SU1161020A1 - Irrigation system - Google Patents

Abstract

1. THE IRRIGATING SYSTEM, containing pump units with blocks, controls associated with pressure sensors, distribution piping and irrigation channels with water supply controls at the inputs, including shut-off organs and float level sensors, characterized in that increase reliability and reduce operating costs by coordinating the transient operation of pumping units and water supply controllers when changing water consumption in the system; all water supply controllers are equipped with max. The minimum flow rate and the threshold element for starting the opening of the valve are hydraulically connected with the distribution pipeline and installed between the level sensor float and the valve. 2. The system according to claim 1, characterized in that the connection between the float of the level sensor and the locking member is made in the form of a lever transmission, the maximum flow limiters made in the form of stops at the bottom of the channel, and the threshold element is in the form of additional capacity on the float, hydraulically connected by means of an adjustable valve to a distribution pipe and having a calibrated orifice. 3. The system according to claim I, characterized in that the connection of the float of the level sensor and the locking member is made electrically in the form of a series-connected potentiometer and threshold relay, the restriction (the Bar is made as a limit switch connected to the actuator of the locking member, and the threshold element is designed as a pressure switch in a distribution pipeline, the contacts of which are connected to a shut-off valve with an electric drive. 4. The system according to Clause 1, characterized in that the irrigation canal is made as O5 several pools, nnyh interconnected gidroavtomatom controlled by level sensors on both sides gidroavtomata. IsD

Description

The invention relates to agriculture and can be applied to irrigation systems intended for irrigation of agricultural crops with the power supply of open channels from a closed pipeline network, in particular with Kuban wide sprinkler sprinkler machines.

The purpose of the invention is to increase reliability and reduce operating costs by coordinating the transient operation modes of pumping units and water supply controllers when water consumption changes in the system.

FIG. 1 shows a diagram of the irrigation system; in fig. 2 — node I in FIG. one.

The irrigation system contains pumping units 1 with control units 2, distribution pipe 3 and irrigation canals (sprinklers) 4 connected to distribution pipe 3 via a water supply regulator, including a shut-off member 5, a lever type element 6 (in the hydraulic version of the water supply regulator) and a float level sensor provided with a maximum flow limiter 8 and a threshold element 9.

The irrigation system is also equipped with a hydroaccumulator 10 and a pressure sensor 11 of pump automation, connected via logic unit 12 with control units 2; when the irrigation canal 4 is made from several pools, they are interconnected through a hydraulic automatic machine, the executive unit 13 of which is controlled by level sensors 14 and 15.

The shut-off organ 5, through which water from the pipeline 3 is fed into the irrigation canal 4, may be hydraulically, electrically or mechanically driven; the last two options (as more widely used) are shown separately in the drawing - to the left and right of pipeline 3. At the same time, the drawing shows the possibility of using different embodiments of the maximum flow limiter 8 of the threshold element 9 and the lever type element 6. Travel stop 8 of the float 7 is made in the form of a stop or bottom in a well with a float, or in the form of a limit switch 16 associated with the control unit 17 of the valve member (valve) 18. The threshold element 9 is made as installed On the float 7 is an additional tank 19 with a calibration drain hole 20 through which water is supplied to the tank through a valve 21 that is adjusted during commissioning and a pipe 22 connected to the distribution pipe 3 or a pressure switch, the sensitive element 23 of which switches contacts 24 and. 25. Float sensor level 7 is made in the form of a float 7 or a sensor including

a float mechanically connected to the engine of the potentiometer 26. The lever-type element 6 is made in the form of a lever (or system), including, for example, the setting device 27 and the threshold relay 28 with contacts 29 and 30.

The locking member 5, controlled by the float level sensor 7, changes the flow rate of the water supplied to the irrigation canal 4 from zero to the maximum value taken to be about 130% of the nominal consumption of irrigation installations of the irrigation canal; The maximum flow rate is set during commissioning using the maximum flow limiter 8, which can be performed not only as float limit stops or shutter, but also as drogsel in the downstream section of pipeline 3, etc. Threshold relay 9 performs the main function relay

0 protects the minimum pressure, allows opening of the locking member 5 only after the pressure in the pipeline 3 exceeds the set value, and closes the locking member 5 in case the pressure in the pipeline 3 becomes less

5 of the set value, which is necessary for normal operation of the pumping station's automation in the initial start-up mode, when commissioned, for example, after switching off the voltage. By changing the setting of the threshold relay 9 different sprinklers

 it is possible to ensure the same conditions of their operation regardless of the location on the slope of the area, to organize a system of water supply priorities and, most importantly, to implement a system of automatic unloading of the pumping station when it is overloaded (overload occurs not only in case of emergency pump failure under conditions of no reserve, but also when the inclusion of excessive irrigation machines in the work of the staff, which

often results in the complete disruption of the irrigation system). The hydroaccumulator 10 can be made in the form of a pneumohydroaccumulus or in the form of a reserve basin located at the highest point of the terrain, or as

5 water towers; hydroaccumulator is necessary to ensure the automatic operation of the pumping station in transient conditions, with changes in the number of operating pumping units.

Automation sensors 11 provide automatic switching on and rejection of pump units 1 when the water consumption of the system changes, they are selected depending on the type of pumps and the adopted 5 method of automatic control of the pump station, in particular, pressure sensors and water level sensors in the accumulator can be used and etc.

When performing irrigation canals 4 from several pools, they are interconnected through a hydraulic automatic machine, the executive body 13 of which, using signals from level sensors 14 and 15, implements control such as the stabilizer of the ratio of level deviations (if several irrigation plants in different pools operate at the same time) or type level difference stabilizer (if one is used, the machine is moved along the whole canal, if irrigation installations in the pools work alternately).

The irrigation system works in the following way.

The pressure rise in the pipeline 3 after the system is turned off or the power supply of the pumping station is the same as the primary filling of the pipeline is performed by auxiliary or one or two main pumping units in the supply mode of a limited flow. As long as the pressure in the pipeline 3 does not rise to the set value, the threshold elements 9 do not allow the valves 5 to open, so the pressure rises quite quickly. When the pressure rises to the set value, i.e., the system comes into standby mode for normal operation (standby mode, or mode of transition to work when using the option of periodic system tests), threshold elements 9 gradually, in the order of priority, begin to resolve the operation of the valves 5, since the water flow through the tube 22 and the valve 21 into the tank 19 exceeds the leakage through the drain hole 20, therefore the tank 19 is filled, creates the calculated load of the float 7, and it is lowered into the water; contact 24 opens, removes the signal "Close, and contact 25 closes, creating the possibility of applying to the block 5-3 the signal" Open. At the same time, the closures 5 of those irrigation canals 4, which are filled to the maximum level, will not open (contact 29 will remain open), and the floats 7 of those irrigation canals 4, the water level in which is less than the minimum, will drop to the lower position. This will lead to the full opening of the associated gates 5, however, the flow rate will not exceed the maximum flow rate set by their limiters 8. At intermediate levels, the float sensors 7 determine the intermediate position of the associated valves 5, with water flow being supplied to each irrigator, the value of which is the smaller the larger the amount of water already accumulated in this irrigating channel. Excessive decrease in pressure of water in pipeline 3 at those intervals when the next shutter opens and the water demand exceeds the capacity of the pumps that are currently turned on (i.e. while the pumping station automation is working on the program for switching on the next pump unit 1 according to a signal from sensors 11), eliminated by feeding the pipeline from the hydroaccumulator 10. With sufficient performance of the pumping station, the process continues until all valves 5 are put into operation, otherwise the process should be stopped after switching on all serviceable pumping units, the water will be supplied to the sprinklers in accordance with their priority queue.

After the irrigation canals 4 are filled, irrigation plants feeding from them with automatic, semi-automatic or manual control irrigate the floor, consuming variable water flow to a greater or lesser degree. If, due to an increase in the flow rate consumed, the water level decreases, the lowered float sensor .7 additionally opens the shutter 5 and increases the water supply to the irrigation canal 4. If, due to a decrease in the consumed flow rate, the water level rises, the float sensor 7 covers shutter 5, maintaining the water level in the irrigation canal in the established canal in the prescribed range.

If all the irrigation installations of this irrigation canal stop working, the water level gradually rises to the maximum, the shutter 5 gradually closes and the water supply to this irrigator is completely stopped. This leads to a slight increase in pressure in the pipeline 3, which results in either opening the next shutter (if there were waiting in the queue) as described, or shutting off the excess pump unit. The float sensor 7 maintains in each irrigation channel 4 a level ranging from the minimum to the maximum for each given irrigator according to the operating conditions of its irrigation plants, and the greater flow is supplied to each irrigator, the smaller the water supply at a given time in this irrigator is ( the lower the level sensor float is lowered), the maximum value of the flow rate does not exceed the value set by limiter 8, which at any water consumption provides a gradual increase in ur ext, but which at the same time, and not so great due to unduly large water supply to the sprinkler vosprep tstvovat normal operation other sprinklers.

55 The sensors 11 of the pump automation control the loading mode of the pumping units and, if necessary, through the logic unit 12 and the control units 2 turn on

pumping units 1 are turned off or operated in accordance with an increase or decrease in the total water consumption of the irrigation system through the gates 5. The possibility of significant pressure surges during switching on and off of pumps is excluded by the damping action of the hydroaccumulator 10.

If an excessive number of irrigation plants are turned on, or if part of the pumping units are abnormally shut off, the pressure in line 3 will decrease, so the threshold elements 9 will close the valves 5 until the pressure normalizes as follows: water supply to tank 19 through the tube 22 and the valve 21 decreases proportionally to y / H (H is the pressure in the pipeline), which leads to the emptying of the tank 9-19 through the opening 20 and, accordingly, to the ascent of the float 7 (the setpoint pressure is controlled by the valve 21; the ballast and the diameter of the drain hole 20), and the closure of the shutter 5 can also be adjusted; in the system with a pressure switch, the shutter closes after contact 24 is closed. Similarly, all valves 5 are closed by threshold elements 9 after the pumping station is disconnected (scheduled, during the passage of the daily maximum of the power system; due to the power supply disconnection, etc.), ensuring possibility of the subsequent fast, automatic input of system in work. Shutting down all running pumps can also occur as a result of the failure of one or several running pumps with a relatively small accumulator and longer shutter speeds for closure of valves 5. At the same time, irrigation plants will continue to work due to previously accumulated water supplies, and pumping units turn on (after energization, prohibition removal, etc.) according to the initial start-up scheme (as described above, before switching on all 5 serviceable pumps or satisfying water demand).

It is advisable to apply the ratio of the arms of the lever-type element to the ratio of the allowable stroke of the locking member to the maximum allowable range.

About fluctuations of the water level in the irrigation canal. This can be done approximately, but it is necessary and advantageous, since the operating characteristics of the closures are maximally extended, which ensures coordination with the characteristics of the pumping station with a lower required storage capacity of the hydroaccumulator, allows for “self-synchronization of situations” (water consumption is less than a larger supply of water already accumulated in this irrigator), eliminates significant changes in the intake flow due to wave oscillations of the surface; the shutter opens almost with a patina, so the working head loss is minimal, which significantly reduces the required pressure in the pipeline and

5 directly (; energy consumption associated with it only).

Thus, the described technical solution allows to obtain reliable

.. an automatic irrigation system, the operating costs of which are reduced by eliminating water discharges through. sprinklers, working pressure is reduced and the labor costs of personnel for managing water supply and water distribution are excluded.

5 The economic efficiency of the system for the area served by the irrigation system of ten Kuban-type machines is more than 60 thousand rubles. in year.

Claims (4)

1. IRRIGATION SYSTEM, containing pumping units with blocks, controls associated with pressure sensors, a distribution pipe and irrigation channels with water supply regulators at the inlets, including shut-off bodies and float level sensors, characterized in that, in order to increase reliability and reduce operational costs by coordinating transient modes of operation of pumping units and water supply regulators when changing water consumption in the system, all water supply regulators are equipped with limiters th element of the flow rate and the threshold of the opening of the closure member, hydrants cyclically connected to the distribution pipe and arranged between the float level sensor and the shut-off organ. 2. The system by π. 1, characterized in that the connection of the float of the level sensor and the shut-off element is made in the form of a lever transmission, with the maximum flow limiters made in the form of stops at the bottom of the channel, and the threshold element in the form of an additional container on the float hydraulically connected through an adjustable valve to the distribution pipe and having a calibrated hole. 3. The system according to π. 1, characterized in that the connection of the float of the level sensor and the shut-off element is made electric in the form of a series-connected potentiometer and a threshold relay, the limiter is made in the form of an end switch connected to the drive of the shut-off element, and the threshold element is made in the form of a pressure switch in the distribution pipe, contacts which are connected to a locking body with an electric drive. 4. The system under item ‘1, characterized in that the irrigation canal is made in the form of several downstream wells interconnected by a hydraulic machine controlled by level sensors on both sides of the hydraulic machine. SU,. „1161020 I