RU2193838C2 - Method and apparatus for application of chemicals with irrigation water used in impulse sprinkling systems - Google Patents

Abstract

FIELD: agriculture. SUBSTANCE: method involves cycles of accumulation of irrigation water in vessel under excessive pressure and preparing portion of chemical solutions combined with charging of spring-air type accumulator. Accumulator is adapted for dosing of rated volume of solution into water flow under pressure during irrigation cycle. Fertilizer solution dosing device is made in the form of spring-air type accumulator having hollow plunger with working volume regulating rod and hydraulically communicated with solution accumulating tank. Pipeline for connecting said tank to irrigation system headset has internal volume correlated with accumulator effective volume within the range of 0.5-0.9. Method and apparatus are used for application of mineral fertilizers, microelements, chemical ameliorants, herbicides and other pesticides with irrigation water. EFFECT: increased efficiency, provision for low-intensity dosing of chemicals into irrigation water flow without using additional energy sources and elimination of used water discharge process. 3 cl, 1 dwg

Description

 The invention relates to the mechanization of agriculture and can be used for making mineral fertilizers, trace elements, chemical reclamants, herbicides and other pesticides with irrigation water. It is recommended for use on modular pulsating irrigation systems, mainly pulsed micro-sprinkling. The device and method can be used in other areas of the economy with similar tasks and identical modes of operation of the main equipment.

 Widely known are the methods of applying mineral fertilizers and other agrochemicals with irrigation water, which consist in the sequential preparation of their uterine formulations, dosing the required amount into the irrigation water stream, mixing with it and distributing over the irrigated area [1].

 A disadvantage of the known methods as applied to pulsed sprinkling systems is that they mainly require external energy sources (electrical, mechanical, pneumatic) or use high-energy hydraulic structures, do not take into account the features of discrete irrigation modes, practically cannot be realized with low-intensity application of agrochemicals, constant monitoring is required for the operation of the equipment and the presence of highly qualified staff is required.

 There is a method of feeding plants with solutions of mineral fertilizers during sprinkling, which includes the selection of part of the water flow from the irrigation pipeline and directing it into a container with chemicals that enrich the water due to the pressure differential created in the pipeline and are dosed into it [2, 3].

 A disadvantage of the known method of introducing agrochemicals with irrigation water is that its application extends to pressure irrigation pipelines with high transit costs, provides for mandatory drops and pressure losses in the main pipeline, the difficulty of controlling the amount of fertilizer applied in time, the process is implemented in a relatively short period of time and low-intensity nutrient intake is not ensured.

 A device for applying liquid fertilizers with irrigation water, including a liquid fertilizer tank installed on the pressure pipe, a metering pump kinematically connected to the rods of the pressure and return hydraulic cylinders and hydraulically to the root cavities of the aforementioned hydraulic cylinders, a distributor and a throttle [4].

The disadvantage of this hydraulic feeder is its high material and energy consumption, as well as significant flow-pressure characteristics, which makes it practically unacceptable in conditions of pulsed micro-sprinkler systems. So, the hydraulic feeder for DM “Fregat”, which is sold by production under this copyright certificate, operates in the pressure range of 0.47 ... 0.75 MPa and flow rates of 60 ... 450 dm ³ / h, while for the considered irrigation conditions the required pressure does not exceed 0 , 2 ... 0.25 MPa. Moreover, the flow rate of irrigation water in the supply pipe is 0.05. ..0.25 dm ³ / s, and the required flow rate of the metering pump during the operational application of fertilizers is estimated at 0.003 ... 1.0 dm ³ / h. For conditions of low-intensity distribution, this indicator of technical characteristics decreases by 50 ... 70 times. It follows that, technically, solving the problem along the path in question is extremely problematic. At the same time, the selected water for the hydraulic drive of the metering pump is disposed of in the enclosed area, which is accompanied by additional material and operating costs.

 Closest to the invention under consideration in a technical network is a hydraulic feeder selected as a prototype for pulse sprinkler systems, containing a container for liquid fertilizers, a pressure pulse generator mounted on the main pipeline, and a metering pump [5].

 A disadvantage of the known device and the method it implements is that they do not solve the problem of reliable dosing of the mother liquors with very limited flow parameters and in a low-intensity mode. In addition, there is an expensive and technically sophisticated special pressure pulse generator that determines the reliability and availability of the device. At the same time, increased demands are made on the physical properties of the mother liquors, the complexity of the design of the metering pump and its high material consumption relative to the irrigated area by the sprinkler installation, the presence of moving piston pairs in a corrosive medium with the presence of abrasive inclusions are noted.

 The problem to which the invention is directed is to ensure the reliability of low-intensity dosing of agrochemicals in the irrigation flow without involving additional energy sources and eliminating the discharge of waste water.

 The essence of the invention lies in the fact that in the method of introducing chemicals with irrigation water on pulsed sprinkler systems, the cycles of accumulation of irrigation water in containers under overpressure and the preparation of a portion of the solutions of chemicals for chemization are combined with charging a spring-air accumulator, which ensures dosing of the estimated volume of solution during the irrigation cycle into a stream of water under pressure.

 The problem is solved so that in the device for introducing chemicals with irrigation water on pulsed sprinkler systems, the fertilizer dispenser is made in the form of an autonomous spring-air accumulator equipped with a hollow plunger with a rod for adjusting its working volume and hydraulically connected to the solution storage tank connected to the head unit irrigation system through a pipeline, the internal volume of which relates to the useful volume of the battery in the range of 0.5 ... 0.9.

 A device for introducing chemicals with irrigation water on pulsed sprinkler systems includes a dispenser of agrochemical solutions that works without discharging waste water and predetermines its reliable functioning as a whole. It is made in the form of a spring-air accumulator autonomously located on a solution storage tank, equipped with a hollow plunger with a rod moving along the axis. The rod provides adjustment of the working volume of the battery, which, accordingly, is dosed for the irrigation cycle. The inner cavity of the plunger is equipped with a spring with a separation membrane, which provides air accumulation under excessive pressure. The battery is hydraulically connected to the storage tank. At the same time, the solution storage tank is connected to the head unit of the irrigation system through a pipeline valve. Moreover, the ratio of the internal volume of the connecting pipeline to the useful volume of the battery is in the range of 0.5 ... 0.9.

 Filling the tank with fertilizers or other agrochemicals is carried out with a tap on the pipeline connecting it to the head unit of the irrigation system. For refueling, both liquid fertilizers and highly soluble dry fertilizers are used. After refueling and sealing the tank with a special cover, the shut-off valve is opened. Water in the cycle of accumulation of the head unit from it enters the solution storage tank in transit, mixes with fertilizers and the resulting solution provides battery charging. Charging the battery is realized by filling the working cavity with the resulting solution of chemicals, the accumulation of kinetic energy by compressing the spring and air, balancing the pressure in the battery and the head of the irrigation system. As a result of the operation of a standard command pulse generator or a working body replacing it, providing direct watering, the battery is simultaneously rarefied with the head unit. This provides a dosed flow of agrochemical solutions into it. In the head unit, the solutions are mixed with irrigation water and from it are distributed over the irrigated area through the appropriate sprinklers. The volume of dosing solution per irrigation cycle is determined by the battery setting. The transition of all nutrients to irrigation water depends on the battery setting, the duration of the irrigation system and the irrigation rate, the concentration of the mother liquor, the length of the connecting pipe and its diameter.

 A method and apparatus for introducing chemicals with irrigation water on pulsed sprinkling systems are presented in the drawing.

 A device for introducing chemicals with irrigation water on pulsed sprinkler systems includes a fertilizer 1 dispenser in the form of an accumulator and a storage tank 2.

 Mortar storage tank 2 contains a shell 3, a drain valve 4, a neck with a cover 6, a flange connector 7 and a connecting pipe 8 with a valve 9. The mouth 5 serves to load the device with tuks, and the valve 4 serves to drain the water and remove slurry inclusions. The cover 6 provides its sealing during normal operation. A pipeline 8 through a valve 9 connects the device to the head unit 10 of an irrigation system represented by irrigation pipelines 11 and 12 with sprinklers located on them. The dispenser of fertilizer solutions 1 is mounted independently on the flange connector 7. It is made of a housing 13, a hollow plunger 14 with sealing cuffs 15 and a rod 16 with a central hole. The rod 16 is equipped with a nipple 17 and a pressure gauge 18, providing air pumping and control of its pressure. A spring 19 is placed inside the plunger 14, and a diaphragm 20 with a casing 21 is placed on its end. Attention is drawn to the fact that in the practical implementation of the device design according to the proposed scheme, the diaphragm can be replaced by a bellows. The diaphragm 20 and the sealing cuffs 15 divide the entire structural volume of the housing 13 into a "working" 22 and a "static" cavity 23. Working cavity 22 with its useful volume provides the accumulation and subsequent dosing of a portion of agrochemical solutions in the process of regular technological irrigation cycles. The volume of this cavity is not constant, during the operation of the device, it constantly varies due to volumetric movements of the diaphragm under the action of constantly changing water pressures in the head unit 10, as well as the state of the air and spring 19. The static cavity 23 ensures the placement of the plunger 14 with its accessories and a certain technological reserve, taking into account the adjustment of the volume of the working cavity within the technical characteristics of the dispenser. The adjustment is carried out by axial movement of the rod 16. The water supply to the head unit 10 is provided through the supply pipe 24 through the shut-off and control valve 25.

 In the process of the regular operation of the head unit 10 through the pipeline 8, a phased supply of water to the device and removal of the agrochemical solution from it is carried out. Attention is drawn to the fact that the ratio of the internal volume of the connecting pipe 8 to the metering volume of the solution of chemical means dosed by the battery is 0.5 ... 0.9. At the same time, it should be borne in mind that the combined use of the energies of a rechargeable spring 19 and compressed air in the internal cavity of the plunger 14 simplifies the design of the dispenser and the device it is equipped with, reduces its dimensions and metal consumption, ensures the visibility of the process control and increases the operational reliability of the device.

 The method of introducing chemicals with irrigation water on pulsed sprinkling systems and a device for these purposes are implemented as follows.

 The fundamental capabilities of the device allow its use in the application of both mother liquors of agrochemicals and dry fertilizers that are well soluble in water. In any of the options, the beginning of the process under consideration is accompanied by the filling of the solution storage tank 2 with the mother liquor or the corresponding fertilizers. For these purposes, a series of operations are performed sequentially: they turn off the tap 9 on the pipe 8, open the cover 6 and tap 4, providing drainage of water from the shell 3. If necessary, flush and remove 2 possible slurry inclusions from the tank 4. Subsequently, the valve 4 is closed and the tank 2 is refueled by means of chemicalization. With regard to dry fat, their value is within 2/3 ... 3/4 of the volume of the shell 3, and the liquid components are deposited in the required amount on the irrigation area or taking into account the maximum possible volume of the tank 2. In parallel with these works, the axial movement of the rod 16 and its plunger 14 with cuffs 15 control the volume of the working cavity 22 by changing the volume of the static cavity 23 and set the amount of the supplied solution per dosing cycle. After this, by manipulating the crane 9, the tank 2 is filled with water by 90 ... 95% of its volume, and by closing the lid 6, it is sealed and the device is ready for operation. Next, open the tap 9, thereby ensuring the flow of irrigation water from the head unit 10 into the device and the implementation of the method of introducing chemicals with irrigation water.

 When the tap 25 is open and water enters through the supply pipe 24, it fills the head unit 10 in the regular “filling” cycle and implements its charging to the value of the preset pressure. Simultaneously with the charging of the head unit 10, water flows through a pipe 8 into a solution storage tank 2, where it is mixed with solutions of the agrochemicals therein, and the resulting mixture enters the working cavity 22 of housing 13 or dispenser 1. The incoming mixture fills the free volume, increases the pressure in the cavity to magnitude in the head unit 10 and moves the diaphragm 20 within its casing 21.

 The volumetric movement of the diaphragm 20 provides compression of the spring 19 and located under the diaphragm 20 in the inner cavity of the rod 14 of the air. Thus, the battery 1 is charged by the volume of the dosed solution of chemicals for the subsequent irrigation cycle under the pressure of the head unit 10. After the head unit 10 is activated and the pressure drops in it, the volume of the agrochemical solution accumulated in the working cavity 22 under the action of the kinematic energy of the spring 19 and compressed air through the tank and pipeline 8 are dosed into the head unit 10. As a result of the ongoing actions, two liquids are mixed and the so-called working solution of chemical means is formed, which minutes enters the conduits 11 and 12 with the corresponding sprinkler and subsequently distributed over the area irrigated. It should be borne in mind that the volume of fertilizer solution delivered to the head unit will be equal to the "useful" volume of accumulated solution in the battery minus the internal volume of the connecting pipe. As a result of laboratory and analytical studies on a prototype device, it was found that with a dosing accuracy of + 8%, the ratio of the inner diameter of the connecting pipe to the last volume of the battery should not exceed the interval of 0.5. ..0.9.

 After the end of the direct watering cycle, the cycle of filling the head unit 10 with water and filling the battery 1 with the next portion of agrochemicals, followed by its discharge, depending on the operation of the irrigation equipment, resumes, that is, the process continues in an automated mode. Visual monitoring of the operation of the dispenser is carried out according to the readings of the pressure gauge 18. If necessary, recharge the battery with compressed air is realized through the nipple 1.

 The duration of the device for the complete removal of agrochemical substances from tank 2 and their transition to irrigation water is determined by its setting and operating mode of irrigation equipment. It is determined by calculation and accumulated experience in operating equipment. At the end of this time, by shutting off the tap 9, the device is turned off. Open the lid 6 and the drain valve 4. Subsequently, all the operations related to the preparation of the device for operation are repeated and subsequently included in the operation.

 Using the proposed method and device for its implementation allows you to coordinate the operating mode of the pulsed sprinkler system with the tasks of low-intensity and dispersed fertilizer application, control the dosage of other chemicals to the irrigation flow, improve the distribution of agrochemicals over the area, maintain the reliability and performance of the irrigation system, and do not affect their technical and operational characteristics.

Sources of information
1. Abramov A.F., Ivashkin V.I. The introduction of chemicals with irrigation water. - M.: Rosagropromizdat, 1988, 88 p.

 2. Soloviev E.E. Plant nutrition during sprinkling. // Collective farm production, 1959, 12, p. 32.

 3. Copyright certificate of the USSR 82032, cl. A 01 C 45 23/04.

 4. Copyright certificate of the USSR 594915, cl. A 01 C 23/04, 1975.

 5. Copyright certificate of the USSR 1119211, cl. A 01 C 23/04, 1985.

Claims (2)

 1. The method of introducing chemicals with irrigation water on pulsed sprinkling systems, including cycles of accumulation of irrigation water in containers under overpressure, enriching the accumulated irrigation water with chemicals, distributing the resulting mixture over the irrigated area and preparing a portion of the solutions of chemicals for chemical treatment, characterized in that the cycles the accumulation of irrigation water in the tank under excess pressure and the preparation of a portion of the solutions of chemical means are combined with charging a spring-air accumulator, which provides dosing the calculated volume of the solution during the irrigation cycle into the flow of irrigation water under pressure.  2. A device for introducing chemicals with irrigation water on pulsed sprinkler systems, containing a pressure head irrigation network with a head unit providing discrete irrigation mode, a solution storage tank for fertilizers, a fertilizer solution dispenser, connecting and pipe fittings, characterized in that the fertilizer solution dispenser made in the form of an autonomous spring-air accumulator equipped with a hollow plunger with a rod for adjusting its working volume and hydraulically connected to the solution accumulation tank connected to the head node of the irrigation system by means of a pipeline, the internal volume of which refers to the useful volume of the battery within 0.5. . . 0.9.