SU1011777A1 - Automatic watering system - Google Patents

Abstract

AUTOMATED IRRIGATING SYSTEM, including a water supply source, a control room, a main channel, distribution and irrigation channels with hydraulic actuators, controlled by signals from level sensors and task mechanisms, peripheral controls: “1d control stations for water distribution by hydraulic actuators and a line of distributors, differing designations; the fact that, in order to increase reliability and simplify the construction, the communication line is made radio-relay and consists of two grounded at the ends s wires connected through amplifiers to controlled items deployed The relatively to each other by 90-180 s and located at each monitoring (A direct and dispatch points.

Description

The invention relates to agriculture, to the field of automation of water distribution in irrigation canals. The known automated irrigation system contains a network of irrigation canals with hydrotechnical structures equipped with downstream level regulators, forming a sequential chain of adjustable links f1}. The disadvantages of this system are the presence of large reserve bones, as well as significant water discharges. An automated irrigation system is also known, including a water supply source, a control room, a main canal, distribution and irrigation canals with hydraulic gates, controlled by signals from level sensors and task development mechanisms, peripheral controlled water distribution control points and hydraulic lines and a communication line 20. Disadvantages This system is of low reliability and complexity due to the use of a wired communication line. The purpose of the invention is to improve reliability and reliability. roschenie system design. The goal is achieved by the fact that the communication line is made of radio relay and consists of two pieces of wire grounded at the ends, connected through amplifiers to controlled points, deployed 90-180 relative to each other and located at each controlled and control points. Figure 1 presents the scheme of the proposed system; figure 2 - section aa in figure 1. The system contains a source of water supply (not shown), channels 1, main, distribution and irrigation, installed on them hydraulic action gates 2, controlled by level 3 sensors connected in series with task 4 mechanisms, controlled by telemechanics points 5 and low frequency amplifier blocks 6 with two pieces of grounded wires 7 at the input, as well as a control center 8, connected to the pieces of grounded wires 7 through. ; low frequency amplifier unit 6. The system works as follows. From the control room 8, a low-frequency command signal is transmitted, containing the address of the controlled point, and a control signal for changing the setpoint of the hydrodynamic regulator 2, which goes to the low-frequency amplifier unit 6, from the output of which goes to two segments of the ground wires 7 that are antenna. The extended segments of the wires of the line, located horizontally near the boundary between the earth and air, when a low-frequency signal is applied to them, form a vertically-polarized electromagnetic field directed by maxima along the axis. Formed electromagnetic field induces an emf in the wires; 7 of the nearby monitored item 5, which is perceived and amplified by the low-frequency amplifier unit 6. From the received and amplified signal, the address is entered into the mechanism for working out task 4 of the monitored item 5, in case of a mismatch of the allocated address with the address of the monitored point, the received signal is fed back to the unit low frequency amplifiers b and then enters the segments of the wires 7 grounded at the ends, where a vertical-polarized electromagnetic field is induced, which is perceived by the segments of the wires on which Ntsov line subsequent controlled paragraph 5,. those. the signal is retransmitted until the address embedded in the signal transmitted from the control tower 8 does not match the address of the controlled point 5. If the address of the signal coincides with the address of the controlled point 5, a command is output at its output that enters the input of the task processing mechanism 4 which mechanically changes the installation of the level sensor 3. After the end of the transition process, the hydraulic valve 2 occupies a new position and maintains the water level set by sensor 3 in the upstream. At the same time, the new water flow rate at this hydraulic structure is maintained in accordance with the distribution plan adopted by the dispatcher. The application of the proposed automated irrigation system is most appropriate in rice irrigation systems using the design of the Kubansk rice irrigation system consisting of standard irrigation modules with an area of 144 hectares. The use of an automated irrigation system makes it possible to significantly reduce its cost and increase operational reliability due to the replacement of extended two-wire communication lines with grounded lines at the ends.

The estimated economic effect from the use of the proposed invention for the Petrovsko-Anastasievsky rice irrigation system site, Krasnodar Krai, ° 15,000 hectares is 2v, 5 p / ha.

Claims (1)

. AUTOMATED IRRIGATION SYSTEM, including a water supply source, a dispatch center, a main canal, distribution and irrigation canals with hydrodeyst. with control gates, controlled by signals from level sensors and job completion mechanisms, peripheral controlled water distribution control points with hydraulic gates and a communication line, characterized in that, in order to increase reliability and simplify the design, the communication line is radio relay and consists of two pieces of wire grounded at the ends connected through amplifiers to controlled items The relative deployed in relative _to each other at 90-180 ° $ g and arranged at each monitored and dispatching n nktov. .