SU1074450A1 - Automated system of pulse sprinkling - Google Patents

Abstract

AUTOMATED SYSTEM FOR PULSED irrigation comprising a supply conduit, the two glazed portion with pulse sprinklers connected to the inlet duct through the valve distributor driven setpoint control pulses and equipped with ejectors at the beginning portions hydraulically sorbschennyh through a check valve to supply conductive conduit, characterized due to the fact that, in order to simplify the construction while reducing the time spent filling the sections, the number of sprinkling devices The plots of the sections are unequal and inversely proportional at each time interval of their filling, the supply pipe of the system is equipped with an ejector at the point where the check valves are connected to it, and the actuator of the valve distributor of the system has two control cavities connected to the beginning of the sections or the atmosphere The control pulses of the control pulses are made as separate for each section of the hydro relay (P pressure, the control elements of which are located in antiphase and connected to the beginnings plots.

Description

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The invention relates to the field of irrigation of agricultural crops and can be used for pulsed irrigation with automated systems. A known automated impulse sprinkler system, including a supply pipe with a pressure pulse generator at the beginning of it, and a pipe network with impulse sprinklers 1. The disadvantages of this system are large time losses for filling the piping network and impulse sprinklers. Also known is an automated impulse sprinkler system that includes a supply pipe, two irrigated areas with impulse sprinklers connected to the supply line through a valve distributor driven by a control pulse setter and equipped with ejectors at the beginning of sections hydraulically communicated through a check valve with the supply line 2. The disadvantages of the known system are the complexity of the system design, which, due to the presence of several feedbacks, can and a self-oscillating mode, as well as loss of time in connection with the fact that portions of the system operate alternately at equal intervals. The aim of the invention is to simplify the design while reducing the time lost to fill the sections. This goal is achieved by the fact that the number of sprinklers of the sections is unequal and inversely proportional at each time interval of their filling, the supply pipe of the system is equipped with an ejector at the point where the check valves are connected to it, and the valve distribution actuator has two control cavities connected via a control unit control pulses with the beginning of the sections or with the atmosphere, and the master of control pulses is made as separate for each section of the pressure relay, the control elements of which p found on the rear opposite and connected to the beginning of the section. FIG. 1 shows a schematic of an automated pulse irrigation system; in fig. 2 shows the control pulse driver unit. The automated pulse irrigation system consists of the main 1 and an additional 2 irrigation stations with main pipelines 3 and 4 on the klauchastok, which are connected to the pan distributor 5. One of the pulse sprinklers (sprinklers) 6, which is the command one on the main section, and the sprinkler 7, which is commanded at the additional section, respectively, through the control pulse adjusters, made in the form of hydraulic pressure relays 8 and 9, are connected to the hydraulic distributor 5, which is a nozzle 10 is connected to a pressure source, such as a pump station. The ejector U of the nozzle 10 through the check valves 12 and 13 is connected with the ejectors 14 and 15, which are located respectively in the main pipeline 3 of the main irrigation section 1 and in the main pipeline 4 of the additional irrigation section 2. The channels 16-18 and 19-21 connect the hydraulic devices of the main and additional irrigation stations with the control valve, which acts as an actuator for setting command control pulses. The hydraulic pressure switches 8 and 9 (Fig. 2) consist of a housing 22, a spool 23, a piston 24, a tuning spring 25. The spool can move up to the stop 26 and has drainage channels 27. The housing opening 28 is connected to the communication channel 16 opening 29 to communication channel 17, opening 30 to communication channel 18, holes 31 and 32 communicate with the atmosphere. The pressure transmitted to the spool 23 through the opening 28 from the trunk pipe, -, -, - ,, the pipeline is perceived by equal internal areas of the spool and does not cause movement, i.e. the valve is balanced. The position of the spool is determined by the pressure applied to its piston 24 and the force of the adjusting spring 25. The spool can connect the overhead fistula of the hydraulic distributor 5 through the communication channel 17 to the pressure through the communication channel 16 or to the atmosphere through the hole 31. Hole 32 It is drainage and serves to remove water from channels 27 of spool 23 and leaks between the body and the spool of a hydraulic relay. When the pressure hydro relay is closed (Fig. 2), the control cavity of the opening 30 is separated from the opening 32. The opening cross section of the opening 32 is larger than the cross section of the drainage channels 27, therefore when switching relays 8 and 9, the connection of the opening 30 to the drain opening 32 does not impair 9. The system works as follows. Water from the pressure source enters the nozzle 10 into the hydraulic distributor 5. Through the channels 16 and 17 of the communication through the hydraulic switch 8, the water pressure is transferred to the left hydraulic distributor 5. The hydraulic piston area is larger than the valve area position During this period, the irrigation sprinklers of the main irrigation area 1 are filled. When water moves through the nozzle 10 in the ejector I, a vacuum occurs, which through the check valve 13 spreads into the main pipe 4 of the additional section 2, where at this time there is a pressure decreasing impulse, due to which, it triggers. There are pulsed sprinklers of the additional site. The check valve 12 at this time is on both sides at approximately the same discharge from the ejector 14 and is not involved in the work.

In this position of the control valve, the cavities of the pulse sprinklers of the main section 1, including the command pulse sprinkler 6, are filled. When the pressure in the cavity of the command pulse sprinkler 6 reaches its working value, it causes short-term activation of the hydraulic pressure switch 8 by the spool 23 to close the channel 16 connection than disconnects the left over piston cavity of the control valve 5 from the pressure source and connects it through the opening 31 in the housing of the hydraulic relay with the atmosphere. Under the action of water pressure, the movable part of the valve 5 is moved to the left. The main pipeline 3 of the main irrigation section 1 is disconnected from the pressure source, the flow of water through the ejector 14 is stopped.

Due to the non-return valve 12, the vacuum from the ejector 11 propagates into the main pipeline 3 of the main irrigation section and a pressure reducing impulse will arise in it. Pulse sprinklers of the main section are triggered. At the time when the movable part 5 is in the left position,

filling the pulse sprinklers of the additional zone through its main pipeline 4.

The operation of the hydraulic circuit serving the additional irrigation site comes from its command impulse sprinkler 7, similarly to the operation of the hydraulic circuit of the main irrigation section. However, the filling of the water cavities of the impulse sprinklers of the additional section occurs much earlier, since their number is smaller. The process then repeats.

A change in the time for filling the pulse sprinklers of the main zone (filling period) is achieved by adjusting the command pulse sprinkler. 6 of the main zone 1, and the duration of the low pressure pulse in the main zone - by adjusting the command sprinkler 7 of the additional irrigation zone.

The number of pulsed sprinklers and the periods of work of the plots are in proportion

NZ N, V,

where Wt is the number of pulsed sprinklers

the main plot; Nj-number of pulse sprinklers

additional plot; Tj - the period of filling the main

plot;

TI is the period of the downward pressure pulse in the main portion. The application of the invention makes it possible to increase the utilization rate of the equipment of the impulse sprinkler system due to the fact that during the filling period of the sprinklers of the main zone, which is 20-30 times longer than the pressure drop pulse, not half of the impulse sprinklers stand idle, but only a few pieces in the additional zone.

The system allows for a wide range of control over the amount of water supplied to the field, which is an essential requirement of modern agricultural technology.

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Fig2

Claims (1)

AUTOMATED PULSE RAINING SYSTEM, including a supply pipe, two irrigation sections with pulse sprinklers connected to a supply pipe through a valve distributor driven by a control pulse generator and equipped with ejectors at the beginning of sections hydraulically communicated through a check valve with a supply pipe, that, in order to simplify the design while reducing time loss for filling sections, the number of sprinklers of sections is unequal and inversely proportional to each section of the time of their filling, the supply pipe of the system is equipped with an ejector at the place where the check valves are connected to it, and the drive of the valve distributor of the system has two control cavities connected through the control pulse generator to the beginning of the sections or to the atmosphere, and The control pulses are made in the form of separate pressure switches for each section, whose control elements are in antiphase and connected to the beginning of the sections.