material for the manufacture of the measuring probe 1 can be metal or plastic pipes, and the rotary rod 3 can be made of rolled wire with a diameter of, for example, 2.5 ... 4 mm. The upper part of the cavity of the measuring probe 1 is equipped with a guiding element fixed on the side surface and protruding into the cavity of the probe 1, on the working surface of which a channel 5 is made with a flexible rod 6 thrown over it, for example, a nylon thread, to the lower end of which a permeable housing 7 is made, made , for example, in the form of a bag and filled with water-soluble material 8, for example, ammonium nitrate, instant sugar, etc. The material for the manufacture of a permeable housing 7 can serve, for example, a mesh-free mesh mesh for reclamation purposes (TU 33-322-86). The specified mesh is used as a packing filter membrane of bulk filter material used to assemble filter columns in a drainage trench. You can also use a nylon sieve (TU 62-11086-80), a polyamide sieve (TU 62-10619-83), a polypropylene frame fabric TU (ESSR) 503-83, a filter polypropylene fabric TU-17 of the Ukrainian SSR 43-20-87, etc. A waterproof housing 7 is mounted on the surface of insoluble TO in water of a porous water-conducting wick 9, which can be used, for example. canvas stitching for land reclamation (Art. 931543 TU UzSSR 14301-87). The water-conducting ability of the canvas is due to its well-defined porosity. As a result of this, according to the experiments of TurkmenNIIIGiM, when it is used, the speed of movement in it, moisture after immersion in water is within the first five minutes, then cm, during the second five minutes 7 cm. In just 10 minutes, the water in the canvas is moved 17 cm from places of immersion in water. The composition of the canvas; viscose fiber - 40%, polyester fiber -57%, production reversal - 3%, piercing thread nylon linear density 15.6 ... 29 tex. Price (wholesale) for 1 m with a canvas width of 1.76 m - 1, 26 rubles. Another option water-conducting wick 9 may be sandy soil in a kapron shell in an air-dry state. Moreover, the height of the layer of water-conducting wick 9 in the measuring probe 1 is at or above the soil layer in which the moisture reserves are insufficient for premature dissolution of the material 8. If, however, the moisture reserves along the entire profile of the soil intended for irrigation are insufficient for premature dissolution of the water-soluble material 8 (such a picture can take place, for example, with a deep, more than 5 m, occurrence of groundwater), then the device does not have to be equipped with a water-fusing wick 9. In this case, the permeable body 7 will children lie directly on the soil surface in the end of the probe 1. The upper end of the nylon thread 6 is fixed to the hook of the signal element 4.

The weight of the water-soluble material 8 in the water-permeable housing 7 should exceed the tensile force of the flexible rod 6 at the angle of inclination (o.s.) of the rotary rod 3 to the outer wall of the probe 1 is greater than 90 °, but less than 180 °. i.e. 180 °> > 90 °. This means that in all cases when applying to the rotary rod 3 a force exceeding the tension force of the flexible rod 6 with its translation into any other new position described by the above dependence, after removing the force, the rotary rod 3 should return to its original position, determined by the length of the nylon thread . In this case, the length of the flexible rod 6 should be such that in the tensioned position to provide the specified limits of the angle of inclination of the rotary rod 3 to the outer wall of the probe 1. Here, however, it should be noted that with the position of technical efficiency it is desirable that the length of the flexible rod provides an angle of inclination of the rotary rods 3 to the outer wall of the probe 1 close to 180 ° (the second quadrant relative to the probe 1), for example, equal to 150 ... 170 °. This allows

1757533 6 to be located at the signal element 4 close to the maximum height, which, due to its elevation above the surface of the soil and plants, provides good observability for the operator and creates certain convenience in work.

In addition, in order to reduce the influence of wind on the position of the rotary rod 3 and prevent its possible displacement, the signal element 4 is mounted on 10 rod 3 in the same secant plane with a curved channel 5 on the guide element and flexible rod 6.

The size of the irrigation stop signaling device is determined by the specified soil wetting depth 15 and can be, for example, up to 2 meters long (including the length of the signal element 4) with an inner diameter of the probe 1 equal to, for example, 2 ... 3 cm. 20

The irrigation stop signaling device is prepared for operation as follows: in the control area of the field to be irrigated, a well is drilled to the required depth, for example, by 0.5 m, 25 meters in diameter equal to the diameter of the probe 1, plastic hydrophobic grease 10 is applied to the outer surface of the probe 1, for example, technical petroleum jelly. Then, by lightly tapping the wooden hammer 30 on the upper end surface of the probe 1, the pre-calibrated stop watering indicator is installed in the drilled well. Charging the device with a water-insoluble porous water-conductive wick 9 can be carried out both before installing it in the well, and then by introducing it into the cavity of the probe 1. In this case, the condition of mandatory contact of the wick 9 with the soil must be observed, the bottom of the well. After that c. the measuring probe 1 is inserted into a water-permeable housing 7 suspended on a flexible rod 6 with a water-soluble material 8 placed therein and resting it in a water wick 9. Next, the rod 6 is passed through a curved channel 5 in the guide element and tied to the hook of the signal element 4 with a free end , observing 50 in this case, according to which the angle of inclination of the rotary rod 3 to the outer wall of the measuring probe 1 in the tensioned position of the rod 6 should be more than 90 °, but less than 180 ° and 55 should be within 150 ... 170 °. In addition, the signal element 4 should be placed end to the direction of the wind, so that its painted lateral plane is parallel to the direction of the air wind flow. The signaling device is ready to work, you can start watering.

Signaling cessation of watering works as follows. In the process of irrigation, for example, by sprinkling (the intensity of the rain is equal to the intensity of moisture absorption into the soil), the irrigation water seeping reaches the soil underlying the bottom of the well. The presence of a hydrophobic grease 10 on the outer surface of the probe 1 prevents water from flowing into the zone of contact of the soil with the walls of the probe 1, thereby preventing any signaling. Water, having reached the soil underlying the bottom of the well, under the influence of static pressure and water-lifting properties of the porous water-conducting wick 9 moves in the cavity of the measuring probe 1 to the water-permeable body 7 in contact with the water-soluble material 8. In the process of moisture interacting with the water-soluble material 8, dissolution occurs the latter with the transition from solid to liquid, which leads to a rapid decrease in the weight of the housing 7. As a result, at a certain stage, the tension force of the flexible rod 6 mill vitsya large weight body 7, which leads to a tipping pivot rod 3 signaling element 4 and is a signal to the operator to cease irrigation. This position of the pivot rod 3 with the signal element 4 is shown by a dashed line,

The depth of penetration of the probe 1 into the soil depends on the nature of soil moisture. When drip irrigation or irrigation by sprinkling (the intensity of the rain is equal to the intensity of absorption of moisture into the soil) probe 1 is buried to the required depth of soil moisture. When watering on furrows, stripes; by flooding, the depth of penetration should be 8 ... 30% less than required. This is explained below. When irrigation with furrows, the permissible depth of water in the furrow (N) is determined by the formula:

Η = 0.6Η-2Δ where N is the depth of the furrow from the ridge to the bottom, cm: '’'

Δ is the accuracy of the layout of the field surface, see

Furrow depth is within

19 ... 25 cm, and the accuracy of the Planning is ± 3 ... 5 cm. From here, the depth of the water in the furrow is within 2 ... 3 cm. If you take a dose on the soil moistening, applying the received data in the form of a scale on the outer surface devices

In addition to monitoring the depth of soil moisture, the indicator can also be used for water accounting. In particular, knowing the initial humidity and depth of the soil layer soaked in moisture, it is easy to determine the amount of water supplied to the field using the formula:

If the average soil composition is 45% on average, then the total moisture capacity of 1 ha of the meter field layer, taking into account 10% of trapped air, will be 4050 m ³ / ha. Of this amount of moisture, approximately 70% (2835 m ³ ) is accounted for by the moisture contained in the soil at its lowest (maximum field) moisture capacity. Since the next irrigation period is recommended to start on average with a soil moisture deficit of 65 ... 70% of the lowest moisture capacity, the initial moisture reserves in the soil before irrigation are on average

1845 .. .1986 m ³ / ha, and the necessary irrigation rate for humidification to the lowest moisture capacity of 1 ha of field to a depth of 1 m will be

860 .. .990 m ³ / ha. With a row spacing of the soil corresponding to the smallest moisture of 60. .90 cm, approximately 25 ... 30 cm is capacity;

on a mirror of water in a furrow. Therefore, with a water depth in the furrow equal to 2 ... 9 cm 20 soil moisture, for the entire area of 1 hectare of the field, the calculated layer of water ^_ will be 0.83 ... 3.0 cm (2 x 2.5): 60 and ( 9x x 30): 90, which corresponds to 83 ... 300 m ³ / ha.

wetting the soil layer to a depth of 10 ... 33 25 cm (83x100): 860 and (300x100): 900, and taking into account / seeping moisture. In addition, the optimum water loss for evaporation (10 ... 20%) per tea of water per field in the optimum soil conditions for the growth of plants contributes to an increase in crop yield.

The advantage of the proposed signaling termination of irrigation is also ease of operation, ease of manufacture and reliability.

Claims (1)

The claims of the Watering cessation switch, including a measuring probe equipped with a scale For vertical placement where M is the amount of water supplied to the field, m ³ / ha: HB - the amount of water in a given capacity layer; 0.6 (0.7) - pre-irrigation coefficient The use of an irrigation stop signaling device allows the economical use of irrigation water, eliminates its over-consumption, as well as the loss of soil nutrients to deep filtration The indicated amount of moisture is sufficient for cm (83 x 100): 860 and (300 x 100): 900, and taking into account '. . ::. depth 8 (9) ... 27 (30) cm, which is 8 ... 30% of the required depth of soil wetting. : It was previously indicated that before using the device, it is advisable to calibrate it. The essence of the tarrybvky is to determine the actual depth of wetting the soil of one or another! the mechanical composition after the actuation of the signal element 4 at various installation depths of the measuring probe 1. in the soil. Determination of the soil wetting depth can be carried out by means of a predetermined depth in the soil by sampling soil samples from various depths of the soil profile and analyzing their moisture, for example, by thermostatic-weighting method. The depth of soil wetting can be determined 45 also by neutron moisture meters, by tensometric or otherwise. Suppose that probe 1 was buried by 0.4, 0.5, and 0.6 m. The actual depth of soil wetting (or the depth of the soil in which moisture is equal to or very close to the lowest (maximum field) moisture capacity) was 0, respectively , 45, 0.57 and 0.7 m. Therefore, if the specified depth of soil wetting is, for example, 0.7 m, then the probe should be deepened by 0.6 m. After mathematical interpolation, you can determine the required depth of penetration of the signaling device, at which the required depth of improvement will be achieved 30th regime of the soil, which contributes to the higher 35 made in the form of a hollow tube, inside which there is a moisture-sensitive element and a conductive wick for contacting the soil at the cut level of the lower end of the tube, a guide element installed in the upper end of the tube, and a signal element, characterized in that , in order to simplify the design and improve the operational characteristics of the stick of the detector, the moisture-sensitive element is made in the form of a moisture-permeable body filled with water-soluble material, and is installed with the possibility of contacting from the initial position with the upper surface of the watertight wick, and the signal element is placed on a rotary rod, which is pivotally mounted on the outer wall of the hollow tube with the possibility of being located in the initial position in the second quadrant 9 1757533 10 of the latter, while the moisture-sensitive element is connected to the signal element by means of a flexible rod passing through the curved groove facing the inside of the hollow tube, which is made on the working surface of the guide element, which protrudes into the cavity of the hollow tube, the signal element being made flat and located in one plane with a flexible rod and a curved groove on the working surface of the guide element.