SU1127548A1 - Watering device - Google Patents

Abstract

1. A WATERING DEVICE connected to a supply network and containing a sectional irrigation pipeline with water outlets and shut-off valves, a pressure source and a mechanism for controlling water outlets group operation, characterized in that, in order to reduce construction cost and increase operational reliability, the pressure source is designed as pneumatic pressure tank divided into PNMV and connected with the irrigation pipe and through a siphon with the supply network, and the mechanism for controlling the group operation of the water outlets nen a steering pnevmoprovo: rows connected to pnevmosektsi E, and is provided with setters watering coupled with check valves, and discharge outlets. 2. The device according to claim 1, characterized in that one of the pneumatic ducts of the control mechanism is provided with a pneumatic collector having air inlets equipped with electric relay with on-off valves for connection to low-voltage communication lines. 3. The device according to claim 1, characterized in that the irrigation control devices are made in the form of needle switches equipped with (L spring-loaded bellows communicated with control pneumatic lines and connected with the slide valves, while the springs of the bellows have different stiffness coefficient and height.

Description

N3 SL

four

About

The invention relates to agriculture, namely to irrigation devices on furrows of agricultural crops.

An irrigation device is known that includes an irrigation pipeline with water inlets opposite each irrigation furrow, which are arranged in a straightforward order and connected to the irrigation pipeline by a water supply system with sew tubes. In addition, each water outlet has a diaphragm actuator with a regulating element, the cavity of which is connected from above to the water-supplying element and from the bottom to the hydraulic connection pipe communicated through the mechanism of grounding the water outlets with the pressure water-supplying network 1.

The disadvantages of this irrigation device are relatively low operational reliability and relatively large building costs.

The closest to the technical essence of the invention is a irrigation device, a subfloat that is tapped to the supply network and contains a sectional irrigation pipe with water inlets for supplying water to the outlet grooves and shut-off valves, a pressure source and a control mechanism for group operation of water outlets 2 |.

The disadvantages of a lime irrigation device are relatively large construction costs due to the density of the pressure network, equal to the number of irrigation pipeline sections, and the large number of transport pipelines, low reliability and speed of control.

AIM OF THE INVENTION STREAM

Noah cost and increase operational reliability.

The goal is achieved by the fact that in the irrigation device, connected to the inlet network and containing a sectional irrigation pipeline with water outlets and shut-off valves, pressure source and control mechanism for the operation of the outlets, the pressure source is made in the form of a pneumonanor tank divided into pneumatic section and communicated with the irrigation pipeline and through the siphon with the inlet network, and the mechanism for controlling the group operation of the water outlets is made in the form of control pneumatic lines connected to pneumatic sections , and is equipped with noliv controllers associated with shut-off valves and water outlets.

In addition, one of the pneumatic lines of the control mechanism is equipped with an air collector having air inlets equipped with electric on-off two-way valves for connection to low-voltage communication lines.

The irrigation control devices are made in the form of spool switches equipped with spring-loaded bellows, communicated with controlled pneumatic lines and connected with the spools of switches, while the springs of sylphs have different stiffness coefficients and heights. 5 On. FIG. 1 shows the layout of irrigation devices on the orbital field, plan; in fig. 2 - irrigation device, side view; on (|) 3 - water distribution structure of the irrigation device, a longitudinal section; in fig. 4 - the mechanism of controlling the rough work of the outlets.

Ilo.:inBHoe device contains a transducer; 1, pipeline 1 supply network, water distribution structure 2,

5 po.1ivpoy conduit 3 is divided into sections odpovremeshyugo zaporpymp irrigation valves 4, 5 in the outfalls distribution furrow irrigation and furrows 6 mehapizm control group work outlets and control the operation of the mechanism construction in the form of the charging tube 7 and 8 njTyuepa vozduhorazr-stand-off with elektroreleynym clan 9. The water distribution structure 2 is designed as an elevated floor above the ground by a calculated value from the conditions for ensuring the command of the tank 10, which is divided by a partition 11 and the receiving 12 and the outlet 13 chambers, which are connected respectively to the NODVODYPIIY and the withdrawal and 1 sections of the transport pipeline 1. Both cameras communicate with each other through a water level regulator in the upper reach, made in the form of a transit 14 with the top of a triangular air inlet 15 at the mark the required level in the receiving chamber 12. In the partition 11 a water outlet opening 16 is provided and in one of the vessel walls there is a water outlet opening 17.

A new chamber 12 contains an inlet 0p pipe for irrigation siphon 18 with an air inlet port 19, and its outlet pipe is equipped with a pressure source in the form of a pneumoscopic reservoir 20, separated by non-enclosures 21 into hermetically insulated one from another, three pneumo sections 22 and communicated with irrigation conduit 3 via mating conduit 23.

The shut-off valves 4 are each made in the form of a nozzle 24, which has a flexible working body 25 that is intrinsically permeable around the perimeter and is connected to irrigation; piping 3 couplings and rubber rings. 26.

Underground outlet 5 is a spout with a diameter of 50-60 mm top

which is located below the plowed horizon, and the bottom is provided with an orifice nozzle 27 having a design diameter and hermetically connected to irrigated three-wire conduit 3 through an opening arranged in it, and the nozzle is provided with a flexible valve body 28 of valve type 4. The underground outlet 5 is located opposite the distribution groove and provides water 15-30 irrigation furrows.

The mechanism for controlling the group operation of the outlets has a control pneumatic line 29, a working pneumatic line 30 and a common pneumatic line 31 connected to the corresponding pneumatic sections 27 of the pneumatic head 20 and through the control unit 32 for irrigation by pneumatic lines 33 of the locking valves 4 and pneumatic lines 34 of the outlets 5 - with locking valves 4 and water outlets 5, the control air pipe 29 communicating with the first pneumatic section 22 through a pneumatic collector 35, having air inlets 36 with a calculated diameter of the holes, which are provided with an electric Lane off valves 37, connected to low-current lines 38 bond.

The irrigation unit 32 is a spool switch having a housing 39i inside which a bellows 40 is located, communicating with the control pneumatic line 29 and spring-loaded with a design stiffness coefficient and height of the spring 41, while the bellows is connected to the spool 42 having pneumatic channels 43-45 connection located at a height of the required distance from one another. The housing 39 is hermetically connected to the pneumatic lines 33 and 34 at the points determined by the location of the entrances to the pneumatic channels 43-45.

The distribution groove within the service limits by the outflow of 5 irrigation furrows has earth bridges.

The device works as follows.

When water enters the conveying pipeline 1, signals are sent through the transfer lines 38 to close with the electric relay two-way valves 9 and 37 of the air discharge valve 8 and the corresponding air inlets 36. As the water enters the receiving chamber 12, the distribution building 2 has a level in it and water is poured through the crests of the transit siphon 14 and the irrigation 18, which are charged, as a result of which the calculated part of the water flow is taken away by the irrigation device, and the Leaving part comes to downstream irrigation devices. At the same time, the level in the chamber decreases and is set at a stabilized mark close to the upper point of the air inlet triangular hole 15. The water level in the receiving chamber maintains at the calculated mark due to the influx of atmospheric air under the hood of the siphon 14 through the water level released by the water level 15. When supplying water flow through pipeline 1 per one irrigation device, siphon 14 is disconnected from operation.

When an irrigation siphon 18 is operating, through the air inlet 19 under its hood, air from the atmosphere enters along with water, and the diameter of the opening 19 is chosen in such a way that its value practically does not reduce the consumption coefficient of the irrigation siphon.

Atmospheric air with water enters pneumatic pressure reservoir 20 and accumulates in one of the other pneumatic sections 22, and water flows through irrigating pipe 23 through an adjoining pipe into irrigation pipe 3. In pneumatic sections 22, this creates closed air cavities, the pressure in which is determined the difference between the levels of water urotsn in the receiving chamber and the level of water in the pneumo-section. Since the two pneumo sections are connected to the pneumatic lines 30 and 31, the cavity of which, together with the cavity between the flexible elements and the ports of the shut-off valves, 4

5 and water outlets 5 is an enclosed space, the pressure of the air accumulated in them is maximal and equal to the required one, and the air coming from the irrigation siphon 18 is carried along with the water flow in the irrigation pipe 3. The required air pressure in the cavity of the pneumatic collector 35 is set depending on whether what is necessary to water the area under the irrigation pipeline, and with the unions 36 closed, in the pneumo-section 22 the maximum pressure is also set, which is transmitted to the bellows 40 by the control pneumatic line 29 The body of which expands and compresses the spring 41, displacing the spool 42 until the pneumatic channel 44 coincides with the pneumatic line 33, which provides air to the shut-off valve 4, the flexible working body of which expands and closes the irrigation pipe at the end of the first section. In this case, the body 39 of the spool 42 overlaps the pneumatic line 34,

5 preventing the inflow of air to the outlets of the first section of the irrigation pipeline. As a result, the calculated curve of the piezometric head is formed on the first section of the irrigation pipeline,

What, with the calculated diameters of the nozzles 27, causes the required flow rates of water through the outlets 5 to the distribution grooves and further to the irrigation grooves.

If it is necessary to irrigate the next section, the corresponding option is opened by the breeder valve 36 with an electric relay two-way valve 37 according to the signal transmitted via the low-current communication line 38. In this case, part of the air flow from the pneumatic collector 35 enters the atmosphere and in its cavity a calculated value is set to less than the initial pressure, while the bellows 40 of the first stage 32 irrigation device moves downward under the action of the spring 41, as a result of which the pneumatic line 34 coincides with the pneumatic channel 43, the overlap of the pneumatic line 33 from the side of the pneumo section 22 and its combination with the pneumatic channel 45 from the side of the shut-off valve 4. As a result, the air from the cavity of the choke valve flows into the atmosphere under The effect of water pressure is on a flexible working body 25, which opens and allows irrigation water to flow into the next section of the irrigation pipeline.

At the same time, the air from the pneumo section 22 through the pneumatic lines 31 and 34 and pneumatic channel 43 is injected under the flexible locking bodies of the outlets 5, which block the flow of water into the distribution grooves at the formed piezometric line from the overlap of the second section of the irrigation pipeline.

With subsequent pressure drops in the pneumocollector 35, the spool 42 of the first stage 32 irrigation device takes the fixed lower position, from which it moves to the uppermost position only when the calculated maximum pressure is created in the sylphon 40 in the case of the need to supply water to the first irrigation plot.

In order to provide the noted work algorithms for preset; 32 irrigation springs, their springs 41 have equal stiffness coefficients to one another, but different compression factors due to an equal design height for the same sizes of bellows 40 and spool 42.

All the factors noted increase the operational reliability of the proposed device in comparison with the known ones.

The construction of the proposed irrigation devices will require 3-4 times less than the transporting pipelines on the irrigated massif, the number of water distribution structures is reduced by the same amount as compared to the known ones, which causes a decrease in

0 construction costs and eliminates interference with high-performance soil tillage and other mechanisms.

The proposed irrigation device has a significantly larger field of application, since it allows feeding large amounts of water into the furrow due to the possibility of reducing the length of the simultaneous irrigation sections from the irrigation pipeline to 50-100 m and can be used on floors with a slope of 0.001 or more in. that

0 time as well-known irrigation devices can be applied with slopes of at least 0.010.

The proposed device has a relatively simple interface with the control equipment (CCA), since it is based on the use of two-position electro-controlled miniature valves, the diameters of which are small (8-10 mm), the required effort to control them is small (0.050-0.10 kgf)

0 When using the device in automated furrow irrigation systems, the length of the communication lines and the number of control points are significantly reduced due to the laying of communication lines only along the transporting water conduit and provides controllability with three to four TU and TC signals at the water distribution structure. irrigated plots.

"Nl

Nt

€

Fig.Z

ge

Fy

Claims (3)

1. IRRIGATION DEVICE connected to the supply network and containing a sectional irrigation pipeline with water outlets and shut-off valves, a pressure source and a control mechanism for group operation of water outlets, characterized in that, in order to reduce the construction cost and increase operational reliability, the pressure source is made in the form of a pressure head the tank, divided into PNRvosection and communicated with the irrigation pipeline and through a siphon - with the supply network, and the mechanism for controlling the group work of outlets in the form of control pneumatic pipelines connected to pneumatic sections, and equipped with irrigation controllers associated with shut-off valves and outlets. 2. The device according to π. 1, characterized in that one of the pneumatic pipelines of the control mechanism is equipped with a pneumatic manifold having air inlet fittings equipped with on-off on-off valves for connecting to low-voltage communication lines. 3. The device according to π. 1, characterized in that the irrigation controllers are made in the form of zolotnik switches equipped with “spring-loaded bellows connected with control pneumatic pipes and connected to the switch spools, while the bellows springs have different stiffness coefficient and height. SU .. „1127548